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Karyopharm Announces Publication of XPOVIO (Selinexor) Phase 2b SADAL Study Results in The Lancet Haematology – GlobeNewswire

June 24, 2020 07:00 ET | Source: Karyopharm Therapeutics Inc.

NEWTON, Mass., June 24, 2020 (GLOBE NEWSWIRE) -- Karyopharm Therapeutics Inc. (Nasdaq:KPTI), an innovation-driven pharmaceutical company, today announced that the results of the Phase 2b SADAL (Selinexor Against Diffuse Aggressive Lymphoma) study evaluating XPOVIO in patients with relapsed or refractory diffuse large B-cell lymphoma (RR DLBCL) were published online in The Lancet Haematology. The SADAL study evaluated selinexor, the Companys first-in-class, oral Selective Inhibitor of Nuclear Export (SINE) compound for the treatment of adult patients with RR DLBCL, not otherwise specified, who have received at least two prior therapies.

The clinical outcomes for patients with heavily pretreated relapsed or refractory DLBCL are typically very poor, and hence results from the multinational Phase 2b SADAL study are noteworthy, said Prof Nagesh Kalakonda, University of Liverpool, lead author of the manuscript. In this population, single-agent oral XPOVIO (selinexor) demonstrated an overall response rate of 28%, including a complete response rate of 12%. Responses were seen in all subgroups regardless of age, gender, prior therapy, DLBCL subtype or prior stem cell transplant therapy. Importantly, patient responses were durable with a median duration of response of 9.3 months (23.0 months for patients who achieved a complete response). Finally, responses were associated with longer survival, underscoring the potential of oral XPO1 inhibition as an oral, non-chemotherapeutic option for patients with RR DLBCL.

These positive data further reinforce our strong belief that oral XPOVIO offers patients an important new treatment option, especially considering the patient population studied in SADAL had an expected median survival of less than six months. Furthermore, treatment with XPOVIO demonstrated deep and durable responses with a safety profile qualitatively similar to previous clinical studies with XPOVIO, said Sharon Shacham, PhD, MBA, Founder, President and Chief Scientific Officer of Karyopharm. We are proud to see these published clinical results and are excited to now commercialize XPOVIO in our second cancer indication on behalf of the patients and families who are desperately in need of new treatment options.

The U.S. Food and Drug Administration (FDA) approved XPOVIO on June 22, 2020 for the treatment of adult patients with RR DLBCL, not otherwise specified, including DLBCL arising from follicular lymphoma, after at least two lines of systemic therapy. This indication was approved based on response rate under the FDAs Accelerated Approval Program, which was developed to allow for expedited approval of drugs that treat serious conditions and that fill an unmet medical need. Continued approval for this indication may be contingent upon verification and description of clinical benefit in a confirmatory trial(s). A Marketing Authorization Application for selinexor for RR DLBCL is planned for submission to the European Medicines Agency in 2021.

The Phase 2b SADAL Study Results

The published results are based on the multi-center, single-arm Phase 2b SADAL study (NCT02227251), which evaluated 127 patients (median of 2 prior treatment regimens) with RR DLBCL. Patients received a fixed 60 mg dose of XPOVIO given orally twice weekly for a four-week cycle. Patients with germinal center B-cell (GCB) or non-GCB subtypes of DLBCL were included in enrollment.

The SADAL study met its primary endpoint of overall response rate (ORR) with an ORR of 28%, including 15 complete responses (CRs) and 21 partial responses (PRs). An additional 11 patients experienced stable disease (SD) for a disease control rate of 37.0%. The ORR in the 59 patients with the GCB-subtype was 34% and the ORR in the 63 patients with the non-GCB subtype was 21%. In addition, there were 5 patients enrolled whose subtype was unclassified and 1 of these patients achieved a CR while 2 of these patients achieved a partial response (PR).

Key secondary endpoints included a median duration of response (DOR) in the responding patients of 9.3 months and median overall survival (OS) across the entire study population of 9.1 months. Median OS has not yet been reached in patients who achieved either a CR or PR. In patients who had stable disease, the median OS was 18.3 months. Patients whose disease progressed or had no response to XPOVIO had a median OS of 4.3 months, which is consistent with the expected poor prognosis for patients who have RR DLBCL and have been previously treated with two or more lines of therapy.

All 127 patients were included in the safety analyses. The most common treatment-related adverse events (AEs) were cytopenias along with gastrointestinal and constitutional symptoms and were generally reversible and managed with dose modifications and/or standard supportive care. The most common non-hematologic AEs were nausea (58%), fatigue (47%), and decreased appetite (37%) and were mostly Grade 1 and 2 events. As expected, the most common Grade 3 and 4 AEs were thrombocytopenia (46%), neutropenia (24%) and anemia (22%) and were generally not associated with clinical sequelae.

The patient population described in this publication includes data from 127 patients in the SADAL study while the FDA approved label includes data from seven additional patients or 134 patients total. As such, there are minor differences in the efficacy and safety percentages between the two sources.

About XPOVIO (selinexor)

XPOVIO is a first-in-class, oral Selective Inhibitor of Nuclear Export (SINE) compound. XPOVIO functions by selectively binding to and inhibiting the nuclear export protein exportin 1 (XPO1, also called CRM1). XPOVIO blocks the nuclear export of tumor suppressor, growth regulatory and anti-inflammatory proteins, leading to accumulation of these proteins in the nucleus and enhancing their anti-cancer activity in the cell. The forced nuclear retention of these proteins can counteract a multitude of the oncogenic pathways that, unchecked, allow cancer cells with severe DNA damage to continue to grow and divide in an unrestrained fashion. Karyopharm received accelerated U.S. Food and Drug Administration (FDA) approval of XPOVIO in July 2019 in combination with dexamethasone for the treatment of adult patients with relapsed refractory multiple myeloma (RRMM) who have received at least four prior therapies and whose disease is refractory to at least two proteasome inhibitors, at least two immunomodulatory agents, and an anti-CD38 monoclonal antibody. Karyopharm has also submitted a Marketing Authorization Application (MAA) to the European Medicines Agency (EMA) with a request for conditional approval of selinexor in this same RRMM indication. Karyopharm submitted a supplemental New Drug Application (sNDA) to the FDA requesting an expansion of its current indication to include the treatment for patients with multiple myeloma after at least one prior line of therapy based on the positive results from the Phase 3 BOSTON study which evaluated selinexor in combination with Velcade (bortezomib) and low-dose dexamethasone. In June 2020, Karyopharm received accelerated FDA approval of XPOVIO for its second indication in adult patients with relapsed or refractory diffuse large B-cell lymphoma (DLBCL), not otherwise specified, including DLBCL arising from follicular lymphoma, after at least 2 lines of systemic therapy. Selinexor is also being evaluated in several other mid-and later-phase clinical trials across multiple cancer indications, including as a potential backbone therapy in combination with approved myeloma therapies (STOMP), in liposarcoma (SEAL) and in endometrial cancer (SIENDO), among others. Additional Phase 1, Phase 2 and Phase 3 studies are ongoing or currently planned, including multiple studies in combination with approved therapies in a variety of tumor types to further inform Karyopharms clinical development priorities for selinexor. Additional clinical trial information for selinexor is available at http://www.clinicaltrials.gov.

For more information about Karyopharms products or clinical trials, please contact the Medical Information department at:

Tel: +1 (888) 209-9326 Email: medicalinformation@karyopharm.com

IMPORTANT SAFETY INFORMATION

Thrombocytopenia: XPOVIO can cause life-threatening thrombocytopenia, potentially leading to hemorrhage. Thrombocytopenia was reported in patients with multiple myeloma (MM) and developed or worsened in patients with DLBCL.

Thrombocytopenia is the leading cause of dosage modifications. Monitor platelet counts at baseline and throughout treatment. Monitor more frequently during the first 3 months of treatment. Institute platelet transfusion and/or other treatments as clinically indicated. Monitor patients for signs and symptoms of bleeding and evaluate promptly. Interrupt, reduce dose, or permanently discontinue based on severity of adverse reaction.

Neutropenia: XPOVIO can cause life-threatening neutropenia, potentially increasing the risk of infection. Neutropenia and febrile neutropenia occurred in patients with MM and in patients with DLBCL.

Obtain white blood cell counts with differential at baseline and throughout treatment. Monitor more frequently during the first 3 months of treatment. Monitor patients for signs and symptoms of concomitant infection and evaluate promptly. Consider supportive measures, including antimicrobials and growth factors (e.g., G-CSF). Interrupt, reduce dose, or permanently discontinue based on severity of adverse reaction (AR).

Gastrointestinal Toxicity: XPOVIO can cause severe gastrointestinal toxicities in patients with MM and DLBCL.

Nausea/Vomiting: Provide prophylactic antiemetics. Administer 5-HT3 receptor antagonists and other anti-nausea agents prior to and during treatment with XPOVIO. Interrupt, reduce dose, or permanently discontinue based on severity of ARs. Administer intravenous fluids to prevent dehydration and replace electrolytes as clinically indicated.

Diarrhea: Interrupt, reduce dose, or permanently discontinue based on severity of ARs. Provide standard anti-diarrheal agents, administer intravenous fluids to prevent dehydration, and replace electrolytes as clinically indicated.

Anorexia/Weight Loss: Monitor weight, nutritional status, and volume status at baseline and throughout treatment. Monitor more frequently during the first 3 months of treatment. Interrupt, reduce dose, or permanently discontinue based on severity of ARs. Provide nutritional support, fluids, and electrolyte repletion as clinically indicated.

Hyponatremia: XPOVIO can cause severe or life-threatening hyponatremia. Hyponatremia developed in patients with MM and in patients with DLBCL.

Monitor sodium level at baseline and throughout treatment. Monitor more frequently during the first 2 months of treatment. Correct sodium levels for concurrent hyperglycemia (serum glucose >150 mg/dL) and high serum paraprotein levels. Assess hydration status and manage hyponatremia per clinical guidelines, including intravenous saline and/or salt tablets as appropriate and dietary review. Interrupt, reduce dose, or permanently discontinue based on severity of the AR.

Serious Infection: XPOVIO can cause serious and fatal infections. Most infections were not associated with Grade 3 or higher neutropenia. Atypical infections reported after taking XPOVIO include, but are not limited to, fungal pneumonia and herpesvirus infection.

Monitor for signs and symptoms of infection, and evaluate and treat promptly.

Neurological Toxicity: XPOVIO can cause life-threatening neurological toxicities.

Coadministration of XPOVIO with other products that cause dizziness or mental status changes may increase the risk of neurological toxicity.

Advise patients to refrain from driving and engaging in hazardous occupations or activities, such as operating heavy or potentially dangerous machinery, until the neurological toxicity fully resolves. Optimize hydration status, hemoglobin level, and concomitant medications to avoid exacerbating dizziness or mental status changes. Institute fall precautions as appropriate.

Embryo-Fetal Toxicity: XPOVIO can cause fetal harm when administered to a pregnant woman.

Advise pregnant women of the potential risk to a fetus. Advise females of reproductive potential and males with a female partner of reproductive potential to use effective contraception during treatment with XPOVIO and for 1 week after the last dose.

ADVERSE REACTIONS

The most common adverse reactions (ARs) in 20% of patients with MM are thrombocytopenia, fatigue, nausea, anemia, decreased appetite, decreased weight, diarrhea, vomiting, hyponatremia, neutropenia, leukopenia, constipation, dyspnea, and upper respiratory tract infection.

The most common ARs, excluding laboratory abnormalities, in 20% of patients with DLBCL are fatigue, nausea, diarrhea, appetite decrease, weight decrease, constipation, vomiting, and pyrexia. Grade 3-4 laboratory abnormalities in 15% of patients included thrombocytopenia, lymphopenia, neutropenia, anemia, and hyponatremia. Grade 4 laboratory abnormalities in 5% were thrombocytopenia, lymphopenia, and neutropenia.

In patients with MM, fatal ARs occurred in 9% of patients. Serious ARs occurred in 58% of patients. Treatment discontinuation rate due to ARs was 27%. The most frequent ARs requiring permanent discontinuation in 4% of patients included fatigue, nausea, and thrombocytopenia.

In patients with DLBCL, fatal ARs occurred in 3.7% of patients within 30 days, and 5% of patients within 60 days of last treatment; the most frequent fatal AR was infection (4.5% of patients). Serious ARs occurred in 46% of patients; the most frequent serious AR was infection. Discontinuation due to ARs occurred in 17% of patients.

USE IN SPECIFIC POPULATIONS

In MM, no overall difference in effectiveness of XPOVIO was observed in patients >65 years old when compared with younger patients. Patients 75 years old had a higher incidence of discontinuation due to an AR than younger patients, a higher incidence of serious ARs, and a higher incidence of fatal ARs.

Clinical studies in patients with relapsed or refractory DLBCL did not include sufficient numbers of patients aged 65 and over to determine whether they respond differently from younger patients.

The effect of end-stage renal disease (CLCR <15 mL/min) or hemodialysis on XPOVIO pharmacokinetics is unknown.

Please see full Prescribing Information.

To report SUSPECTED ADVERSE REACTIONS, contact Karyopharm Therapeutics Inc. at 1-888-209-9326 or FDA at 1-800-FDA-1088 or http://www.fda.gov/medwatch.

About Karyopharm Therapeutics

Karyopharm Therapeutics Inc. (Nasdaq: KPTI) is an innovation-driven pharmaceutical company dedicated to the discovery, development, and commercialization of novel first-in-class drugs directed against nuclear export and related targets for the treatment of cancer and other major diseases. Karyopharm's Selective Inhibitor of Nuclear Export (SINE) compounds function by binding with and inhibiting the nuclear export protein XPO1 (or CRM1). Karyopharms lead compound, XPOVIO (selinexor), received accelerated approval from the U.S. Food and Drug Administration (FDA) in July 2019 in combination with dexamethasone as a treatment for patients with heavily pretreated multiple myeloma. In June 2020, XPOVIO was approved by the FDA as a treatment for patients with relapsed or refractory diffuse large B-cell lymphoma. A Marketing Authorization Application for selinexor for patients with heavily pretreated multiple myeloma is also currently under review by the European Medicines Agency. In addition to single-agent and combination activity against a variety of human cancers, SINE compounds have also shown biological activity in models of neurodegeneration, inflammation, autoimmune disease, certain viruses and wound-healing. Karyopharm has several investigational programs in clinical or preclinical development. For more information, please visit http://www.karyopharm.com.

Forward-Looking Statements

This press release contains forward-looking statements within the meaning of The Private Securities Litigation Reform Act of 1995. Such forward-looking statements include those regarding Karyopharms beliefs regarding XPOVIOs ability to treat patients with relapsed or refractory diffuse large B-cell lymphoma and expectations related to other XPOVIO regulatory submissions. Such statements are subject to numerous important factors, risks and uncertainties, many of which are beyond Karyopharm's control, that may cause actual events or results to differ materially from Karyopharm's current expectations. For example, there can be no guarantee that any positive developments in the development or commercialization of Karyopharms drug candidate portfolio will result in stock price appreciation. Managements expectations and, therefore, any forward-looking statements in this press release could also be affected by risks and uncertainties relating to a number of other factors, including the following: the risk that the COVID-19 pandemic could disrupt Karyopharms business more severely than it currently anticipates, including by reducing sales of XPOVIO, interrupting or delaying research and development efforts, impacting the ability to procure sufficient supply for the development and commercialization of selinexor or other product candidates, delaying ongoing or planned clinical trials, impeding the execution of business plans, planned regulatory milestones and timelines, or inconveniencing patients; the adoption of XPOVIO in the commercial marketplace, the timing and costs involved in commercializing XPOVIO or any of Karyopharms drug candidates that receive regulatory approval; the ability to retain regulatory approval of XPOVIO or any of Karyopharms drug candidates that receive regulatory approval; Karyopharm's results of clinical trials and preclinical studies, including subsequent analysis of existing data and new data received from ongoing and future studies; the content and timing of decisions made by the U.S. Food and Drug Administration and other regulatory authorities, investigational review boards at clinical trial sites and publication review bodies, including with respect to the need for additional clinical studies; the ability of Karyopharm or its third party collaborators or successors in interest to fully perform their respective obligations under the applicable agreement and the potential future financial implications of such agreement; Karyopharm's ability to obtain and maintain requisite regulatory approvals and to enroll patients in its clinical trials; unplanned cash requirements and expenditures; development of drug candidates by Karyopharms competitors for indications in which Karyopharm is currently developing its drug candidates; and Karyopharms ability to obtain, maintain and enforce patent and other intellectual property protection for any drug candidates it is developing. These and other risks are described under the caption "Risk Factors" in Karyopharms Quarterly Report on Form 10-Q for the quarter ended March 31, 2020, which was filed with the Securities and Exchange Commission (SEC) on May 5, 2020, and in other filings that Karyopharm may make with the SEC in the future. Any forward-looking statements contained in this press release speak only as of the date hereof, and, except as required by law, Karyopharm expressly disclaims any obligation to update any forward-looking statements, whether as a result of new information, future events or otherwise.

Velcade is a registered trademark of Takeda Pharmaceutical Company Limited.

Contacts:

Investors: Karyopharm Therapeutics Inc. Ian Karp, Vice President, Investor and Public Relations 857-297-2241 | ikarp@karyopharm.com

Media:

FTI Consulting Simona Kormanikova or Robert Stanislaro 212-850-5600 |Simona.Kormanikova@fticonsulting.com or robert.stanislaro@fticonsulting.com

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Karyopharm Announces Publication of XPOVIO (Selinexor) Phase 2b SADAL Study Results in The Lancet Haematology - GlobeNewswire

Stem Cell Therapy Market 2020: Industry Growth, Competitive Analysis, Future Prospects and Forecast 2025 – 3rd Watch News

Stem Cell Therapy market report provides a complete assessment of this industry sector through a thorough analysis of various market segments. This study summarizes industry scenarios for current market position and industry size based on size and revenue share. Stem Cell Therapy market provides important information about the markets geographic environment and key organizations that define the markets competitive hierarchy.

Stem Cell Therapy market reports highlight key industry trends, revenue forecast formation, market size, sales volume and growth path. In addition to an in-depth assessment of numerous market segments, important data regarding growth drivers that will affect the profitability graph are mentioned in the report.

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The research reports provide reliable primary and secondary studies. It also relies on the most recent analytical skills to organize highly detailed and accurate research studies like this keyword market. This report also researches and evaluates the impact of Covid-19 outbreak on the Stem Cell Therapy industry, involving potential opportunity and challenges, drivers and risks. We present the impact assessment of Covid-19 effects on market growth forecast based on different scenario.

Read complete report with TOC at:https://www.adroitmarketresearch.com/industry-reports/stem-cell-therapy-market

Stem Cell Therapy Market report provides in-depth analysis and insights into developments impacting businesses and enterprises on global and regional level. The report covers the global Stem Cell Therapy Market performance in terms of revenue contribution from various segments and includes a detailed analysis of key trends, drivers, restraints, and opportunities influencing revenue growth of the global consumer electronics market. This report studies the global Stem Cell Therapy Market size, industry status and forecast, competition landscape and growth opportunity. This research report categorizes the market by companies, region, type and end-use industry.

Global Stem Cell Therapy market is segmented based by type, application and region.

Based on Type, the market has been segmented into:

Based on cell source, the market has been segmented into,

Adipose Tissue-Derived Mesenchymal SCs Bone Marrow-Derived Mesenchymal SCs Embryonic SCs Other Sources

Based on application, the market has been segmented into:

Based on therapeutic application, the market has been segmented into,

Musculoskeletal Disorders Wounds & Injuries Cardiovascular Diseases Gastrointestinal Diseases Immune System Diseases Other Applications

In terms of region, this research report covers almost all major regions of the world, such as North America, Europe, South America, the Middle East, and Africa and Asia Pacific. Europe and North America are expected to increase over the next few years. In Stem Cell Therapy market the Asia Pacific region are expected to grow significantly during the forecast period. The latest technologies and innovations are the most important characteristics of North America and the main reason the United States dominates the world market. The South American keyword market is also expected to grow in the near future.

The research study can answer the following Key questions: What are the prominent factors driving the Stem Cell Therapy Market across different regions? What will be the progress rate of the Stem Cell Therapy Market for the conjecture period 2020 2025? Who are the major vendors dominating the Stem Cell Therapy industry and what are their winning strategies? What are the challenges faced by the Stem Cell Therapy Market? What will be the market scope for the estimated period? What are the major trends shaping the expansion of the industry in the coming years?

Do You Have Any Query Or Specific Requirement? Ask to Our Industry Expert @https://www.adroitmarketresearch.com/contacts/enquiry-before-buying/691

About Us :

Adroit Market Research is an India-based business analytics and consulting company. Our target audience is a wide range of corporations, manufacturing companies, product/technology development institutions and industry associations that require understanding of a markets size, key trends, participants and future outlook of an industry. We intend to become our clients knowledge partner and provide them with valuable market insights to help create opportunities that increase their revenues. We follow a code Explore, Learn and Transform. At our core, we are curious people who love to identify and understand industry patterns, create an insightful study around our findings and churn out money-making roadmaps.

Contact Us :

Ryan Johnson Account Manager Global 3131 McKinney Ave Ste 600, Dallas, TX 75204, U.S.A Phone No.: USA: +1 972-362 -8199 / +91 9665341414

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Stem Cell Therapy Market 2020: Industry Growth, Competitive Analysis, Future Prospects and Forecast 2025 - 3rd Watch News

Century Therapeutics Announces Acquisition of Empirica Therapeutics – Business Wire

PHILADELPHIA--(BUSINESS WIRE)--Century Therapeutics today announced its acquisition of Empirica Therapeutics to leverage its iPSC-derived allogeneic cell therapies against glioblastoma (GBM).

We are pleased to welcome the Empirica team to the Century family. Their deep expertise and unique capabilities will allow us to accelerate efforts to develop iPSC derived immune effector cell products designed to treat and potentially cure brain cancer, said Lalo Flores, PhD, Chief Executive Officer of Century Therapeutics. GBM is a particularly aggressive, often treatment-resistant form of adult brain cancer with an average survival time of under two years. Together, we are in a stronger position to develop potentially curative cell therapies for this devastating disease.

Empirica Therapeutics was founded by Dr. Sheila Singh, MD, PhD, Professor of Surgery and Biochemistry and chief pediatric neurosurgeon at McMaster Childrens Hospital, and Dr. Jason Moffat, PhD, Professor of Molecular Genetics at the University of Toronto and an expert in functional genomics and gene-editing platforms. The companys science is based on a powerful integrative multi-omics platform, combined with its unique patient-derived, therapy-adapted models of recurrent GBM, that has led to the discovery and validation of novel brain tumor targets. Empiricas cutting edge preclinical models of recurrent GBM, have demonstrated the potential of CAR-T cell therapy in GBM, as published in a May 2020 Cell Stem Cell paper.

Our team is excited to become part of Century Therapeutics, whose iPSC-derived allogeneic cell therapies show immense potential for treating solid as well as hematologic malignancies, said Dr. Singh. Dr. Singh served as Empiricas CEO after co-founding the company with Chief Scientific Officer Dr. Moffat. We look forward to combining our unique patient-based cancer models with Centurys platform to create promising treatments for the patients who need them most, Singh said.

Janelle Anderson, PhD, Chief Strategy Officer at Century Therapeutics, shepherded the deal forming the subsidiary, which will be known as Century Therapeutics Canada and based in Hamilton, Ontario. Financial terms of the deal have not been disclosed.

About Century Therapeutics

Century Therapeutics is harnessing the power of stem cells to develop curative cell therapy products for cancer that overcome the limitations of first-generation cell therapies. Our genetically engineered, universal iPSC-derived immune effector cell products (iNK, iT) are designed to specifically target hematologic and solid tumor cancers. Our commitment to developing off-the-shelf cell therapies will expand patient access and provides an unparalleled opportunity to advance the course of cancer care. Century was launched in 2019 by founding investor Versant Ventures in partnership with Fujifilm and Leaps by Bayer. For more information, please visit http://www.centurytx.com.

About Glioblastoma (GBM)

Glioblastoma (GBM) is one of the most common types of primary brain tumor in adults and is almost uniformly lethal, with less than 5% of patients living beyond five years. GBM has an incidence rate of 3 per 100,000 people annually in the United States of America. The standard of care for GBM consists of tumor resection following by chemotherapy and radiation. Despite aggressive multimodal treatment, almost all patients experience relapse 7-9 months post-diagnosis and median survival has not extended beyond 16-20 months over the past decade. Recent studies suggest that the primary GBM tumor evolves significantly during the course of therapy and presents itself as a much more aggressive tumor at the time of recurrence. The treatment-resistant nature of GBM to standard therapies provides compelling motivation for developing novel treatment approaches.

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Century Therapeutics Announces Acquisition of Empirica Therapeutics - Business Wire

$14M Federal Grant to Research CAR-T Gene Therapy to Cure HIV – POZ

A group of collaborating scientists received a $13.65 million federal grant to study and develop a CAR-T therapy that will genetically modify immune cells and potentially cure HIV, according to a press release from the University of California, Los Angeles (UCLA).

The National Institutes of Health (NIH) funds the five-year grant as part of its effort to support HIV cure research. Participating researchers are affiliated with UCLA, the University of WashingtonFred Hutchinson Cancer Research Center and CSL-Behring, a biotech company based in the United States and Australia.

The overarching goal of our proposed studies is to identify a newgene therapy strategy to safely and effectively modify a patients own stem cells to resist HIV infection andsimultaneously enhance their ability to recognize and destroy infected cells in the body in hopes of curing HIV infection, said UCLAs Scott Kitchen, PhD, an associate professor of medicine in the division of hematology and oncology, in the press release. Kitchen will colead the research with Irvin Chen, PhD, director of the UCLA AIDS Institute at the David Geffen School of Medicine.

Transplantation ofHIV-resistant stem cells is the only approach that has ever led to a known cure for HIV(andlikely a second such cure). But stem cell transplants are risky and can only be done in people with HIVwho need them for cancer treatment. Using gene therapy tomodify an individuals own stem cells might be a safer way toachieve the same result.

The Food and Drug Administration first approved CAR-T therapywhich stands for chimeric antigen receptor T-cell therapyin 2017. Its used to treat some forms of cancer, but as POZs sister publication Cancer Health has reported, it hasnt been commonly used because it is expensive and must be custom made for each patient.

In the case of cancer treatment, CAR-T therapy involves taking a patients T cells and sending them to alab where they are genetically modified to recognize and attack the cancer. The resulting cells are then infused back into the individual after the person has received strong chemotherapy to kill off some of their existing immune cells to make room for the new ones.

In CAR-T therapy for HIV, blood-forming stem cells would be genetically engineered togive rise to T cells that would seek out and destroy cells infected with HIV.

In a recent early study of the approach, the UCLA scientists found that engineered CAR T cells destroyed HIV-infected cellsand lived for more than two years.

Our work under the NIH grant will provide a great deal of insight into ways the immune response can be modified to better fight HIV infection, said Chen, a professor of medicine and of microbiology, immunology and molecular genetics at the Geffen School of Medicine. The development of this unique strategy that allows the body to develop multiple ways to attack HIV could have an impact on other diseases as well, including the development of similar approaches targeting other types of chronic viral infections and cancers.

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$14M Federal Grant to Research CAR-T Gene Therapy to Cure HIV - POZ

Coronavirus and sex hormones baldness may be a risk factor and anti-androgens a treatment – The Conversation AU

Two small studies published recently suggested most men hospitalised with COVID-19 are bald, generating headlines around the world.

While this may sound strange, science does offer a plausible explanation.

Male pattern baldness is associated with high levels of male sex hormones called androgens. And androgens seem to play an important role in the entry of SARS-CoV-2, the coronavirus that causes COVID-19, into cells.

So its possible high levels of androgens might increase the risk of severe infection and death from COVID-19.

This hypothesis is important to identify people at risk and raises the possibility of new treatment strategies for COVID-19.

Read more: Why do more men die from coronavirus than women?

Its been obvious from early in the pandemic. Men are at greater risk of severe infection and death from COVID-19 than women.

There are several possible factors at play here. For one, men are more likely to suffer from chronic conditions known to pose a higher risk of serious illness from COVID-19. These include heart disease and diabetes.

Another is that mens immune systems are not as good as womens at warding off the severe effects of viral infections.

These factors are indirectly influenced by sex hormones. Now it seems sex hormones might also have a direct effect on SARS-CoV-2s ability to enter our cells and establish infection.

In one study of 122 male COVID-19 patients admitted to hospitals in Madrid, 79% were bald about double the population frequency.

Another small study in Spain observed a similar overrepresentaton of baldness among men hospitalised with COVID-19.

Read more: Starting to thin out? Hair loss doesn't have to lead to baldness

Male pattern baldness is strongly associated with a higher level of dihydrotestosterone (DHT), a more active derivative of testosterone, and one of the androgen family of male sex hormones.

Confirming this correlation between baldness and susceptibility to COVID-19 with larger samples, controlling for age and other conditions, would be significant. It would suggest a higher DHT level could be a risk factor for severe COVID-19.

SARS-CoV-2 enters human lung cells when a protein on the virus surface (the spike protein) latches onto protein receptors (ACE2 receptors) embedded in the cells surfaces.

How does this work? Recently scientists discovered that an enzyme called TMPRSS2 cleaves the SARS-CoV-2s spike protein, enabling it to bind to the ACE2 receptor. This allows the virus to enter the cell.

The gene that encodes TMPRSS2 is activated when male hormones, particularly DHT, bind to the androgen receptor (a protein on the surface of cells, including hair cells and lung cells).

So the more male hormone, the more androgen receptor binding, the more TMPRSS2 is present, and the easier it is for virus to get in.

A preliminary, non-peer-reviewed study which correlated the androgen levels of hundreds of people in the UK with COVID-19 severity supports this theory. Higher androgen level was associated with susceptibility to and severity of COVID-19 in men (but not women, who have much lower androgen levels in their blood).

The same researchers showed that inhibiting androgen receptors reduced the ability of SARS-CoV-2s spike protein to bind to ACE2 receptors on stem cells in culture.

Over- or underproduction of androgens in the body causes a variety of conditions in both men and women.

For instance, men with benign prostate enlargement overproduce androgen, as do women with polycystic ovary syndrome.

Many such conditions are treated with androgen deprivation therapy (ADT), which inhibits the production or effect of androgens. For instance, prostate cancer, in which cancer cell growth is fuelled by androgens, is routinely treated with ADT.

Conversely, some people have low androgen production, or mutations that affect the binding and action of androgens such as women with androgen insensitivity syndrome caused by mutations of the androgen receptor.

It will be important to find out whether, as the androgen hypothesis predicts, patients with over- or under-production of male hormones are at greater or lesser risk of COVID-19.

Read more: How can I treat myself if I've got or think I've got coronavirus?

If the androgen link holds up, this would encourage exploration of anti-androgens as a way to prevent and treat COVID-19.

Many anti-androgens are already approved for the treatment of other conditions. Some, like baldness treatments, have been used safely for years or decades. Some, like cancer treatments, can be tolerated for months.

A study which looked at men hospitalised with COVID-19 in Italy showed the rate of infection was four times lower in prostate cancer patients on ADT than in untreated cancer patients.

Perhaps a single dose given to someone who tests positive to SARS-CoV-2, or has just been exposed, would suffice to lower the chance of the virus taking hold.

But we need research to confirm this. Several androgen-suppressing drugs are now undergoing clinical trials to determine whether they reduce complications among men with COVID-19.

It will be important to verify that anti-androgen treatment works in the lungs as well as the prostate, and is effective in cancer-free patients. Wed also need to find out what dose is effective, and when it should be administered.

Anti-androgen treatments have several side effects in men, including breast enlargement and sexual dysfunction, so medical oversight is a must.

The androgen link could go a long way to explaining why men are more susceptible to COVID-19 than women. It also may explain why children younger than ten seem very resistant to COVID-19 because, until puberty, boys as well as girls make little androgen.

The more we know about who is at heightened risk from COVID-19, the better we can target information.

The androgen link also opens up an avenue for the discovery of drugs which might mitigate some of the impact of COVID-19 as it continues to sweep the globe.

Read more: COVID-19's deadliness for men is revealing why researchers should have been studying immune system sex differences years ago

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Coronavirus and sex hormones baldness may be a risk factor and anti-androgens a treatment - The Conversation AU

Cell Therapy Market 2020 Trend, Growth, Latest Technology & Application Analysis and Global Industry Opportunities Forecast to 2025 – Cole of Duty

The Global Cell Therapy market report presents market dynamics focusing on all the important factors market movements depend on. It includes current market trends with a record from historic year and prediction of the forecast period. This report is a comprehensive market analysis of the Cell Therapy market done on a basis of regional and global level. Important market analysis aspects covered in this report are market trends, revenue growth patterns market shares and demand and supply along with business distribution

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The most commonly used process of cell therapy aims to use healthy cells from a donor (Allogeneic) which is compatible or autogenic that is from the patient itself along with their alteration to increase their therapeutic ability. There are various complex steps involved in the process like genetic screening of cell, cell harvesting and reinfusion into the patients body. All these steps are complex and important and have therapeutic result on the patient. These advanced usage of cell therapy will result in growth of the cell therapy market size during the forecast period.

Cell therapy market trends indicate growth owing to the various regulations being approved by the government in the desire to provide quick relief to the patients. Furthermore, many healthcare industries are working in collaboration with the government to identify the various processes to ways to improve cell therapy. Furthermore, the cell therapy market size is also influenced by the commercialization of stem cells treatments.

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The Stem cell therapy segment dominates the types of cell therapy and is said to have the maximum success rate. It has a special feature that it differentiates into any category of cell, at the same time ensuring the individual identity is intact. Industry experts state that the stem cell would revolutionize regenerative medicine, owing to its extensive use in treatment of fatal disease like neurodegenerative, cardiovascular and cancer. The growth of cell therapy market size is also factored to the increased research and development about the same. However, at the same time the huge cost involved in the various processes involved might be hinder the market growth.

The cell therapy market size is segmented on various categories like Clinical-use, Research and Therapy type and region. On the basis of region, North America is projected to contribute the maximum share to the market owing to increased development.

Key players in the market are JCR Pharmaceuticals Co., Ltd., Kolon TissueGene, Inc.; and Medipost and many more.

Segmentation:

The various segments of cell therapy market size are:

By Use & Type Outlook

By Cell Therapy Type

By Therapeutic Area

By Therapy Type

By Region

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Cell Therapy Market 2020 Trend, Growth, Latest Technology & Application Analysis and Global Industry Opportunities Forecast to 2025 - Cole of Duty

Glioblastoma Multiforme Treatment (GBM) Market: Rise in Awareness Regarding Cancer and Novel Therapies to Boost the Market – BioSpace

Theglobal glioblastoma multiforme treatment marketis anticipated to rise significantly owing to key players adopting competitive strategies such as merger and acquisitions for marketing. According to a report by Transparency Market Research, the key players in the global glioblastoma multiforme treatment are adopting strategies such as development of biological drugs that helps in reducing the side effects in the patients which are caused due to consuming chemotherapeutic agents and immunosuppressant along with multiple therapies. The prominent players in the market are also collaborating with diagnostic laboratories so as to increase awareness level of the population in regards to the availability of options for treatment for the invasive diseases.

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Some of the key players operating in the global glioblastoma multiforme market are Celldex Therapeutics, Inc., Abbvie, Inc., Brostol-Myers Squibb Co., F.Hoffman La Roche, and Exellixis, Inc. During 2013, F.Hoffman La Roche was the most efficient and promising source of glioblastoma multiforme treatment all because of brain shuttle which was the companys novel drug delivery system.

The global glioblastoma multiforme treatment market is expected to rise at a healthy CAGR of 11.4% during the forecast period of 2014 to 2022. The global market is expected to attain a valuation of $US0.91 bn by the end of 2022. The global glioblastoma multiforme product segment is led by bevacizumab product and is expected to rise in demand during the forecast period as it is more efficient than temozolomide. Geographically, the glioblastoma multiforme treatment market is led by North America. This region is consuming larger share in the market is expected to dominate the global market during the forecast period.

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Rise in Awareness Regarding Cancer and Novel Therapies to Boost Global Glioblastoma Multiforme Market

The global glioblastoma multiforme treatment market is rising rapidly owing to increasing geriatric population. Rise in awareness about the brain tumor itself is generating demand for the glioblastoma multiforme treatment market. Various organizations across the globe are spreading awareness about the introduction of novel therapies thus, boosting the growth of market. Rise of modern techniques for diagnosis and rapid development of drug delivery technologies are likely to supplement the growth of the market. Increasing support from government to conduct research and development across the globe is adding fuel to the market.

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Development of healthcare infrastructure is one of the reasons for market growth. The unmet medical needs require desperate novel treatment strategies thus, generating demand for the market. The glioblastoma multiforme treatment pipeline include a mix of immunotherapy, small molecules, biological therapeutics and other types of therapeutics that makes it ideal for treatment of disease. Advanced introduced in molecular biology and gene technology also has the potential to provide lucrative novel possibilities for effective treatment of diagnosed patients.

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Recurrence of Disease Likely to Hamper Market Growth

The global glioblastoma multiforme treatment market is anticipated to face certain restrains in the market that might hamper the growth of the market. The current FDA approved treatments are likely to cause neurotoxicity in patients which might stagger the growth of market. This treatment is not resistance against DNA modifying agents thus, hampering its growth in the market. The migration of malignant cells inside the adjacent brain tissues increasing the complexity of surgery is also affecting the market. The treatment options lack efficiency as the mortality rate is characterized by rapid growth and poor survival rates. Survival rates of glioblastoma is 8.7% even after glioblastoma multiforme treatment being in the healthcare sector since last few years. The modalities have worked little to decrease the overall mortality rate of patients. Recurrence of the disease, invasiveness of GBM, and resistance of glioma stem cell against conventional modalities are other potential factors that will hamper the growth of the global glioblastoma multiforme treatment market.

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Glioblastoma Multiforme Treatment (GBM) Market: Rise in Awareness Regarding Cancer and Novel Therapies to Boost the Market - BioSpace

Why are more bald men in hospital with coronavirus? The answer could hold a treatment – ABC News

Twosmallstudiespublished recently suggested most men hospitalised with COVID-19 are bald, generatingheadlinesaround the world.

While this may sound strange, science does offer a plausible explanation.

Male pattern baldness is associated with high levels of male sex hormones called androgens.

And androgens seem to play an important role in the entry of SARS-CoV-2, the coronavirus that causes COVID-19, into cells.

So it's possible high levels of androgens mightincrease the riskof severe infection and death from COVID-19.

This hypothesis is important to identify people at risk and raises the possibility of new treatment strategies for COVID-19.

It's been obvious from early in the pandemic. Men areat greater riskof severe infection and death from COVID-19 than women.

There are severalpossible factorsat play here. For one, men are more likely to suffer from chronic conditions known to pose ahigher riskof serious illness from COVID-19.

These includeheart diseaseanddiabetes.

Another is that men's immune systems are not as good aswomen'sat warding off the severe effects of viral infections.

These factors are indirectly influenced by sex hormones. Now it seems sex hormones might also have a direct effect on SARS-CoV-2's ability to enter our cells and establish infection.

In one study of 122 male COVID-19 patients admitted to hospitals in Madrid,79 per cent were bald about double the population frequency.

Anothersmall studyin Spain observed a similar overrepresentation of baldness among men in hospital with COVID-19.

Male pattern baldness isstrongly associatedwith a higher level of dihydrotestosterone (DHT), a more active derivative of testosterone, and one of the androgen family of male sex hormones.

Confirming this correlation between baldness and susceptibility to COVID-19 with larger samples, controlling for age and other conditions, would be significant.

It would suggest a higher DHT level could be a risk factor for severe COVID-19.

SARS-CoV-2 enters human lung cells when a protein on the virus' surface (thespike protein) latches onto protein receptors (ACE2 receptors) embedded in the cells' surfaces.

How does this work? Recently scientists discovered that an enzyme calledTMPRSS2cleaves the SARS-CoV-2's spike protein, enabling it to bind to the ACE2 receptor. This allows the virus to enter the cell.

Breaking down the latest news and research to understand how the world is living through an epidemic, this is the ABC's Coronacast podcast.

The gene that encodes TMPRSS2 is activated when male hormones, particularly DHT, bind to the androgen receptor (a protein on the surface of cells, including hair cells and lung cells).

So the more male hormone, the more androgen receptor binding, the more TMPRSS2 is present, and the easier it is for virus to get in.

Apreliminary, non-peer-reviewed studywhich correlated the androgen levels of hundreds of people in the UK with COVID-19 severity supports this theory.

Higher androgen level was associated with susceptibility to and severity of COVID-19 in men (but not women, who have much lower androgen levels in their blood).

The same researchers showed that inhibiting androgen receptors reduced the ability of SARS-CoV-2's spike protein to bind to ACE2 receptors on stem cells in culture.

Over or underproduction of androgens in the body causes a variety of conditions in both men and women.

For instance, men withbenign prostate enlargementoverproduce androgen, as do women withpolycystic ovary syndrome.

Many such conditions are treated with androgen deprivation therapy (ADT), which inhibits the production or effect of androgens.

For instance, prostate cancer, in which cancer cell growth is fuelled by androgens, is routinely treated with ADT.

Conversely, some people have low androgen production, or mutations that affect the binding and action of androgens such as women withandrogen insensitivity syndromecaused by mutations of the androgen receptor.

It will be important to find out whether, as the androgen hypothesis predicts, patients with over- or under-production of male hormones are at greater or lesser risk of COVID-19.

If the androgen link holds up, this would encourage exploration of anti-androgens as a way to prevent and treat COVID-19.

Many anti-androgens arealready approvedfor the treatment of other conditions. Some, like baldness treatments, have been used safely for years or decades.

There are more than 100 coronavirus vaccines in the pipeline and almost a dozen that have made it to humans trials. ABC Health takes a look.

Some, like cancer treatments, can be tolerated for months.

A study which looked at men hospitalised with COVID-19 in Italy showed the rate of infection wasfour times lowerin prostate cancer patients on ADT than in untreated cancer patients.

Perhaps a single dose given to someone who tests positive to SARS-CoV-2, or has just been exposed, would suffice to lower the chance of the virus taking hold.

But we need research to confirm this. Several androgen-suppressing drugs are now undergoingclinical trialsto determine whether they reduce complications among men with COVID-19.

It will be important to verify that anti-androgen treatment works in the lungs as well as the prostate, and is effective in cancer-free patients.

We'd also need to find out what dose is effective, and when it should be administered.

Anti-androgen treatments have severalside effectsin men, including breast enlargement and sexual dysfunction, so medical oversight is a must.

The androgen link could go a long way to explaining why men are more susceptible to COVID-19 than women.

It also may explain why children younger than ten seem very resistant to COVID-19 because, until puberty, boys as well as girls makelittle androgen.

The more we know about who is at heightened risk from COVID-19, the better we can target information.

The androgen link also opens up an avenue for the discovery of drugs which might mitigate some of the impact of COVID-19 as it continues to sweep the globe.

Jenny Graves is a Distinguished Professor of Genetics and Vice Chancellor's Fellow at La Trobe University. This article originally appeared on The Conversation.

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Why are more bald men in hospital with coronavirus? The answer could hold a treatment - ABC News

4D physiologically adaptable cardiac patch: A 4-month in vivo study for the treatment of myocardial infarction – Science Advances

INTRODUCTION

Cardiovascular disease associated with myocardial infarction (MI) is a major cause of morbidity and mortality worldwide (1, 2). The heart is composed of dynamic and multicellular tissues that exhibit highly specific structural and functional characteristics. Adult cardiac muscle is thought to lack the ability to self-repair and regenerate after MI. Traditional cardiac patches serve as temporary mechanical supporting systems to prevent the progression of postinfarction left ventricular (LV) remodeling (2). However, the damaged myocardium is still unable to self-restore, and the subsequent maladaptive remodeling is typically irreversible (2). Because of the shortage of organ donors and the limited retention of cellular therapies, the field of cardiac engineering has emerged to generate functional cardiac tissues to provide a promising alternative means to repair damaged heart tissue (3, 4). In addition to playing a role in providing mechanical support, cellularized cardiac patches and scaffolds have also been investigated to restore the functionality of the damaged myocardium (5, 6). Compared to synthetic materials, hydrogel-based materials derived from, or partially derived from, natural sources can mimic the specific aspects of the tissue microenvironment and can support both cell adhesion and growth (7). Hence, these hydrogel-based materials can provide a more favorable matrix for the growth and differentiation of cardiomyocytes (7, 8). However, limitations of structural design and manufacturing techniques, as well as the low mechanical strength and weak processability of hydrogel-based patches, still make their clinical application challenging (3, 7, 8).

Because of the limited expansion and regeneration capacity of primary cardiomyocytes, the use of human induced pluripotent stem cellderived cardiomyocytes (hiPSC-CMs) provides a continuous cell source by which to produce terminally differentiated cells and avoid controversial ethical issues in biomedical research (9, 10). Although several studies have been performed with hiPSC-CMs to generate functional cardiac tissue constructs (11, 12), more studies are required to explore the interaction between hiPSC-CMs and the matrix microenvironment (i.e., scaffolds and other cells) for therapeutic improvement. Hence, further studies should focus on exploring material bioactivity, architectural design and manufacturing, the biomechanical properties of tissue constructs, and the long-term in vivo development of these tissue constructs, which will ultimately affect three-dimensional (3D) cell assembly and neotissue remodeling for clinical research purposes (2, 10, 13).

In this study, a 4D hydrogel-based cardiac patch was developed with a specific smart design for physiological adaptability (or tunability) using a beam-scanning stereolithography (SL) printing technique. Beam-scanning SL printing offers an effective methodology for creating microfabricated tissue constructs with photocurable hydrogels, which are able to achieve many essential requirements in manufacturing tissue micropatterns and macroarchitectures (14). The printing speed and laser intensity are able to be varied as required, which provides the ability to tailor the cross-linking degree of the inks and, therefore, affects the physicochemical properties of hydrogels. Moreover, it was observed that a light-induced graded internal stress, followed by a solvent-induced relaxation of material, drove an autonomous 4D morphing of the objects after printing (15, 16). It was found that this self-morphing process was able to achieve conformations that were nearly identical to the surface curvature of the heart. Moreover, taking the physiological features of the cardiac tissue and the physical properties of the hydrogel into account, a highly stretchable microstructure was created to allow for an easy switch of fiber arrangement from a wavy pattern to a mesh pattern, in accordance with the diastole and systole in the cardiac cycle. The specific design was expected to increase the mechanical tolerance of the printed hydrogel and to decrease the unfavorable effect of hiPSC-CM residence on the printed patches when exposed to the dynamic mechanics. By triculturing cardiomyocytes, mesenchymal stromal cells, and endothelial cells, the printed microfibers with specific nonlinear microstructures could reproduce the anisotropy of elastic epicardial fibers and vascular networks, which plays a crucial role in supporting the effective exchange of nutrients and metabolites, as well as guiding contracting cells for engineered cardiac tissue.

The cardiac muscle fibers mainly consist of longitudinally bundled myofibrils (cardiomyocytes and collagen sheaths), which are surrounded by high-density capillaries (17, 18). This anisotropic (directionally dependent) muscular architecture results in the coordinated electromechanical activity of the ventricles, which involves the directionally dependent myocardial contraction and the propagation of the excitation wave (19, 20). As can be observed by diffusion tensor imaging (DTI) (21, 22), a helical network of myofibers in the LV is organized to form a sheet structure, and the orientation of the fiber angles varies from approximately +60 to 60 across the ventricular wall (Fig. 1A). The visualization of the fiber structure illustrates the left-handed to the right-handed rotation of the fibers going from the epicardium to the endocardium in the LV (21). Computer-aided design (CAD)driven 3D printing offers a promising technique by which to transform the anatomical detail of cardiac fiber maps into a highly complex arrangement of fibers within an engineered cardiac tissue (23). Figure 1B shows that the spiral arrangement of 3D myocardial fibers crosses the ventricular wall (a left-handed to right-handed spiral of the fibers going from the epicardium to the endocardium) and their 2D mesh pattern projections at different angles.

(A) Photograph of the anatomical heart and the fiber structure of the LV visualized by DTI data. (B) Schematic illustration of a short-sectioned LV that illustrates the variation of fiber angle from the epicardium to the endocardium. The orientation (2D mesh pattern projection) of the fiber angles varies continuously with the position across the wall and distribution changes from the apical region to the basal region. (C) Curvature change of cardiac tissue at two different phases (diastole and systole) of the cardiac cycle, which occurs as the heartbeat and pumping blood. (D) CAD design of 3D stretchable architecture on the heart. It provides dynamic stretchability without material deformation or failure when the heart repeatedly contracts and relaxes. (E) Representation of a simplified geometric model of the fibers in the printed object. In the selected region, the angle (), the length of fiber (L), spatial displacement (D) and the ventricular curvature () are defined with systole (1) and diastole (2) states. (F) Mechanism of the internal stress-induced morphing process. Uneven cross-linking density results in different volume shrinkage after stress relaxation. Photo credit: Haitao Cui, The George Washington University (GWU).

Moreover, another specific feature of the cardiac tissue is the diastole and systole in the cardiac cycle induced by the contraction of cardiac muscle, which generates the force for blood circulation (8, 24). When taking the volume change of the heart into account, the arrangement of fibers is dynamically stretched in a selected region (Fig. 1C). Hence, the mesh pattern was changed to hexagon or wavy pattern in the 2D plane to adapt the change of ventricular curvature (Fig. 1D). It was able to create a highly stretchable structure with very limited deformability, which is expected to decrease the negative effect on the attached, susceptible cardiomyocytes. To mathematically characterize this design, we simplified the solid geometric model with a plane curve prototype to elaborate on the relationship between the redundant length of the stretchable structure (L) and the ventricular curvature () in the systole state (Fig. 1E). By the calculation, it can be estimated asL=cos1(1D22/2)D(1)where L is the redundant length of the stretchable structure from straight to curve, is the ventricular curvature in the systole state, and D is the approximate length of fiber in the diastole state (here, D = 400 m from our study). In the previous study, a light-induced 4D morphing phenomenon was demonstrated when using our customized beam-scanning SL printer (15, 16). The laser-induced graded internal stress, introduced through the printing process, is a major driving force of this 4D dynamic morphing (15, 16, 25). The uneven cross-linking density of photocrosslinkable inks generates the difference of modulus between the upper and lower surfaces of thin objects due to laser energy attenuation, leading to different volume shrinkage after stress relaxation (15). However, when multilayers were printed, the beam-scanning SL printing resulted in the repeated cross-linking of previous layers. The bottom layers had a higher cross-linking density. In this case, the bottom layer, which was cured the earliest, adhered to the substrate and could not shrink freely, while the top layer during printing could gradually and spontaneously shrink because of the release of internal stress. Thus, the printed objects have a tendency to bend toward the newly cured layer. We also found the humidity-responsive, reversible 4D phenomenon, which is swelling-induced stretching and dehydration-induced bending (15). After printing, the printed patch can transform from a 3D flat pattern to the 4D curved architecture when appropriate printing parameters are selected (Fig. 1F), which will be elaborated upon in the next section. It was hypothesized that by integrating a unique 4D self-morphing ability within the construct, the structural expandability of the design would improve the physiological adaptability of the engineered cardiac patch to the heart for in vivo cardiac regeneration.

A gelatin-based printable ink consisting of gelatin methacrylate (GelMA) and polyethylene glycol diacrylate (PEGDA) was used to create the anisotropic cardiac patch with myocardial fiber orientation. As a chemical derivative of gelatin [gelatin is derived from the hydrolysis of collagen, which is a major component of the extracellular matrix (ECM)], GelMA is a photocurable biomaterial with many arginine-glycine-aspartic acids and other peptide sequences that can significantly promote cell attachment and proliferation (14). The PEGDA solution was mixed with GelMA to decrease the swelling volume and to increase the mechanical modulus and structural stability of the printed hydrogels. The structural characteristics and mechanical properties of the printed hydrogels were determined by fiber design, printing parameters, the ink concentration, and mixing ratio of GelMA and PEGDA. To optimize the fiber design, stacked wavy architectures were generated with fiber width of 100, 200, and 400 m, fill density of 20, 40, and 60%, and fiber angles () of 30, 45, and 60 between each layer with two, four, and eight layers, respectively, using 10% GelMA and 10% PEGDA. The laser intensity, working distance, ink volume, and temperature were set to the same conditions as our previous studies (15, 26, 27) to eliminate the effect of the printing parameters. In this situation, the printing speed of the laser-based SL printing affects the photocuring performance, the structural accuracy (fineness), and the curvature of the 4D self-morphing. To ensure the complete solidification of the inks, a printing speed of 10 mm/s was set on the basis of our previous trials. By varying the printing speed (cross-linking density), a series of 4D self-morphing patches (wave pattern) were obtained with different curvatures. The mesh-patterned patches also exhibited a similar 4D morphing behavior. In all 4D self-morphing structures, the degree of deformation largely depends on the swelling, water content, and ionic strength. After 4D morphing, the wave-patterned patches maintained their wavy structure with a slight deformation. In our study, the bending of macrostructure does not significantly affect the microstructure. Figure 2A shows the curvature change of 4D morphing with increasing printing speed. Similar to the 4D morphing mathematical model by stress relaxation in the previous study (15), the relationship between the 4D curvature and printing speed can be modeled with the materials and printing parameters using the following equation1/r=4.7802.53lnv[mm1](2)where r is the radius of the object curvature after 4D morphing, is the printing speed (millimeters per second), and 0 is the shrinkage, which is dependent on both the material and the immersion medium. Here, 0 = 0.012 s1 in aqueous solution. The results demonstrated that the patches printed with a print speed (6 mm/s) had an appropriate curvature with the 4D morphing to obtain a sufficient integration with the LV surface of the mouse hearts.

(A) Curvature change of 4D morphing versus printing speed (means SD, n 6, *P < 0.05). (B) Printing accuracy of the hydrogel patches versus fiber width for different fill density (fd; means SD, n 6, *P < 0.05, **P < 0.01, and ***P < 0.001). (C) Color map of tensile moduli of the patches with varying GelMA and PEGDA concentrations. (D) Optical and 3D surface plot images of the patches. Scale bars, 200 m. (E) Average elasticity values of the wave-patterned patches in horizontal (x) and vertical (y) directions. Number sign (#) shows the statistical comparison between the horizontal and vertical directions (means SD, n 6, **P < 0.01 and ##P < 0.01). (F) Uniaxial tensile stress-strain curves of 5% GelMA and 15% PEGDA. Immunostaining of cell morphology (F-actin; red), sarcomeric structure (-actinin; green), gap junction [connexin 43 (Cx43); red], and contractile protein [cardiac troponin I (cTnI); red] on the patches on (G) day 1 and (H) day 7. Scale bars, 20 m. (I) Beating rate of hiPSC-CMs on the patch and well plate on day 3 and day 7 (means SD, n 6, *P < 0.05; n.s. no significant difference). BPM, beats per minute. Photo credit: Haitao Cui, GWU.

As is shown in Fig. 2B, the printing accuracy of different fiber width, fiber angle, layer number, and fill density of the fiber arrangement was investigated. The fiber pattern with a 100-m width showed significantly lower accuracy (50%) when compared to both fibers with 200-m (>70%) and 400-m (>90%) widths. In addition, the fiber pattern with a 60% fill density showed lower accuracy than the fiber pattern with 40% fill density. This implies that the fiber pattern with higher fill density or lower width is associated with more directional changes of the laser head per unit area, which is a function of the limitation of the printing resolution. In addition, there was no significant difference in the accuracy observed when increasing the number of stacked fibers (or fiber angles) due to the high reproducibility of the SL printing (fig. S1A). It was observed that smaller fiber widths or higher fill densities had a higher surface area per unit area, which was beneficial for the attachment of more cells, as the increased surface area better mimics the native myofibers. According to a previous study, the quantitative measurement of fiber angles showed that the dominant distribution of fiber angle was +45 to 45 from the epicardium to the endocardium (21). Therefore, a fiber pattern was printed with a 200-m width, 40% fill density, and a maximum angle of 45 for adjacent layers to optimize the mechanical properties of the hydrogel patches.

To test and measure the mechanical (both compression and tensile) modulus of the hydrogels, we varied the mixed weight ratio of GelMA and PEGDA from 5 to 20% (Fig. 2C and fig. S1, B and C). The results demonstrated that the mechanical moduli of the hydrogels fall within the range of the native myocardium modulus (101 to 102 kPa) in the physiological strain regime (28, 29). In addition, swelling testing showed that when GelMA was mixed with PEGDA, the printed hydrogels maintained excellent structural stability without notable swelling (fig. S1D). With consideration for the optimized ink viscosity and hydrogel elasticity, the inks used to fabricate our myofiber patches were formulated with concentrations of 5% GelMA and PEGDA (5, 10, and 15%) and were effectively printed on the basis of our design. Figure 2D shows the optical and 3D surface plot images of the patches printed by 5% GelMA and 15% PEGDA with a 200-m width, 40% fill density, and a 45 angle for adjacent layers. The fluorescent images of the 3D printed patches are also displayed (fig. S2A). The anisotropic behaviors of the wavy-patterned patches in the horizontal (x) and the vertical (y) direction demonstrated that uniaxial tension on the fiber pattern resulted in different deformation and stress generation in a directionally dependent manner (Fig. 2E). In particular, the stress-strain curve of the patch with 5% GelMA and 15% PEGDA was consistent with the tensile features of the native myocardium within the physiological strain regime (Fig. 2F) (19, 30). The fatigue was obvious along the y direction at the initial stage, which is attributed to the lower connectivity of fibers in the y direction and higher extendibility of the wavy-patterned fibers in the x direction. It is expected that this physiologically adaptable design would increase the stretchability and stability of the hydrogel patches, allowing them to absorb and release energy against the force of cardiac contraction (31, 32). Compared to the mesh design, the current architecture would allow for structural compliance of the hydrogel fibers without notable deformation. Moreover, the successfully printed patterns also well represent the microstructure of the native myocardial tissue, which is formed from collagen fibers and other ECM proteins, together with cardiomyocytes. However, the width of the myofibers within the myocardial tissue was much smaller (30 to 40 m) than the printed pattern (200 m), which is largely a limitation of the resolution of the currently available technology.

After the optimization of both the printing parameters and the ink formulation, the cardiac patches were manufactured with 5% GelMA and 15% PEGDA using a beam-scanning SL printing system. The wavy-patterned patches with a diameter of 8 mm and a thickness of 600 m were used to perform the in vitro studies, while the mesh-patterned patches of the same fiber volume fraction served as the control. By keeping the same surface area across the different construct patterns, we could ensure that there would be the same available cell number for each of the patches. Upon analysis, the redundant length (L) of the stretchable structure was determined to be around 140 m. Because of their capacity for restoring cardiac function in previous studies, hiPSC-CMs were cultured using the same protocol developed at the National Heart, Lung, and Blood Institute (NHLBI) (33). Before cell seeding, a thin layer of Matrigel was precoated on the well plate or patches surface to improve the hiPSC-CM adhesion. By day 7, spontaneous contractions of monolayer hiPSC-CMs were observed (fig. S2B and movie S1), and immunostaining results demonstrated that hiPSC-CMs displayed specific myocardial protein expression, including sarcomeric alpha-actinin (-actinin), connexin 43 (Cx43), and cardiac troponin I (cTnI). (fig. S2, C and D). The cell-laden ink was printed by mixing 1 106 per ml of hiPSC-CMs with 5% GelMA and 15% PEGDA. However, a decrease in the metabolic activity of the hiPSC-CMs was observed, and the distinct cardiac beating behavior was not evident (fig. S2, E and F). These observations were likely the result of the limited 3D space within the hydrogel. Hence, a postseeding approach was then applied to fabricate the cardiac patches. Compared to the cell-laden samples, the hiPSC-CMs seeded on the patches showed significantly higher proliferation and beating rate. The attached hiPSC-CMs exhibited spontaneous contractions along the fibers on day 3 (movie S2). Moreover, the immunostaining images revealed robust F-actin, -actinin, Cx43, and cTnI expression of hiPSC-CMs on the printed patches (Fig. 2G). After 7 days of culture, the hiPSC-CMs began to form aggregation structures atop the printed fibers and began to contract synchronously across the entire patches, indicating electrophysiological coupling of the cells (Fig. 2H). Moreover, the beating rate of the hiPSC-CMs on the printed patch was notably similar to that of the monolayer hiPSC-CMs on the seeded well plate (Fig. 2I).

According to previous studies, human mesenchymal stromal cells (hMSCs) have been widely used in coculture with cardiomyocytes and endothelial cells to improve cell viability, myogenesis, angiogenesis, cardiac contractility, and other functions due to their paracrine activity (34, 35). Hence, a triculture of hiPSC-CMs, human endothelial cells (hECs), and hMSCs was performed to fabricate the vascularized cardiac patches. The analysis of cell tracker staining was conducted to investigate the distribution of different cells in the triculture and to optimize the cell ratio in the triculture system based on the calculated fluorescent value. The results demonstrated that when the initial ratio of seeded cells was 4:2:1, the resultant cellular proportion of hiPSC-CMs, hECs, and hMSCs was ~ 30, ~40, and ~30%, respectively, at confluency, which falls within the range of the cellular composition [25 to 35% cardiomyocytes, 40 to 45% endothelial cells, and ~30% supporting cells (i.e., fibroblasts, smooth muscle cells, hematopoietic-derived cells, and others)] of the human heart (Fig. 3A) (36, 37). After 7 days of culture, the printed construct showed a uniform cell distribution and longitudinal alignment of the cells along the fiber direction (Fig. 3B and fig. S3). Autofluorescence images of green fluorescent proteintransfected (GFP+) hiPSC-CMs on day 7 indicated that the cardiomyocytes exhibited an increased proliferation rate on the patches, as compared to initial seeding on day 1, and were able to generate spontaneous contractions (Fig. 3C and fig. S4). After 7 days of culture, fluorescent image analysis of CD31 [platelet endothelial cell adhesion molecule-1 (PECAM-1)] stained patches revealed that the wave-patterned patch had a higher density of capillary-like hEC distribution along the fibers when compared to the mesh control (Fig. 3D). In our previous studies, we found that the beam-scanning laser is able to cure the ink for the macroarchitectural formation together with the aligned microstructure present on the printed fibers (16). Hence, the hECs were easily grown along the fiber direction. Moreover, the iPSC-CMs exhibited an excellent contraction-relaxation behavior along the fibers in the wave-patterned patches, potentially allowing for a local mechanical stimulation on the fiber resident cells, which can help to improve the growth and distribution of hECs. In addition, immunostaining analysis of the cTnI and the marker von Willebrand factor (vWf) indicated that our wave-patterned patches contained a dense network of vascular cells interwoven with hiPSC-CMs distributed over the printed fibers, and the ratio of hiPSC-CMs and hECs was largely retained with 45% hiPSC-CMs (Fig. 3, E and F). Furthermore, it has been well established that the electrical activity at the cardiomyocyte membrane is controlled by ion channels and G proteincoupled receptors, which are usually actuated by calcium transients (38). The electrophysiological profiles of the cardiac patches demonstrated the generation of typical calcium oscillation waveforms and synchronous beating along with the printed fibers across the entire patches after 3 days (Fig. 3G). Over the next 7 days of culture, the amplitudes of calcium transients gradually increased to a stable state, suggesting the establishment of excellent functional contraction-relaxation and electrophysiological behaviors (Fig. 3, H and I).

Cell distribution of tricultured hiPSC-CMs (green), hECs (red), and hMSCs (blue) on the cardiac patches using cell tracker staining after (A) 1 day of confluence and (B) 7 days of culture. Scale bars, 200 m. (C) Autofluorescence 3D images of GFP+ hiPSC-CMs on the wave-patterned patch on day 1 and day 7. Scale bars, 100 m. (D) Immunostaining of capillary-like hEC distribution (CD31; red) on the hydrogel patches. Scale bars, 200 m. Immunostaining (3D images) of cTnI (red) and vascular protein (vWf; green) on the (E) wave-patterned and (F) mesh-patterned patches. Scale bars, 200 m (3D image) and 20 m (2D inset). Calcium transients of hiPSC-CMs on the hydrogel patches recorded on (G) day 3 and (H) day 7. (I) Peak amplitude of the calcium transients of hiPSC-CMs on the mesh- and wave-patterned patches on day 3, day 7, and day 10 (means SD, n 30 cells, *P < 0.05).

To enhance the effectiveness of our design, a custom-made bioreactor consisting of a dynamic flow device and a mechanical loading device was constructed to provide a physiologically relevant environment, which could incorporate both mechanical strain and hydrodynamics (Fig. 4A) (39). The patches were compressed in the radial direction using positive pressure between the piston and stationary polydimethylsiloxane (PDMS) holder to yield a mechanical loading, which mimics the contractile behavior of the in vivo human heart (fig. S5A). During the dual mechanical stimulation (MS), the applied force was stored in the patch as strain energy, which was then responsible for returning the patch to its original shape. The out-of-plane loading (bending) determines the stretch and recovery of the fibers, while the fluid shear stress regulates cellular orientation (Fig. 4B). Both were applied to the patches and transferred onto the cells to improve the vascularization and myocardial maturation of the resident cells.

(A) Schematic illustration of a custom-made bioreactor to apply dual MS for the maturation of engineered cardiac tissue. PMMA, polymethylmethacrylate. (B) Both the out-of-plane loading and fluid shear stress applied to the patches. (C) Immunostaining of cTnI (red) and vWf (green) on the wave-patterned patch under MS condition (+MS) versus nonstimulated control (MS). Scale bars, 50 m. (D) Immunostaining of the -actinin (green) and Cx43 (red) on the wave-patterned patch under MS condition (+MS) versus nonstimulated control (MS). Scale bars, 20 m. (E) Cross-sectional immunostaining of the sarcomeric structure (Desmin; green) and vascular CD31 (red) on the patches under MS condition (+MS). Scale bars, 50 m. (F) The beating rate of hiPSC-CMs on the printed patches under MS condition (+MS) versus nonstimulated control (MS) on day 14 (means SD, n 6, *P < 0.05). BPM, beats per minute. Relative gene expression of (G) myocardial structure [myosin light chain 2 (MYL2)], (H) excitation-contraction coupling [ryanodine receptor 2 (RYR2)], and (I) angiogenesis (CD31) on the patches under MS condition (+MS) versus nonstimulated control (MS) on day 1, day 7, and day 14 (means SD, n 9, *P < 0.05, **P < 0.01, and ***P < 0.001).

After 2 weeks of dynamic culture, we observed a higher expression of mature cardiomyogenic cTnI and angiogenic vWf in MS samples and more longitudinally aligned vascular cells, when compared to the nonstimulated control (Fig. 4C and fig. S5, B and C). In addition, the patches exhibited enhanced sarcomere density and junctions, as identified by the -actinin and Cx43 expression of the hiPSC-CMs (Fig. 4D and fig. S5, D and E). Cross-sectional images illustrated that the high density of cell assemblies on the wave-patterned patches was evident under MS conditions and these assemblies exhibited a higher expression of desmin and CD31 markers compared to the mesh control (Fig. 4E). This suggests that the specific design of the cardiac patch was able to impede the mechanical force against material deformation in our dynamic system to support repeatable stretch cycles and decrease the negative effect on the cells. Moreover, the assembled hiPSC-CM fibers on the cardiac patch spontaneously and synchronously contracted along with the fiber direction (Fig. 4F and movie S3). However, the entire patch did not exhibit in-plane contraction or macroscopic movement itself due to the high mechanical resistance of the hydrogel material. In general, it was observed that the wave-patterned patch was capable of stretching to a physiologically relevant fiber pattern compared to the mesh design, which could improve cell guidance and elongation along the fiber direction.

Consistent with the immunostaining results, the expression of cardiac-related genes, including genes associated with sarcomeric structure, excitation-contraction coupling, and angiogenesis, was significantly increased on day 14 compared to day 7. These results suggest that there was an increase in maturation of the iPSC-CMs on the printed patches over time (Fig. 4, G to I, table S1, and fig. S6). After the application of the MS, the expression of the MYL2 (myosin light chain 2) and RYR2 (ryanodine receptor 2) genes were significantly increased in our wave-patterned patches on day 14, as compared to the mesh control. This demonstrates that our specific patch design can enhance iPSC-CM contractile and electrical function under MS. Moreover, the angiogenic CD31 gene was also considerably up-regulated on the wave-patterned patches with perfusion culture. In general, the gene expression on day 14 was up to 28-fold higher compared to day 1, and an average of 5.5-fold increase in the expression of maturation genes was observed with the MS condition as compared to the nonstimulated groups. This observation provides further evidence that significantly enhanced cardiac maturation is achievable on the printed patches when specific structural design and physiologically relevant culture conditions are combined.

Having used the dynamic culture system to enhance the maturation of hiPSC-CMs in vitro, we further investigated the vascularization and myogenic maturation of the printed cardiac patches in vivo. Ischemia-reperfusion (I/R) is a major contributor to the myocardial damage resulting from MI in humans (40). Murine models of I/R injury provide an effective means to simulate clinical acute or chronic heart disease for cardiovascular research (41, 42). Hence, a chronic MI model with I/R injury was created to assess the functional effects of cardiac patch implantation (43, 44). The cellularized and acellular patches were implanted onto the epicardium of immunodeficient nonobese diabetic severe combined immunodeficient gamma (NSG) mice and were assessed for long-term development 4 months after implantation. Compared to the classic MI model, our I/R injury model produced a shortened recovery time, less inflammation, and higher survival rates. The patches (4-mm diameter by 600-m thickness in size) were entirely positioned over the infarcted (ischemia) site of the mouse hearts (Fig. 5, A and B, and movie S4). To assess the direct interaction (structure and cells) between the patch and the host epicardium, we did not apply fibrin glue. After 3 weeks of implantation, optical images showed that the cellularized patches had a firm adhesion to the epicardium regardless of the contractile function of the heart (Fig. 5C). Hematoxylin and eosin (H&E) assessment confirmed the robust epicardial engraftment of the cell-laden patches, which contained high-density cell clusters after 3 weeks (Fig. 5D). Fluorescent images also showed that the GFP+ hiPSC-CMs (green) maintained higher viability after 3 weeks of implantation (Fig. 5E). The immunofluorescence analysis of cTnI and vWf illustrated the existence and development of hiPSC-CMs and hECs on the cellularized patches in the treated region with time. The image results showed that many vascular cells were found spanning the interface of the patch and myocardium and expanded within the myocardial patch (Fig. 5F).

(A) Optical image of surgical implantation of the patch. (B) Optical image of a heart I/R MI model after 4 months. (C) Optical image of the implanted cellularized patch at week 3, exhibiting a firm adhesion (inset). (D) H&E image of the cellularized patch at week 3, demonstrating the cell clusters with a high density (yellow arrowhead). Scale bar, 400 m. (E) Fluorescent image of (GFP+) iPSC-CMs on the patch at week 3, showing a high engraftment rate (yellow arrowhead). Scale bar, 100 m. (F) Immunostaining of cTnI (red) and vWf (green) on the cellularized patch at week 3. Scale bar, 100 m. (G) H&E images of mouse MI hearts without treatment (MI) and with cellularized patch (MI + patch) at week 10. Infarct area after MI (yellow circles). Scale bars, 800 m. (H) Cardiac magnetic resonance imaging (cMRI) images of a mouse heart with patch at week 10. Left (spin echo): the position of the heart and implanted patch. Right (cine): the blood (white color) perfusion from the heart to the patch. Photo credit: Haitao Cui, GWU.

After 10 weeks of implantation, H&E staining results showed that the infarct sizes of the patch groups (~3.8 0.7%) were smaller than the MI-only control (~8.4 1.1%), suggesting that the patch can provide mechanical support to effectively prevent LV remodeling (Fig. 5G and fig. S7A). The images and videos of the cardiac magnetic resonance imaging (cMRI) demonstrated that the implanted patch was able to contract and relax with the heartbeat of the mouse and also confirmed its excellent structural durability along with evident blood perfusion from the heart to the patch (Fig. 5H and movie S5). Fluorescent images also showed that the GFP+ hiPSC-CMs (green) maintained higher viability after 10 weeks of implantation (fig. S7B). hiPSC-CMs with cTnI+-expressing capillaries (vWf+) were observed in the patches, where the lumen structure of neovessels was also clearly visible (Fig. 6A). Together, these results indicated that epicardially implanted patches exhibited robust survival and vascularization in vivo. Moreover, a high density of capillaries identified by human-specific CD31 expression was observed within the cellularized patches, suggesting that the implanted hECs and hMSCs increased the vessel formation throughout the patch in vivo (Fig. 6B).

(A) Immunostaining of cTnI (red) and vWf (green) on the cellularized patch at week 10. Scale bar, 800 m. Border of the heart (white dashed line) and capillary lumen (white arrow). Scale bar (enlarged), 100 m. (B) Immunostaining of human-specific CD31 (red) on the cellularized patch at week 10, showing the generated capillaries by hECs. Scale bar, 800 m. Border of the heart (white dashed line). Scale bar (enlarged), 100 m. (C) Immunostaining of cTnI (red) and vWf (green) on the cellularized patch for 4 months, showing the increased density of the vessels. Scale bar, 800 m. Border of the heart (white dashed line) and capillary lumen (white arrow). Scale bar (enlarged), 100 m. (D) Quantification of capillaries with vWf staining data for 10 weeks and 4 months (means SD, n 6, *P < 0.05 and **P < 0.01). (E) Immunostaining of human-specific CD31 (red) on the cellularized patch for 4 months. Scale bar, 800 m. Border of the heart (white dashed line). Scale bar (enlarged), 100 m. (F) Immunostaining of -actinin (green) and human-specific CD31 (red) on the cellularized patch at month 4. Scale bars, 50 m.

By 4 months, H&E staining results showed a higher cell density and smaller infarct area (~5.6 1.5%) in the cellularized patch compared to the acellular patch and MI groups (~14.3 2.3%; fig. S7C). The GFP+ fluorescent results demonstrated that the hiPSC-CMs retained high engraftment rates (fig. S7D). Similar to what was observed at 10 weeks, the cellularized patch had a strong integration within the epicardium, whereas the cell-free patch had a weak adhesion by month 4. In addition, the cMRI images also illustrated that the implanted patch had an excellent connection with the mouse heart (fig. S7E). The positive expression of mature cTnI further indicated the presence of advanced structural maturation of the hiPSC-CMs in the treated region, and the capillaries were also substantially identified by the vWf staining in the cell-laden patch groups (Fig. 6C). The images also demonstrated more progressive implant vascularization with a 1.5-fold increase in blood vessel density after 4 months of implantation, when compared to cell-free controls (Fig. 6D). The data were counted by five randomly selected fields in each heart. However, the fraction of humanized vessels was not significantly increased, as identified by the human-specific CD31 staining (Fig. 6E). Therefore, the increased vascularization and vascular remodeling in vivo likely originated from the host vessel ingrowth as opposed to the implanted human vessels at the initial stage of implantation. However, differing from the in vitro results, the cross-sectional images of the implants did not exhibit substantial sarcomeric structure (identified by -actinin) when compared to the native cardiac tissue (Fig. 6F). It can be observed that the cell aggregation in the vertical direction showed a disordered assembly and 3D stacking behavior. Overall, these results demonstrated that the printed patches underwent progressive vascularization, largely remained on the epicardial surface of the LV over the 4-month implantation period, and effectively covered all of the infarcted area. Cardiac function was also evaluated at different time points after injury via cMRI assessments. The LV ejection fraction of all patch groups (~64.1 3.5%) was higher than the MI-only group (~56.1 1.5%); however, there was no difference observed between the cellularized patch group and the cellular group.

MI is a leading cause of morbidity and mortality worldwide. The hiPSC-CMs provide a potentially unlimited source for cardiac tissue regeneration, as they are able to recapitulate many of the physiological, structural, and genetic properties of human primary cardiomyocytes and heart tissue (13). Current methods for the treatment of MI largely involve injecting cardiomyocytes directly into the epicardial infarct zone; however, because of the limited engraftment capacity of the injected cardiomyocytes, injection therapies are not fully satisfactory in restoring cardiac functionality (13). Several studies have been performed with hiPSC-CMs to generate functional cardiac tissue constructs using tissue engineering techniques (7, 10). However, the physiological features of hiPSC-CMs are more sensitive to the physicochemical and bioactive properties of the scaffolds in which they reside. Compared to synthetic polymers, natural polymer-based hydrogels can provide a more favorable matrix for the growth and differentiation of cardiomyocytes (7). However, limitations of structural design and manufacturing techniques, as well as the low mechanical strength and weak processability of hydrogel-based patches, still make their clinical application challenging.

As a proof of concept, a physiologically adaptable 4D cardiac patch, which recapitulates the architectural and biological features of the native myocardial tissue, has been printed using a beam-scanning SL printing technique. The smart patches provided mechanical support, a physiologically tunable structure, and a suitable matrix environment (elasticity and bioactivity) for cell implantation. Successful vascularization of the patches allowed for the continued metabolic demand of hiPSC-CMs and permitted them to remain both viable and functional throughout the in vivo study. Robust engraftment and development of the implanted patches were further confirmed using a more clinically relevant and mechanically realistic environment. The study results showed that the anisotropic mechanical adaption of the printed patches improved the maturation of cardiomyocytes and vascularization in vitro under MS. After implantation into the murine MI model, the printed patches exhibited high levels of in vivo cell engraftment and vascularization.

In a previous study, an engineered auxetic design was developed to give a cardiac patch a negative Poissons ratio, providing it with the ability to conform to the demanding mechanics of the heart (31). Here, we further propose and develop a 4D physiologically adaptable design for a cardiac patch, which includes hierarchical macro- and microstructural transformations attuned to the mechanically dynamic process of the beating heart. Therein, a physiological adaptation is evident in the response of cells (or genes) to the microenvironmental change. Similarly, the adaptive responses of the resident cells on the scaffolds to replicate the native microenvironment are crucial for the in vivo integration of engineered tissue with and the host tissue after implantation. In addition, a highly biomimetic in vitro culture system was developed with dynamic perfusion and mechanical loading to enhance cardiac maturation. Overall, the current work has several unique features: (i) a greatly improved mechanical stretchability of the hydrogel patches; (ii) a triculture of hiPSC-CMs, hMSCs, and hECs, which is necessary to obtain a complex cardiac tissue; (iii) an application of in vitro dual MS by which to improve cardiac maturation; and (iv) in vivo long-term development of the printed patches in a murine chronic MI model to evaluate the potential therapeutic effect.

Although several studies have shown that cell transplantation can greatly improve cardiac function in the MI model, no substantial evidence supporting these improvements in cardiac function was found in the current study. In the MS culture studies, it was observed that the entire patch did not exhibit in-plane contraction. The high mechanical resistance of the hydrogel could be a reason as to why the patches did not significantly enhance cardiac function in vivo. Moreover, as is known, the implanted human cardiomyocytes exhibit different beating frequencies and other biological features within the host mouse heart (13, 45, 46). Hence, integrated functional repair was not observed in this study. Differing from the hypothesis of the functional enhancement, the in vivo results revealed that the enhanced cardiomyogenesis and neovascularization of humanized patches did not significantly improve the cardiac function of the MI mice. The patches provided cellularized niche conditions so that most of the implanted cardiomyocytes were alive, although they still exhibited immature 3D sarcomeric organization. Moreover, the neovascularization effects of the cell-laden patches at the infarct region were also confirmed, suggesting that paracrine effects appear to be a major contributing factor. Although there was a lack of functional integration between humanized patches with the hearts of the host mice, the printed patches exerted no adverse effects on the host cardiac function or vulnerability to arrhythmias. The cell transplantation improved the cellularized environment in the infarct area by, at least in part, promoting angiogenesis and increasing cell retention. The multiple cell transplantation with a high density of hiPSC-CMs retention in the murine MI model suggests that this goal may have been at least partially achieved. While applying humanized grafts to infarcted rodent hearts would likely confirm the paracrine effects, large animal studies are warranted to further evaluate the therapeutic efficacy toward a potential clinical use.

In the future, a physiologically relevant large animal study, such as a porcine or nonhuman primate MI model, will serve as a more realistic means to study cardiac patch engraftment (42, 46). Moreover, developments in advanced printing techniques will enable the development of thick, scale-up ready myocardial tissue, which will play a prominent role in the ultimate success of clinical cardiac engineering therapies. In general, the developed cardiac patch has a great potential to provide a desired therapeutic effect on the in vitro maturation and in vivo retention of hiPSC-CMs, based on the previously unidentified engineering design and manufacturing process.

These studies were designed to evaluate the concept of a 4D cell-laden cardiac patch with physiological adaptability as a potential method for the treatment of MI. To evaluate this technology, we tricultured hiPSC-CMs, hMSCs, and hECs to obtain a complex cardiac tissue and also applied in vitro dual MS to replicate the physiologically relevant conditions for the improvement of regenerated myocardial function. A 4-month in vivo study was conducted to assess the performance of our 4D cell-laden cardiac patches, where the animals were randomly assigned to different experimental groups before the experiments. The sample size and power calculation were determined on the basis of our experience with the experimental models and the anticipated biological variables. Typically, the power is 0.8, and the significance level is 0.05 when the effect size is determined by the minimum sample difference divided by the SD (GPower 3.1). All experiments were blinded and replicated. The sample sizes and replicates are shown in the figure legends.

Ten grams of gelatin (type A, Sigma-Aldrich) was dissolved in 100 ml of deionized water with stirring at 80C. Next, 5 ml of methacrylic anhydride was added dropwise into the gelatin solution. After reaction at 80C for 3 hours, the reactant was dialyzed in deionized water for 5 days at 40C to remove any excess methacrylic acid. The GelMA solid product was finally obtained through lyophilization. The ink solutions consisted of GelMA [with concentrations of 0, 5, 10, 15, or 20 weight % (wt %)], 1 wt % 2-hydroxy-4-(2-hydroxyethoxy)-2-methylpropiophenone (Irgacure 2959, photoinitiator), and PEGDA (Mn = 700; Sigma-Aldrich; with concentration of 0, 5, 10, 15, and 20 wt %). Solutions were prepared using a 1 phosphate-buffered saline (PBS) solution.

Our 3D computational myocardium model was programmed on the basis of DTI results and was simplified to the basic geometry to replicate the fiber orientation of the native myocardium. The wave (or hexagonal) microstructure was configured with different diameter fibers and fiber angels between each layer, while the mesh microstructure served as a control. To optimize the fiber design, wave or mesh architectures with side lengths of 100, 200, and 400 m and internal angles () of 30, 45, and 60 between each layer were designed with two, four, and eight layers, respectively. All cardiac construct models were saved as .stl files, processed using the Slic3er software package, and were transferred to the 3D printer. Representative CAD models of the constructs were calculated and predicted for surface area, porosity, and other structural characteristics.

Printed cardiac patches were manufactured using our customized table-top beam-scanning SL printer, which is based on the existing Printrbot rapid prototyping platform. This system consists of a movable stage and a 110-m fiber optic-coupled solid-state ultraviolet (355 nm) laser mounted on an X-Y tool head for three-axis motion. The laser scans and solidifies the top layer of ink in a reservoir, and a movable platform lowers the construct further into the ink, covering it with the next material layer. For this study, the effective spot size of the emitted light was 150 50 m and had an energy output of ~20 uJ at 20 kHz. The ability to alter the frequency of the pulsed signal facilitates power control at the material surface ranging from 40 to 110 mW.

Different stacked architectures with fiber widths of 100, 200, and 400 m; fill densities of 20, 40, and 60%; and fiber angels of 30, 45, and 60 between each layer were manufactured with two, four, and eight layers, respectively. The printing accuracy of the patterns was quantified by the mean trajectory error (Et) compared to the designed shape. Et=1ni=0n(x(i)xt(i))2+(y(i)yt(i))2, where n 20 is the number of data points collected. Compressive and tensile mechanical properties were measured with an MTS criterion universal testing system equipped with a 100-N load cell (MTS Systems Corporation). For compressive testing, the printed patches (2 cm by 2 cm) having different microstructures were placed on the tester. The crosshead speed was set to 2 mm/min, and Youngs modulus was calculated from the linear region of the compressive stress-strain curves. For the tensile testing, the samples were mounted on to custom-made copper hooks affixed to the tester and were pulled at a rate of 1 mm/min to a maximum strain of 20%. Youngs modulus was calculated from the linear portion of the tensile stress-strain curve. In addition, the representative uniaxial tensile stress-strain plots for the latitudinal and longitudinal specimens of myocardial constructs were used to evaluate the anisotropic mechanical properties. The swelling behavior was evaluated by quantifying the weight gain after equilibrium swelling. The printed samples were immersed in PBS at 37C for 7 days. The swelling ratios of hydrogel matrices were calculated as equilibrium mass swelling ratio (SR). SR = (wt w0)/w0 100%, where w0 is the original weight of printed samples and wt is the equilibrium weight of samples after swelling.

hiPSC-CMs and GFP+ hiPSC-CMs were cultured in cardiomyocyte basic medium using the same protocol developed by our collaborators at the NHLBI (33). hECs (human umbilical vein endothelial cells; Thermo Fisher Scientific) were cultured in endothelial growth medium consisting of Medium 200 and low-serum growth supplement. hMSCs (harvested from normal human bone marrow, Texas A&M Health Science Center, Institute for Regenerative Medicine) were cultured in mesenchymal stem cell growth medium consisting of minimum essential medium, 20% fetal bovine serum, 1% l-glutamine, and 1% penicillin/streptomycin. All experiments were performed under standard cell culture conditions (in a humidified, 37C, 95% air/5% CO2 environment) with hECs and hMSCs of six cell passages or less.

After the patches were printed, iPSC-CMs, hECs, and hMSCs with different ratios were seeded on the patch constructs (the surface of the patch was precoated with a thin layer of Matrigel, Corning). The tricultured cardiac patches were maintained in the mixed medium at a 1:1:1 ratio for further characterization and in vitro cell study. hECs and hMSCs were prestained with CellTracker Orange CMRA Dye and CellTracker Blue CMAC Dye (Molecular Probes) and were then seeded onto the constructs. After 1, 3, and 7 days of coculture, cells were imaged using a Zeiss 710 confocal microscope. Cell proliferation on days 1, 3, and 7 were quantified using a cholecystokinin-8 solution [10% (v/v) in medium; Dojindo]. After 2 hours of incubation, the absorbance values were measured at 570 and 600 nm on a photometric plate reader (Thermo Fisher Scientific). The spreading morphology and arrangement of hMSCs and hECs were characterized using the double staining of F-actin (red, Texas Red; 1:200) and nuclei [blue, 4,6-diamidino-2-phenylindole dihydrochloride (DAPI), Thermo Fisher Scientific; 1:1000].

A customized bioreactor system consisting of a mechanical loading device and a dynamic flow device was used to culture our cell-laden constructs. The dynamic flow device is composed of four parts: a perfusion chamber, a flow controller, a nutrient controller, and a gas controller (5% CO2/95% air). The culture medium was perfused through the constructs using a digital peristaltic pump (Masterflex, Cole-Parmer) over the whole experimental period, which facilitated the efficient transfer of nutrients and oxygen. A shear stress was set at 10 dynes/cm2 (which is within the range of the shear stress observed in microcirculation), and a flow rate of 8.4 ml/min was selected (the viscosity of medium is ~7.8 104 Ns/m2) (47, 48). A PDMS holder was used to both firmly mount the patches within a polymethylmethacrylate chamber and to maintain the patch structure during cell culturing and MS to prevent undesired movement and damage. The patches were compressed at the speed of 60 times/min in the radial direction using positive pressure between the piston and the stationary holder to yield the mechanical force. The calculated (preload) contractile force per unit area was ~50 mN/mm2 along the fiber direction to match those in the native cardiac tissue. The cardiac constructs were placed in the bioreactor system and incubated at 37C for 7 and 14 days.

After 1 and 2 weeks of culture, cellular functions including cardiomyogenesis and angiogenesis were assessed using an immunofluorescence method. After the predetermined period, the cell-laden constructs were fixed with formalin for 20 min. The samples were permeabilized in 0.1% Triton X-100 for 15 min and were then incubated with a blocking solution [containing 1% bovine serum albumin, 0.1% Tween 20, and 0.3 M glycine in PBS] for 2 hours. The cells were then incubated with primary antibodies at 4C overnight. After incubation with primary antibodies, secondary antibodies were introduced to the samples in the dark for 2 hours at room temperature, followed by incubation with a DAPI (1:1000) solution for 5 min. All images were obtained using the confocal microscope, and protein quantifications were performed using ImageJ (49). In addition, the immunostaining analysis was performed with sliced fragments that were cut with a cryostat microtome. The primary antibodies that were used for our study were purchased from Abcam and included anti-actinin (1:500), antihuman-specific CD31 (human-specific PECAM-1; 1:500), anti-desmin (1:1000), anti-Cx43 (1:1000), anti-cTnI (1:500), and anti-vWf (1:1000). The secondary antibodies were purchased from Thermo Fisher Scientific and included anti-mouse Alexa Fluor 594 (1:1000) and goat anti-rabbit Alexa Fluor 488 (1:1000).

To evaluate the functional beating behavior, iPSC-CMs were observed and recorded using the inverted microscope and confocal microscopy. The Ca2+ that triggers contraction comes through the sarcolemma and plays an important role in excitation-contraction coupling of the heart beating. After the predetermined period, intracellular calcium transients were recorded under the fluorescent microscope at a wavelength of 494 nm over 30 to 120 s. Movies were analyzed with an ImageJ software to measure the fluorescence intensities for two to eight regions of interest (F) and for three to eight background regions (F0) per acquisition.

The cardiac tissue constructrelated gene expression was analyzed by a real-time quantitative reverse transcription polymerase chain reaction (RT-PCR) assay. Specifically, myocardial structure [cTnI (TNNI3), cTnT (TNNI2), MYL2, MYL7, myosin heavy chain 6 (MYH6), MYH7, and -actinin 2 (ACTN2)], excitation-contraction coupling (calsequestrin 2, RYR2, phospholamban, sodium/calcium exchanger 1, and adenosine triphosphatase sarcoplasmic/endoplasmic reticulum Ca2+ transporting 2), and angiogenic genes (vWf and CD31) were studied to detect the cardiomyocyte and vascular maturation processes in the constructs. The primers that were used are shown in the Supplementary Materials (table S1). Briefly, the total RNA content was extracted using TRIzol reagent (Life Technologies). The total RNA purity and concentration were determined using a microplate reader [optical density at 260/280 nm within 1.8 to 2.0). The RNA samples were then reverse-transcribed to complementary DNA using the Prime Script RT Reagent Kit (Takara). RT-PCR was then performed on the CFX384 Real-Time System (Bio-Rad) using SYBR Premix Ex Taq according to the manufacturers protocol. The gene expression levels of the target genes were normalized against the housekeeping gene glyceraldehyde 3-phosphate dehydrogenase. The relative gene expression was normalized against the control group to obtain the relative gene expression fold values, which were calculated via the 2Ct method.

The in vivo development of the printed cellularized constructs was evaluated using a xenograft model of transplantation into 6-week-old NSG mice. All the animal experiments were approved by the Institutional Animal Care and Use Committee of the NHLBI. A method of random and blinded group allocation was applied to our animal experiments. The murine model with chronic MI was created via an I/R procedure to analyze implanted cell development, remodeling, and infarction treatment for 4 months. The printed cellularized patches (4-mm diameter by 600-m thickness in size) were prepared in sterile conditions and were surgically implanted into the LV ischemic area of each NSG mouse through a limited left lateral thoracotomy. The acellular patch and MI-only groups served as controls. At different time points after implantation, cMRI was performed to visualize the beating heart and to evaluate the structural/functional parameters, which included the ejection fraction, end-systolic volume, end-diastolic volume, stroke volume, and cardiac output, among others. Last, animals were euthanized, and the specimens, along with the adjacent tissues, were collected for further examination.

Histology was used to qualitatively examine the samples at different time points and included the examination of cellular cytoplasm, red blood cells, and cell distributions. The samples were fixed in formalin, processed, and were embedded in optimal cutting temperature compound for cryosection histology. The samples were cut into 5- to 10-m slides. The mean infarct size was also calculated through the histologic studies. The infarct size was expressed as the percentage of the affected myocardial area (necrosis + inflammatory tissue) in all myocardial areas analyzed, with infarct area % = infarct area 100/total myocardial area. Immunostaining was used to evaluate the in vivo cardiomyogenesis and angiogenesis of the implants. The antibodies were used in a manner similar to the in vitro study. The number of neovessels, including sprouted capillaries, was counted per section, and a total of five sections per sample were analyzed. All of the slide analyses were performed using the ImageJ software.

All data are presented as the means SD. A one-way analysis of variance (ANOVA) with Tukeys test was used to verify statistically significant differences among groups via Origin Pro 8.5, with P < 0.05 being statistically significant (#, *P < 0.05; ##, **P < 0.01; ###, ***P < 0.001).

Acknowledgments: We would like to thank J. Zou and Y. Lin (IPSC core, NHLBI) for providing hiPSC-CMs and S. Anderson (Animal MRI core, NHLBI) for carrying out the MRI analysis. Funding: We also thank American Heart Association Transformative Project Award, NSF EBMS program grant #1856321, and NIH Directors New Innovator Award 1DP2EB020549-01 for financial support. Author contributions: H.C., C.L., Y.H., and L.G.Z. conceived the ideas and designed the experiments. H.C., X.Z., and S.-j.L. conducted the in vitro experiments. H.C., Y.H., C.L., Z.-x.Y., and H.S. carried out animal experiments. H.C., C.L., T.E., Y.H., Z.-x.Y., S.Y.H., M.B., M.M., J.P.F., and L.G.Z. performed data analysis and prepared the manuscript. Competing interests: A patent application describing the approach presented here was filed by H.C., L.G.Z., and Y.H. (US 62/571,684; PCT/US20 18/055707). The authors declare that they have no other competing interests. Data and materials availability: All data needed to evaluate the conclusions in the paper are present in the paper and/or the Supplementary Materials. Additional information related to this paper may be requested from the authors.

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4D physiologically adaptable cardiac patch: A 4-month in vivo study for the treatment of myocardial infarction - Science Advances

SFARI | SFARI workshop explores challenges and opportunities of gene therapies for autism spectrum disorder – SFARI News

On February 67, 2020, the Simons Foundation Autism Research Initiative (SFARI) convened a two-day workshop to explore the possibility of gene therapies for autism spectrum disorder (ASD), a neurodevelopmental condition associated with changes in over 100 genes. Inspired by the recent, stunning successes of gene therapy for the fatal neuromuscular disorder spinal muscular atrophy (SMA)1, and by the accumulation of genes confidently associated with ASD2, SFARI welcomed a diverse collection of researchers to begin to think about whether a similar approach could be taken for ASD. Because gene therapy attempts to fix what is broken at the level of a causative gene, it would offer a more direct and imminent strategy than mitigation of the many and as yet mostly unclear downstream effects of a damaged gene.

The workshop was organized in 20 talks and several discussion panels, which tackled many outstanding issues, including how to choose candidate target genes and predict outcomes; how to optimize vectors for gene delivery; how to decide when to intervene; which animal models to develop; how to find appropriate endpoints for clinical trials and understand the available regulatory pathways. SFARI also raised the question of how its funding might best propel gene therapy efforts amid the emerging, complex ecosystem of academic laboratories, biotech companies, and pharmaceutical industries.

Even the opportunity to have this discussion is very rewarding, said SFARI Investigator Matthew State of the University of California, San Francisco (UCSF), one of the investigators who directed teams of geneticists to analyze the Simons Simplex Collection (SSC).

These efforts have offered up multiple potentially feasible therapeutic targets. Though rare, de novo disruptive mutations in the highest confidence ASD genes often result in severe impairment characterized not only by social difficulties, but also by intellectual disability and seizures. The combination of a single gene mutation of large effect coupled with particularly severe outcomes that include ASD are likely to offer the most immediate targets for gene therapy. For now, this leaves out a large number of individuals with autism for whom genetic causes are not yet known and are likely the result of a combination of many small effect alleles across a large number of genes.

Highlights from talks and discussion panel, chaired by Rick Lifton of Rockefeller University

In the first talk of the workshop, State brought the group up to speed on ASD genomics. The most recent tally from exome-sequencing in simplex cases of ASD highlighted 102 genes in which rare mutations confer individually large risks2. In contrast, the task of identifying common variants carrying very small risks remains quite challenging, with less than a half dozen alleles so far identified with confidence3. The rare, disruptive mutations that result in loss of function of one gene copy are an attractive focus for gene therapy because of the tractability of targeting a single spot in the genome per individual and because, in the vast majority of cases, there remains a single unchanged allele. This points to ways to boost gene and/or protein expression back toward the normal state by leveraging the unaffected copy. But both the limited number of cases known so far combined with the possibility that different mutations to the same gene may have different effects complicate thinking about how to prioritize targets for gene therapy.

State made several points that were continually touched on throughout the workshop. Many ASD genes are highly expressed during midfetal development in the cortex, and additional experiments will need to determine whether and how long a window of opportunity may be present for successful gene therapy postnatally. Given the relatively small number of people with these conditions, new clinical trial designs are needed that dont rely on comparisons between large control and intervention groups (see also Bryan Kings talk below).

Beyond the gene-crippling mutations found in the exome, disruptions to transcription may also dramatically raise risk for autism and may be corrected with a type of gene therapy using ASOs. SFARI Investigator Stephan Sanders of UCSF focused on the role of splicing, the process by which an initial transcript is turned into messenger RNA by removal of introns and joining together of exons. Splicing is disrupted in at least 1.5 percent of individuals with ASD4, and possibly many more, as suggested by transcript irregularities found in postmortem autism brain5. Sanders described Illuminas Splice AI project in which machine-learning helps predict noncoding variants that can alter splicing, including those beyond typical splice sites found near a gene6. As a result of incorporating sequence information around and between splice sites, this computational tool detected more mutations with predicted splice-altering consequences in people with ASD and intellectual disability than in those without the condition.

An ASO designed to bind specific portions of RNA could conceivably correct errors in transcription. ASOs have already been approved for use in other disorders in order to skip exons, retain exons or to degrade mRNA. Unlike other forms of gene therapy, ASOs do not permanently alter the genome, making it a kind of gene therapy lite. This reversibility has both disadvantages (having to re-infuse the ASO every few months) and advantages (multiple opportunities to optimize the dose and target; serious adverse effects are not permanent).

Jonathan Weissman of UCSF discussed the available toolbox for controlling gene expression developed by many different laboratories. To turn genes on or off, he has developed a method to combine CRISPR with an enzymatically inactive (dead) Cas9, which can then be coupled with a transcriptional activator (CRISPRa) or repressor (CRISPRi)7 (Figure 2). In the case of loss-of-function mutations, Weissman outlined strategies to make the remaining good allele work harder: increase transcription via CRISPRa, decrease mRNA turnover, increase translation of a good transcript via modification of upstream open reading frames (uORFs) or increase a proteins stability, possibly through small molecules acting on the ubiquitin system8. That said, the effects on a cell may be complicated. Using Perturb-Seq screens, Weissman described genetic interaction manifolds that show nonlinear mapping between genotype and single cell transcriptional phenotypes9. Additionally, Weissman summarized recent work from his laboratory that has identified large numbers of uORFs that result in polypeptides, some of which affect cellular function.

SFARI Investigator Michael Wigler of Cold Spring Harbor Laboratories echoed the idea of a gene-therapy strategy that increases expression of the remaining good copy of a gene, especially given that in his estimate, 45 percent of simplex cases of autism carried a de novo, likely disrupting variant. He also called attention to the uterine environment, especially the challenge posed by expression of paternally derived antigens in the fetus and the impact of a potential maternal immune response, and the need to understand how it interacts with de novo genetic events.

Highlights from talks and discussion panel, chaired by Arnon Rosenthal of Alector

The discussion turned to finding ways of getting genes into the central nervous system. The AAV is the darling of gene therapy, given that it does not replicate and is not known to cause disease in humans. A version that can cross the blood-brain barrier (AAV9) was used to deliver a gene replacement to children with SMA intravenously; though this effectively delivered the genetic cargo to ailing motor neurons in the spinal cord, it does not work that well at delivering genes throughout the brain.

Ben Deverman of the Stanley Center at the Broad Institute of MIT and Harvard detailed his efforts to optimize AAV for efficient transduction of brain cells through a targeted evolution process: his team engineers millions of variants in the capsid of the virus, then screens them for entry into the nervous system and transduction of neurons and glia. This has yielded versions (called AAV-PHP.B and AAV-PHP.eB) that more efficiently enter the brain10,11. One successfully delivered the MECP2 gene to the brain of a Rett syndrome mouse model, resulting in ameliorated symptoms and an extended lifespan12. Unfortunately, these viruses dont work in human cells or in all mouse strains. A quick mouse genome-wide association study (GWAS) revealed that the Ly6a gene mediates efficient blood-brain barrier crossing of AAV-PHP.B and AAV-PHP.eB13. Now his group has identified Ly6a-independent capsids that may translate better to humans. He also noted that the PHP.B vectors have tissue specificity for brain and liver.

With an estimated 87 percent of autism-associated genes raising risk through haploinsufficiency (having only one functional gene copy out of the two), SFARI Investigator Nadav Ahituv of UCSF made the case for approaches that boost expression of the remaining good copy of a gene through endogenous mechanisms a strategy he called cis-regulation therapy. This method also provides a way to work around the small four kb payload of AAV, which strains to contain cDNA of many autism genes. A recent study by his group used CRISPRa targeted at an enhancer or promoter of SIM1 and promoter of MC4R, both obesity genes, in mice. Using one AAV vector for a dCas9 joined to a transcription activator, and another AAV vector having a guide RNA targeting either a promoter or an enhancer, and a guide RNA targeting a promoter, the researchers injected the vectors together into the hypothalamus, which resulted in increased SIM1 or MC4R transcription and reversed the obesity phenotype brought on by loss of these genes14. Targeting regulatory elements had the added benefit of tissue specificity, and there seemed to be a ceiling effect for SIM1 expression, which suggested an endogenous safeguard against overexpression at work. He is now collaborating with SFARI Investigator Kevin Bender, also at UCSF, to apply this approach to the autism gene SCN2A.

Botond Roska of the Institute of Molecular and Clinical Ophthalmology in Basel, Switzerland pointed out that getting genes to the cells where they are needed is crucial when treating eye diseases. Off-target effects there can induce degeneration of healthy cells. For this reason, Roska and his group have created AAVs that target specific cell types in the retina by developing synthetic promoters that efficiently promote expression of the viruss cargo15. The promoters they designed were educated guesses based on four approaches: likely regulatory elements close to genes expressed with cell-type specificity in the retina, conserved elements close to cell typespecific genes, binding sites for cell typespecific transcription factors and open chromatin close to cell typespecific genes. Screening a library of these in mouse, macaque and human retina revealed some with high cell-type specificity (Figure 3). Importantly, macaque data predicted success in human retina much better than did mouse data. In preliminary experiments, and more relevant to gene therapy for ASD, these cell-specific vectors also had some success in mouse cortex, for example lighting up parvalbumin neurons or an apparently new type of astrocyte.

Roska also described new methods for delivery, in which nanoparticles are coated with AAV, then drawn into the brain using magnets16. This magnetophoresis technique allows a library of experimental AAVs to be tested at the same time in one monkey. Steering nanoparticles with magnets gives more control of vector placement and gene delivery. He argued that these in the future could access even deep structures of the brain.

Highlights from talks and discussion panel, chaired by Steven Hyman of the Broad Institute at MIT and Harvard

Kathy High of Spark Therapeutics reviewed the story of gene therapy for spinal muscular atrophy (SMA) type 1. Though she was not directly involved in that research, she is well aware of the regulatory atmosphere surrounding gene therapy, given that Spark Therapeutics developed the first approved AAV-delivered gene for a form of retinal dystrophy. The SMA story is a useful case study in that an ASO-based therapy (nusinersen, marketed as Spinraza), approved in 2016, set the stage for a gene-replacement therapy, marketed as Zolgensma (onasemnogene abeparvovec). Ultimately, the amount of data supporting Zolgensmas approval was modest: a Phase one dose study of 15 infants1, and an ongoing Phase three trial of 21 infants and safety data from 44 individuals. Yet the approval was helped by the dramatic results and clear endpoints: those receiving a single intravenous infusion of an AAV9 vector containing a replacement gene all remained alive at 20 months of age, whereas only 8 percent survived to that age in the natural history data, which compiles the diseases untreated course. High mentioned that maintaining product quality for gene therapeutics may prove trickier than for typical medications.

The attractive, highly customizable nature of gene therapy might have a regulatory downside in that different vector payloads, even when designed to do the same thing, could invite separate approval processes. Though not knowing how regulatory agencies would view this, High said that their perspectives are bound to evolve as more gene therapy trials are completed.

Getting to ASD-related syndromes, Bender talked about SCN2A, which encodes the sodium channel Nav1.2. SCN2A mutations in humans can be gain of function or loss of function; gain-of-function mutations are associated with early onset epilepsy, and loss-of-function mutations with intellectual disability and ASD. In a mouse model missing one copy of SCN2A, Bender and his group have discovered a role for SCN2A in action potential generation in the first week after birth, and in synaptic function and maturation afterward through regulation of dendritic excitability18 (Figure 4). Using AAV containing CRISPRa constructs developed with the Ahituv lab, the researchers successfully increased SCN2A expression, and recovered synapse function and maturity, even when done several weeks postnatally. Getting the appropriate dosage is critical since gain-of-function mutations are linked to epilepsy. However, Bender reported even when SCN2A expression increased to double normal levels, no hints of hyperexcitability appeared. We might be able to overdrive this channel as much as we want and actually may not have risk of producing an epileptic insult, he said. Next steps are to figure out the developmental windows for intervention, evaluate changes in seizure sensitivity and extend this kind of cis-regulatory approach to other ASD genes.

Angelman syndrome is another condition that attracts interest for gene therapy, in part because neurons already harbor an appropriate replacement gene. Angelman syndrome stems from mutations to the maternally inherited UBE3A gene, which is particularly damaging to neurons because they only express the maternal allele, while the paternal allele is silenced by an antisense transcript. SFARI Investigator Mark Zylka of the University of North Carolina and colleagues showed in 2011 that this paternal allele could be unsilenced with a cancer drug in a mouse model of Angelman syndrome19. Since then, three companies have built ASOs to do the same thing, and these are going into clinical trials. To get a more permanent therapeutic, Zylka has been developing CRISPR/Cas9 systems to reactivate paternal UBE3A, and preliminary experiments show that injecting this construct into the brains of embryonic mice, and then again at birth, results in brain-wide expression of paternal UBE3A and is long-lasting (at least 17 months). Zylka is now making human versions of these constructs. He later noted rare cases of mosaicism for the Angelman syndrome mutation people with 10 percent normal cells in blood have a milder phenotype20, which suggests that even inefficient transduction of a gene vector could help.

Zylka also made a case for prenatal interventions in Angelman syndrome: studies of mouse models indicate that early reinstatement of UBE3A expression in mouse embryos rescues multiple Angelman syndrome-related phenotypes, whereas later postnatal interventions rescue fewer of these21; for humans, a diagnostic, cell-based, noninvasive prenatal test will be available soon22; ultrasound-guided injections into fetal brain of nonhuman primates have been developed23; prenatal surgeries are now standard of care for spinal bifida; and intervening prenatally decreases the risk of an immunogenic response to an AAV vector or its cargo. During the discussion, it was noted that another benefit of acting early was that less AAV would be needed to transduce a much smaller brain; however, a drawback is the lack of data on Angelman syndrome development from birth to one year of age. This natural history would be necessary for understanding whether a prenatal therapy is more effective than treatment of neonates.

SFARI Investigator Guoping Feng of the Massachusetts Institute of Technology has been investigating SHANK3, a high-confidence autism risk gene linked to a severe neurodevelopmental condition called Phelan-McDermid syndrome, which is marked by intellectual disability, speech impairments, as well as ASD. SHANK3 is a scaffold protein important for organizing post-synaptic machinery in neurons. Mouse studies by Feng have shown that SHANK3 re-expression in adult mice that have developed without it can remedy some, but not all, of their phenotypes, including dendritic spine densities, neural function in the striatum and social interaction24. Furthermore, early postnatal re-expression rescued most phenotypes. This makes SHANK3 a potential candidate for gene therapy; however, it is a very large gene 5.2kb as a cDNA that is difficult to fit into a viral vector. To get around this, Fengs group has designed a smaller SHANK3 mini-gene as a substitute for the full-sized version. Preliminary experiments show that AAV delivery of the mini-gene can rescue phenotypes like anxiety, social behavior and corticostriatal synapse function in SHANK3 knockout mice. Feng also discussed his success in editing the genome in marmosets and macaques using CRISPR/Cas9 technology and showed data from a macaque model of SHANK3 dysfunction25. These models may help test gene therapy approaches and identify biomarkers of brain development closely related to the human disorder.

For people with rare conditions brought on by even rarer mutations, individualized gene therapies can provide a pathway for treatment. SFARI Investigator Timothy Yu of Boston Childrens Hospital/Harvard described his N-of-1 study in treating a girl with Batten disease, a recessive disorder in which a child progressively loses vision, speech and motor control while developing seizures. In a little over a year, an ASO that targeted her unusual splice-site mutation in the CLN7 gene was designed, developed and given intrathecally to the girl26. The lift was in negotiating with the FDA and working with private organizations, not just in the science, Yu said. After a year of treatment with the ASO (dubbed milasen after the girl, Mila), there were no serious adverse events; seizure frequency and duration had decreased (Figure 5); and possibly her decline had slowed. Though she remains blind, without intelligible speech and unable to walk on her own, she was still attentive and could respond happily to her familys voices. The highly personalized framework for this drugs approval is completely different from how medications meant for populations are approved, and it opens a regulatory can of worms, Yu said, though he added that the regulators were willing to countenance drug approval for an individuals clinical benefit.

Rett syndrome is a neurodevelopmental condition caused by mutations to the MECP2 gene that has a substantial research base in mouse models. Over 10 years ago, mouse models highlighted the possibility for therapeutics in this condition when Rett-associated phenotypes were rescued by adding back MECP2, even in adulthood27. This reversibility has spurred interest in gene therapy for Rett syndrome, but getting the MECP2 dose right is critical, said Stuart Cobb of the University of Edinburgh and Neurogene: just as too little MECP2 leads to Rett syndrome, too much also results in severe phenotypes. For this reason, it would be nice to package a replacement MECP2 gene with other regulatory elements to control its expression, but this results in constructs that do not fit into viral vectors. To make more room, Cobb and his colleagues have been able to chop away two-thirds of the MECP2, reserving two domains that interact to make a complex on DNA (Figure 6). Mice with this mini-gene are viable and have near normal phenotypes; likewise, injecting this mini-gene into MECP2-deficient mice extended their survival28. Doubling the dose, however, substantially lowered survival. Putting in safety valves to prevent overexpression is going to be quite important, he said. One idea is to add back a construct containing only the last two exons of MECP2, which is where most Rett mutations land. These would then be spliced into native transcripts (called trans-splicing), and thus their expression controlled by endogenous regulatory elements.

Underscoring the double-edged sword of MECP2 dosage, Yingyao Shao from Huda Zoghbis lab at Baylor described an MECP2 duplication syndrome (MDS) in humans, which features hypotonia, intellectual disability, epilepsy and autism. Experiments in an MDS mouse model, which carries one mouse version and one human version of MECP2, recapitulates some of the phenotypes of the human condition and can be rescued by an ASO targeting the human allele29. Shao described work to optimize the ASO for translation into humans, which involved developing a more humanized MDS model that carries two human MECP2 alleles. An acute injection of the ASO was able to knock down MECP2 expression in a dose-dependent manner in these mice, and RNA levels dropped a week after injection, with protein levels falling a week later. MECP2 target genes also normalized their expression level, and one maintained this for at least 16 weeks post-injection. The ASO also rescued behavioral phenotypes of motor coordination and fear conditioning, but not of anxiety; these corrections followed the molecular effects, and these timelines would be important to keep in mind while designing clinical trials. Shao also noted that overtreatment with the ASO resulted in Rett-associated phenotypes, but that this was reversible, which suggests that some fine-tuning of dosing in humans might be possible.

To avoid overtreatment and toxicity of any MDS-directed therapy, Mirjana Maletic-Savatic, also at Baylor, is leaving no stone unturned in a hunt for MDS biomarkers that can predict, in each individual, the safety of a particular dose and regimen. Such biomarkers would also help monitor individuals during treatment, give information about target engagement and identify candidates for a particular treatment. Anything found to be sensitive to expression levels of MECP2 could also be useful for Rett, though she noted that MECP2 levels measured in blood do not track linearly with gene copy number. Thus, because of interindividual variability, her approach is to collect a kitchen sink of data deriving composite biomarkers that accurately reflect the stage and severity of disease in a given case. She and her colleagues are collecting clinical, genetic, neurocircuitry (such as EEG and sleep waves), immunology and molecular data detected in blood, urine and CSF. These measures are also being explored in induced neurons derived from skin samples of people with MDS. She highlighted two interrelated potential biomarkers in the blood of those with this condition; both measures are downstream targets of MECP2 and are responsive to ASO treatment.

Highlights from Early detection and clinical trial issues talks and panel discussion, chaired by Paul Wang of SFARI

Coming up with objective measures of a persons status either their eligibility for a treatment, or whether the treatment has engaged with its target or even whether the treatment is effective is a real necessity in autism-related conditions, which comprise multiple interrelated behaviors. Eye-tracking methodology may provide such a marker, argued SFARI Investigator Ami Klin of Emory University. Focusing on the core social challenges of autism, Klin, Warren Jones and colleagues have been studying children as they view naturalistic social scenes to quantify their social attention patterns. This has revealed how remarkably early in development social visual learning begins and that this process is disrupted in infants later diagnosed with ASD prior to features associated with the condition appearing. By missing social cues, autism in many ways creates itself, moment by moment, Klin said. In considering gene therapy, it may be useful to know that eye looking (how much a subject looks at a persons eyes, an index of social visual engagement) in particular and social visual engagement in general are under genetic control30; that eye-tracking differences emerge as early as 26 months of age; and that homologies in social visual engagement exist between human babies and nonhuman infant primates.

In getting to a point to test gene therapies, identifying those who need them is essential. Wendy Chung of Columbia University and the Simons Foundation illustrated how diagnosis is yoked closely to therapy. To illustrate this, she described her pilot study of newborn blood spots to screen for SMA; at the start, no treatment was available, but the screen identified newborns for a clinical trial of nusinersin. Notably, the screen only cost an additional 11 cents per baby. In the three years since her pilot screen began, the FDA approved two gene therapies for SMA and the SMA screen was adopted for nationwide newborn screening. Currently she is piloting a screen for Duchenne muscular dystrophy and plans to develop a platform that will allow researchers to add other conditions. In prioritizing genetic conditions for gene therapy, she outlined some ideas for focus, such as genes resulting in phenotypes that would not be identified early without screening, those that are relatively frequent, those that are lethal or neurodegenerative, those with a treatment in clinical trials or with FDA-approved medications, and those conditions that are reversible.

In the meantime, Chung also outlined SFARIs involvement in establishing well-characterized cohorts of individuals with autism, which can help lay a groundwork for gene therapy. People with an ASD diagnosis can join SPARK (Simons Foundation Powering Autism Research for Knowledge), which collects medical, behavioral and genetic information (through analysis of DNA from saliva, at no cost to the participant). If a de novo genetic variant is found in one of ~150 genes, that person is referred to Simons Searchlight, which fosters rare conditions communities and which is also compiling natural history data on people with these mutations.

Bryan King of UCSF discussed how current trial designs for ASD were inadequate for gene therapy trials. As ASD prevalence has grown, parallel design trials with one group receiving an experimental medicine and the other a placebo are the standard, but these wont be possible for the rare conditions that are candidates for gene therapy. Also, change is hard to capture, given the malleable nature of ASD: with no intervention, diagnosis can shift between ASD and pervasive developmental disorder-not otherwise specified (PDD-NOS) in 1284 months (as defined by the DSM-IV). Current scales are subjective and may miss specific items of clinical significance. (Last year, SFARI funded four efforts to develop more sensitive outcome measures.) King outlined other pitfalls in ASD clinical trials, including significant placebo responses, inadequate sample sizes and not being specific enough when asking about adverse effects. King also mentioned improvements that may arise from just enrolling in a study, which could prompt previously housebound families to venture out with their child, which could kick off a cascade of positive effects. He reiterated how, for gene therapy, a natural history comparison group may be more appropriate, combined with solid outcome measures.

SFARI Investigator James McPartland of Yale University then underlined the need for objective biomarkers for clinical trials, for which there are currently none that are FDA qualified for ASD. As the director of the Autism Biomarkers Consortium for Clinical Trials (ABC-CT), he works with other scientists to develop reliable biomarkers that can be scaled for use in large samples across different sites. McPartland noted a biomarker studied in the ABC-CT: an event-related potential (N170) to human faces, which is on average slower in ASD than in typically developing children. He is working on ways to make it easier for people with ASD and intellectual disabilities to participate in biomarker studies and to make them more socially naturalistic. In discussion, he mentioned he thought it would be possible to look for these kinds of biomarkers in younger children.

SFARI Investigator Shafali Jeste of the University of California, Los Angeles recounted her experience in working with children with genetic syndromes associated with neurodevelopmental conditions. Though she is asked to participate in clinical trials for these conditions, she senses the field has some work to do to be ready for these trials, particularly in those with additional challenges such as epilepsy and intellectual disability. Meaningful and measurable clinical endpoints are still insufficient, and there needs to be more ways to improve accessibility of these trials for these rare conditions. This means developing new measures, such as gait-mat technology that senses walking coordination, or EEG measures in waking and sleep, which have been applied to people with chromosome 15q11.2-13.1 duplication (dup15q) syndrome, who have severe intellectual disability and motor impairments. Jeste also emphasized that increasing remote access to some measures can make a big difference for a trial; for example, a trial of a behavioral intervention for tuberous sclerosis complex that required weekly lab visits was disappointingly under-enrolled until researchers revamped it so most of the intervention could be done remotely31.

By grappling with the challenges to gene therapy for ASD, the workshop marked out a faint road map of a way forward. As the scientific questions are answered, the regulatory and clinical trial infrastructure will need to develop apace, and coordination between private, academic and advocacy sectors will be essential. But as gene therapy for diverse human conditions continues to be explored and gene discovery in ASD continues, there is reason to believe that some forms of ASD can eventually benefit from this strategy. This workshop provided a terrific discussion about the challenges in developing targeted gene interventions and their potentially transformative effects as therapies, said John Spiro, Deputy Scientific Director of SFARI. We are grateful to all theparticipants, and SFARI looks forward to translating these discussions into focused funding decisions in the near future.

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SFARI | SFARI workshop explores challenges and opportunities of gene therapies for autism spectrum disorder - SFARI News