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Stem Cell Therapy Market by Treatment,Application,End Users and Geography Forecast To 2027 – LionLowdown

Stem Cell Therapy Market is expected to reach 202.77 billion by 2027 from XX billion in 2019 at CAGR of XX %.

The report includes the analysis of impact of COVID-19 lock-down on the revenue of market leaders, followers, and disrupters. Since lock down was implemented differently in different regions and countries, impact of same is also different by regions and segments. The report has covered the current short term and long term impact on the market, same will help decision makers to prepare the outline for short term and long term strategies for companies by region.

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Stands for use of stem cells to treat or prevent disease or condition.Bone marrow transplant and some therapies derived from umbilical cord blood are mainly used in stem cell therapy. Advancement, in order to establish new sources for stem cells, and to apply stem-cell treatments for neurodegenerative diseases and conditions such as diabetes, heart disease, and other conditions, are increased in recent years.

Stem Cell Therapy Market Researchers are making efforts to discover novel methods to create human stem cells. This will increase the demand as well as supply for stem cell production and potential investigation in disease management. Increasing investment & research grants for developing safe and effective stem cell therapy products, the growing patient base for target diseases, concentrated product pipelines, increasing approval of the new clinical trials, rapid technological advancement in genomics, and the rising awareness about the stem cell are expected to drive the growth of the Stem Cell Therapy solutions market during the forecast period.

However, improper infrastructure, insufficient storage systems, nascent technology in underdeveloped economies, Ethical issues related to an embryonic stem cell, low patient acceptance rate, Difficulty in the preservation of stem cell are expected to restrain the market growth. North America is expected to be the largest growing region by 2026; the reason behind that is extensive funding by Government. However, Emerging countries like India, china, Korea have low growth rate as compared to Developed regions in 2017 but increase in awareness about stem cell therapy will lead the Asia Pacific to generate a significant level of revenue by 2026.

Key Highlights of Stem Cell Therapy Market report

Detailed quantitative analysis of the current and future trends from 2017 to 2026, which helps to identify the prevailing market opportunities. Comprehensive analysis of factors instrumental in changing the market scenario, rising prospective opportunities, market shares, core competencies in terms of market development, growth strategies and identification of key companies that can influence this market on a global and regional scale. Assessment of Market definition along with the identification of key drivers, restraints opportunities and challenges for this market during the forecast period. Complete analysis of micro-markets with respect to individual growth trends, prospects, and contributions to the overall Stem Cell Therapy Solutions market. Stem Cell Therapy market analysis and comprehensive segmentation with respect to the Application, End users, Treatment, and geography to assist in strategic business planning. Stem Cell Therapy market analysis and forecast for five major geographies-North America, Europe, Asia Pacific, Middle East & Africa, Latin America, and their key regions. For company profiles, 2017 has been considered as the base year. In cases, wherein information was unavailable for the base year, the years prior to it have been considered.

Research Methodology:

The market is estimated by triangulation of data points obtained from various sources and feeding them into a simulation model created individually for each market. The data points are obtained from paid and unpaid sources along with paid primary interviews with key opinion leaders (KOLs) in the market. KOLs from both, demand and supply side were considered while conducting interviews to get an unbiased idea of the market. This exercise was done at a country level to get a fair idea of the market in countries considered for this study. Later this country-specific data was accumulated to come up with regional numbers and then arrive at a global market value for the stem cell therapy market. Key Players in the Stem Cell Therapy Market are:

Chiesi Farmaceutici S.P.A Are: Gamida Cell ReNeuron Group, plc Osiris Therapeutics, Inc. Stem Cells, Inc. Vericel Corporation. Mesoblast, Ltd.

Key Target Audience:

Stem Cell Associations and Organizations Government Research Boards and Organizations Research and consulting firms Stem Cell Therapy Market Investors Healthcare Service Providers (including Hospitals and Diagnostic Centers) Stem Cell Therapeutic Product Manufacturing Organizations Research Labs Clinical research organizations (CROs) Stem Cell Therapy Marketing Players Pharmaceutical Product Manufacturing Companies

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Scope of the Stem Cell Therapy Market Report:

Stem Cell Therapy market research report categorizes the Stem Cell Therapy market based on Application, End users, Treatment, and geography (region wise). Market size by value is estimated and forecasted with the revenues of leading companies operating in the Stem Cell Therapy market with key developments in companies and market trends. Stem Cell Therapy Market, By Treatments:

Allogeneic Stem Cell Therapy Autologous Stem Cell Therapy

Stem Cell Therapy Market, By End Users:

Hospitals Ambulatory Surgical Centers

Stem Cell Therapy Market, By Application:

Oncology Central Nervous System Diseases Eye Diseases Musculoskeletal Diseases Wound & Injuries Metabolic Disorders Cardiovascular Disorders Immune System Disorders Stem Cell Therapy Market, By Geography:

North America Europe Asia Pacific Middle East & Africa Latin America

Available Customization:

With the given market data, Maximize Market Research offers customization of report and scope of the report as per the requirement

Regional Analysis:

Breakdown of the North America stem cell therapy market Breakdown of the Europe stem cell therapy market Breakdown of the Asia Pacific stem cell therapy market Breakdown of the Middle East & Africa stem cell therapy market Breakdown of the Latin America stem cell therapy market

MAJOR TOC OF THE REPORT

Chapter One: Stem Cell Therapy Market Overview

Chapter Two: Manufacturers Profiles

Chapter Three: Global Stem Cell Therapy Market Competition, by Players

Chapter Four: Global Stem Cell Therapy Market Size by Regions

Chapter Five: North America Stem Cell Therapy Revenue by Countries

Chapter Six: Europe Stem Cell Therapy Revenue by Countries

Chapter Seven: Asia-Pacific Stem Cell Therapy Revenue by Countries

Chapter Eight: South America Stem Cell Therapy Revenue by Countries

Chapter Nine: Middle East and Africa Revenue Stem Cell Therapy by Countries

Chapter Ten: Global Stem Cell Therapy Market Segment by Type

Chapter Eleven: Global Stem Cell Therapy Market Segment by Application

Chapter Twelve: Global Stem Cell Therapy Market Size Forecast (2019-2026)

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Stem Cell Therapy Market by Treatment,Application,End Users and Geography Forecast To 2027 - LionLowdown

Stem Cell Therapy Market Analysis, COVID-19 Impact,Outlook, Opportunities, Size, Share Forecast and Supply Demand 2021-2025 – Farming Sector

Global Stem Cell Therapy market research report is an exceptional guide to encourage accurate market-based understanding, thorough trend assessment as well as`product utilization to ensure optimum competitive advantage for delivering accurate customer behavior and user preferences. The report is in place to allow market players plan and deliver novel business strategies and tactical business output to sustain gradual evolution into a better business entity. The report is a highly reliable and unbiased data presentation which has been prepared following the highest standards of research endeavors by our in-house research activities undertaken by seasoned research practitioners. Further, to induce logical decision making, data sets are presented in the form of charts, graphs and tables to incur maximum benefits.

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Vendor Landscape

The report has been meticulously drafted to ensure intensive business decision making, strategy building as well as inventory management and delivery of thought provoking business decisions. The report sheds ample light on specific market developments and participant competencies, comprising specific data on vendor growth objectives, followed by an in-depth SWOT assessment to highlight core market strengths and player competencies. Details about their threat probabilities as well as weaknesses have also been highlighted, besides identifying their strengths and opportunities based on which market players in global Stem Cell Therapy market may deliver growth proficient business discretion.

The complete value chain and downstream and upstream essentials are scrutinized in this report. Essential trends like globalization, growth progress boost fragmentation regulation & ecological concerns. This Market report covers technical data, manufacturing plants analysis, and raw material sources analysis of Stem Cell Therapy Industry as well as explains which product has the highest penetration, their profit margins, and R&D status. The report makes future projections based on the analysis of the subdivision of the market which includes the global market size by product category, end-user application, and various regions.

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Regional Diversification

Regional growth developments and identification of growth potential hotbeds have been specifically identified to ensure thoughtful business decisions across these areas in particular. The growth stimulation mettle of the growth hotbeds have been adjudged on the basis of several core parameters such as vendor activities, manufacturing preferences, customer preferences and eventual investments in promotional activities and advertising, based on which futuristic business decisions are well designed and deployed.

To ensure high ROI based business decisions, this report highlights core areas such as Canada, Mexico, and the US as top North American with promising growth mettle. Based on European growth proficient developments, Netherlands, Russia, Italy and the UK are spotted as chief growth hotbeds.

Across APAC, Japan, China, India, South Korea and other Southeast Asian countries are flagged as top investment areas. Additionally, the report also suggests that MEA and South America also showcases ample growth mettle, thus unleashing novel growth opportunities in the regions.

Stem Cell Therapy Market Segmentation

Type Analysis of Stem Cell Therapy Market:

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

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

Applications Analysis of Stem Cell Therapy Market:

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

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

Reasons for Report Investment:

1. This global Stem Cell Therapy market research report analyzed on the basis of regional. product-based and end-use applications have been presented with thorough value-based and volume centric elements 2. The report categorically highlights prominent growth steering factors as well as major limitations containing revenue maximization and growth stability 3. The report also renders a clear perspective of prominent market opportunities and growth conducive stimuli 4. The commercial landscape of global Stem Cell Therapy market has been innately discussed at length to identify market players and their proficiencies.

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Stem Cell Therapy Market Analysis, COVID-19 Impact,Outlook, Opportunities, Size, Share Forecast and Supply Demand 2021-2025 - Farming Sector

AGC Biologics Confirms Cell and Gene Therapy Commercial Expertise as Manufacturer of Orchard Therapeutics’ Newly Approved Libmeldy – PRNewswire

SEATTLE, Jan. 4, 2021 /PRNewswire/ -- AGC Biologics, a leading global Biopharmaceutical Contract Development and Manufacturing Organization (CDMO), is the first manufacturer of Orchard Therapeutics' Libmeldy, which was recently approved by the European Commission (EC) as a one-time therapy for eligible patients with early-onset Metachromatic Leukodystrophy (MLD).

The EC has granted full (standard) market authorization for Libmeldy (autologous CD34+ cells encoding the ARSA gene), a lentiviral vector-based gene therapy manufactured at AGC Biologics' Milan facility. Orchard Therapeutics is already underway with EU launch preparations to support commercial-scale drug manufacturing at the AGC Biologics Milan facility.

"AGC Biologics is delighted to have successfully partnered with Orchard Therapeutics on this great milestone," says AGC Biologics Chief Business Officer, Mark Womack. "We're very proud to be one of few Cell and Gene Therapy CDMOs with commercial experience Libmeldy being the third commercial product we've manufactured and we look forward to continuing our partnership with Orchard to provide this life-changing therapy to those affected by MLD."

"We are very honored to have been a part of the entire clinical journey of this product, from the very first treated patient, all the way to market approval. As manufacturer of both lentiviral vector and drug product, we are proud to support Orchard in treating this devastating disease," says AGC Biologics General Manager of Milan, Luca Alberici.

"The EC approval of Libmeldy opens up tremendous possibilities for eligible MLD children faced with this devastating disease," saysBobby Gaspar, M.D., Ph.D., Chief Executive Officer of Orchard. "We are humbled by the opportunity to bring this remarkable innovation to young eligible patients in the EU, and confident in the capabilities of our partners at AGC Biologics to help us achieve this goal."

MLD is a rare neurodegenerative disorder caused by mutations in the ARSA gene. While there are several forms of MLD, the disorder primarily affects young children and disease progression and life expectancy varies based on age of symptom onset. Libmeldy is designed to correct the genetic cause of MLD by inserting functional copies of the ARSA gene into the genome of a patient's own hematopoietic stem cells (HSCs) using a self-inactivating (SIN) lentiviral vector. It is approved in the EU for children with i) late infantile or early juvenile forms, without clinical manifestations of the disease, or ii) the early juvenile form, with early clinical manifestations of the disease, who still have the ability to walk independently and before the onset of cognitive decline. Libmeldy is the first therapy approved for eligible patients with early-onset MLD.

About AGC Biologics: AGC Biologics is a leading global biopharmaceutical Contract Development and Manufacturing Organization (CDMO) with a strong commitment to deliver the highest standard of service as we work side-by-side with our clients and partners, every step of the way. We provide world-class development and manufacture of mammalian and microbial-based therapeutic proteins, plasmid DNA (pDNA), viral vectors and genetically engineered cells. Our global network spans the U.S., Europe and Asia, with cGMP-compliant facilities in Seattle, Washington; Boulder, Colorado; Copenhagen, Denmark; Heidelberg, Germany; Milan, Italy; and Chiba, Japan and we currently employ more than 1,600 employees worldwide. Our commitment to continuous innovation fosters the technical creativity to solve our clients' most complex challenges, including specialization in fast-track projects and rare diseases. AGC Biologics is the partner of choice. To learn more, visit http://www.agcbio.com.

About Orchard Therapeutics:Orchard Therapeutics is a global gene therapy leader dedicated to transforming the lives of people affected by rare diseases through the development of innovative, potentially curative gene therapies. Our ex vivo autologous gene therapy approach harnesses the power of genetically modified blood stem cells and seeks to correct the underlying cause of disease in a single administration. In 2018, Orchard acquired GSK's rare disease gene therapy portfolio, which originated from a pioneering collaboration between GSK and the San Raffaele Telethon Institute for Gene Therapy in Milan, Italy. Orchard now has one of the deepest and most advanced gene therapy product candidate pipelines in the industry spanning multiple therapeutic areas where the disease burden on children, families and caregivers is immense and current treatment options are limited or do not exist.

Orchard has its global headquarters in London and U.S. headquarters in Boston. For more information, please visit http://www.orchard-tx.com, and follow us onTwitterandLinkedIn.

About OTL-200/Libmeldy:Libmeldy (autologous CD34+ cell enriched population that contains hematopoietic stem and progenitor cells (HSPC) transduced ex vivo using a lentiviral vector encoding the human arylsulfatase-A (ARSA) gene), also known as OTL-200, is approved in the European Union (as appropriate may add: "UK, Iceland, Liechtenstein and Norway" as an alternative can rewrite as "was approved by the European Commission" or something similar) for the treatment of MLD in eligible early-onset patients characterized by biallelic mutations in the ARSA gene leading to a reduction of the ARSA enzymatic activity in children with i) late infantile or early juvenile forms, without clinical manifestations of the disease, or ii) the early juvenile form, with early clinical manifestations of the disease, who still have the ability to walk independently and before the onset of cognitive decline. Libmeldy is the first therapy approved for eligible patients with early-onset MLD.

The most common adverse reaction attributed to treatment with Libmeldy was the occurrence of anti-ARSA antibodies (AAA). In addition to the risks associated with the gene therapy, treatment with Libmeldy is preceded by other medical interventions, namely bone marrow harvest or peripheral blood mobilization and apheresis, followed by myeloablative conditioning, which carry their own risks. During the clinical studies, the safety profiles of these interventions were consistent with their known safety and tolerability.

For more information about Libmeldy, please see the Summary of Product Characteristics (SmPC).

Libmeldy is not approved outside of the European Union, UK, Iceland, Liechtenstein and Norway. OTL-200 is an investigational therapy, which has not been approved by the U.S. Food and Drug Administration or any other health authority.

OTL-200 was developed in partnership with the San Raffaele-Telethon Institute for Gene Therapy (SR-Tiget) in Milan, Italy.

SOURCE AGC Biologics

http://www.agcbio.com

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AGC Biologics Confirms Cell and Gene Therapy Commercial Expertise as Manufacturer of Orchard Therapeutics' Newly Approved Libmeldy - PRNewswire

Forge Biologics Announces FDA Clearance of Investigational New Drug Application for Phase 1/2 Clinical Trial (RESKUE) of FBX-101 Gene Therapy for…

COLUMBUS, Ohio, Jan. 4, 2021 /PRNewswire/ --Forge Biologics Inc., a gene therapy manufacturing and development company, today announced that the company has received FDA clearance of the Investigational New Drug (IND) to initiate a Phase 1/2 clinical trial evaluating its novel, first-in-human AAV gene therapy, FBX-101, for patients with Krabbe disease. FBX-101 is the company's first therapeutic program to receive an IND which also received Institutional Biosafety Committee (IBC) and Institutional Review Board (IRB) approvals required prior to any patient enrollment. This marks a major step forward in building out the company's hybrid model as a gene therapy manufacturing and development engine.

Krabbe disease is a rare and fatal pediatric leukodystrophy affecting about 1-2.6 in 100,000 people in the United States. Patients are born with mutations in the galactosylceramidase(GALC) gene, which encodes an enzyme that helps break down lipid molecules inside cells. This results in the toxic buildup of psychosine, a lipid molecule that can't be degraded in cells, particularly in cells in the brain and peripheral nerves, and leads to toxic levels that cause cell death and myelin loss. The disease initially presents as physical delays in development, muscle tightness and irritability, and rapidly advances to difficulty swallowing and breathing, loss of vision and hearing, and increasing cognitive degeneration. Early onset, or "Infantile", Krabbe disease cases usually results in death by age 2-4 years, while later onset or "Late Infantile" cases have a more variable course of progressive decline. There is currently no approved treatment for either form of Krabbe disease.

FBX-101 is an adeno-associated viral (AAV) gene therapy administered after hematopoietic stem cell transplant (HSCT), that delivers a functioning copy of the GALC gene, the enzyme needed to prevent the buildup of psychosine in myelinated cells of both the central and peripheral nervous system. FBX-101 has been shown to correct the central and peripheral myelination deficits, significantly improve the behavioral impairments associated with Krabbe disease in animal models, and drastically improve the lifespan of treated animals. The use of transplant and intravenous AAV gene therapy infusion has the potential to overcome some of the immunological safety challenges of traditional AAV gene therapies.

"The ground-breaking treatment approach using HSCT and AAV gene therapy, initially developed by Dr. Escolar, has safely demonstrated superior benefits in preclinical animal studies of Krabbe disease than either treatment method alone," said Timothy J. Miller, Ph.D., Forge's CEO, President, and Co-Founder. "We are grateful for the FDA's engaged review and allowance of the IND, and look forward to enrolling patients very soon."

FBX-101 is the culmination of nearly 20 years of Krabbe disease research, led by Maria Escolar, M.D., M.S., Chief Medical Officer at Forge Biologics and the pioneer for evaluating the natural history and new treatment approaches for patients with Krabbe disease. "This combination approach is extremely exciting because the preclinical data demonstrate significant correction of survival, behavior and neuromuscular function in animal models compared to either transplant or AAV treatment alone. This is a significant milestone for Krabbe disease families suffering from this deadly disease," said Dr. Escolar.

The initiation of the RESKUE trial in Forge's gene therapy pipeline continues Forge's momentum within the biotechnology industry in Columbus, Ohio, bringing positive impact to both Ohio and the global rare disease community.

Patients and families can learn more about clinical trials for FBX-101 by visiting https://www.forgebiologics.com/science/#krabbe.

About Krabbe diseaseKrabbe disease is a rare, pediatric leukodystrophy affecting about 1-2.6 in 100,000 people in the U.S. and is inherited in an autosomal recessive manner. Krabbe disease is caused by loss-of-function mutations in the galactosylceramidase (GALC) gene, a lysosomal enzyme responsible for the breakdown of certain types of lipids such as psychosine. Without functional GALC, psychosine accumulates to toxic levels in cells. The psychosine toxicity is most severe in the myelin cells surrounding the nerves in the brain and in the peripheral nervous system, eventually leading to the death of these cells. The disease initially manifests as physical delays in development, muscle weakness and irritability and advances rapidly to difficulty swallowing, breathing problems, cognitive, vision and hearing loss. Early onset or "Infantile", Krabbe disease cases usually results in death by age 2-4 years, while later onset or "Late Infantile" cases have a more variable course of progressive decline. There is currently no approved treatment for Krabbe disease.

About FBX-101Forge is developing FBX-101 to treat patients with infantile Krabbe disease. FBX-101 is an adeno-associated viral (AAV) gene therapy that is delivered after a hematopoietic stem cell transplant. FBX-101 delivers a functional copy of the GALC gene to cells in both the central and peripheral nervous system. FBX-101 has been shown to functionally correct the central and peripheral neuropathy and correct the behavioral impairments associated with Krabbe disease in animal models, and to drastically improve the lifespan of treated animals. This approach has the potential to overcome some of the immunological safety challenges observed in traditional AAV gene therapies.

About Forge BiologicsForge Biologics is a hybrid gene therapy contract manufacturing and therapeutic development company. Forge's mission is to enable access to life changing gene therapies and help bring them from idea into reality. Forge has a 175,000 ft2 facility in Columbus, Ohio, "The Hearth", to serve as their headquarters. The Hearth is the home of a custom-designed cGMP facility dedicated to AAV viral vector manufacturing and will host end-to-end manufacturing services to accelerate gene therapy programs from preclinical through clinical and commercial stage manufacturing.By taking a patients-first approach, Forge aims to accelerate the timelines of these transformative medicines for those who need them the most.

For more information, please visit https://www.forgebiologics.com.

Patient, Pediatrician, Genetic Counselors & Family Inquiries

Dr. Maria Escolar Chief Medical Officer Forge Biologics Inc. [emailprotected]

Media Inquiries:

Dan Salvo Director of Communications and Community Development Forge Biologics Inc. [emailprotected]

Investor Relations and Business Development

Christina Perry Vice President, Finance and Operations Forge Biologics Inc. [emailprotected]

SOURCE Forge Biologics

https://forgebiologics.com

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Forge Biologics Announces FDA Clearance of Investigational New Drug Application for Phase 1/2 Clinical Trial (RESKUE) of FBX-101 Gene Therapy for...

MorphoSys and Incyte Announce the Acceptance of the Swissmedic Marketing Authorization Application f – PharmiWeb.com

DGAP-News: MorphoSys AG / Key word(s): Miscellaneous 05.01.2021 / 08:00 The issuer is solely responsible for the content of this announcement.

Media Release

MorphoSys and Incyte Announce the Acceptance of the Swissmedic Marketing Authorization Application for Tafasitamab

- The Swissmedic MAA seeks approval for tafasitamab in combination with lenalidomide for the treatment of adult patients with relapsed or refractory diffuse large B-cell lymphoma

PLANEGG/MUNICH, Germany and MORGES, Switzerland - January 5, 2021 - MorphoSys AG (FSE: MOR; Prime Standard Segment; MDAX & TecDAX; NASDAQ:MOR) and Incyte (NASDAQ:INCY) today announced that the Swiss Agency for Therapeutic Products (Swissmedic) has accepted the marketing authorization application (MAA) for tafasitamab, a humanized Fc-modified cytolytic CD19 targeting monoclonal antibody. The MAA seeks approval for tafasitamab, in combination with lenalidomide, followed by tafasitamab monotherapy, for the treatment of adult patients with relapsed or refractory diffuse large B-cell lymphoma (DLBCL), including DLBCL arising from low grade lymphoma, who are not candidates for autologous stem cell transplantation (ASCT). The MAA will now enter the formal review process by Swissmedic.

The Swissmedic MAA for tafasitamab will be reviewed as part of the U.S. Food and Drug Administration's (FDA) modified Project Orbis, which provides a framework for concurrent submission and review of oncology drug applications among the FDA's international collaborators. Collaboration among international regulators may allow patients with cancer to receive earlier access to products in other countries.

"Currently about 40% of DLBCL patients do not respond to initial therapy or relapse thereafter leading to a high medical need for new, effective therapies," said Peter Langmuir, M.D., Group Vice President, Targeted Therapeutics, Incyte. "The acceptance of the MAA for tafasitamab for review by Swissmedic is a pivotal step towards bringing tafasitamab in combination with lenalidomide to eligible patients in Switzerland."

"Tafasitamab in combination with lenalidomide may represent an important new targeted treatment option for patients with relapsed or refractory DLBCL," said Mike Akimov, M.D., Ph.D., Head of Global Clinical Development, MorphoSys. "We look forward to continuing to work with the regulatory authorities alongside our partners at Incyte to bring this novel therapeutic option to eligible patients with a high unmet medical need."

The Swissmedic application, submitted by Incyte in collaboration with MorphoSys, is supported by data from the L-MIND study evaluating tafasitamab in combination with lenalidomide as a treatment for patients with relapsed or refractory DLBCL and data from the RE-MIND study, an observational retrospective study in relapsed or refractory DLBCL. If approved, Incyte will hold the marketing authorization, and have exclusive commercialization rights for tafasitamab in Switzerland.

Incyte has exclusive commercialization rights for tafasitamab outside the United States.

About Diffuse Large B-cell Lymphoma (DLBCL) DLBCL is the most common type of non-Hodgkin lymphoma in adults worldwide[1], characterized by rapidly growing masses of malignant B-cells in the lymph nodes, spleen, liver, bone marrow or other organs. It is an aggressive disease with about 40% of patients not responding to initial therapy or relapsing thereafter[2]. In Europe, each year approximately 16,000 patients are diagnosed with relapsed or refractory DLBCL[3],[4],[5].

About L-MIND The L-MIND trial is a single arm, open-label, multicenter Phase 2 study (NCT02399085) investigating the combination of tafasitamab and lenalidomide in patients with relapsed or refractory diffuse large B-cell lymphoma (DLBCL) who have had at least one, but no more than three prior lines of therapy, including an anti-CD20 targeting therapy (e.g. rituximab), who are not eligible for high-dose chemotherapy or refuse subsequent autologous stem cell transplant. The study's primary endpoint is Overall Response Rate (ORR). Secondary outcome measures include Duration of Response (DoR), Progression-Free Survival (PFS) and Overall Survival (OS). In May 2019, the study reached its primary completion.

For more information about L-MIND, visit https://clinicaltrials.gov/ct2/show/NCT02399085

About RE-MIND RE-MIND, an observational retrospective study (NCT04150328), was designed to isolate the contribution of tafasitamab in combination with lenalidomide and to prove the combinatorial effect. The study compares real-world response data of patients with relapsed or refractory diffuse large B-cell lymphoma (DLBCL) who received lenalidomide monotherapy with the efficacy outcomes of the tafasitamab-lenalidomide combination, as investigated in MorphoSys' L-MIND trial. RE-MIND collected the efficacy data from 490 relapsed or refractory DLBCL patients in the U.S. and the EU. Qualification criteria for matching patients of both studies were pre-specified. As a result, 76 eligible RE-MIND patients were identified and matched 1:1 to 76 of 80 L-MIND patients based on important baseline characteristics. Objective Response Rates (ORR) were validated based on this subset of 76 patients in RE-MIND and L-MIND, respectively. The primary endpoint of RE-MIND was met and shows a statistically significant superior best ORR of the tafasitamab-lenalidomide combination compared to lenalidomide monotherapy.

For more information about RE-MIND, visit https://clinicaltrials.gov/ct2/show/NCT04150328.

About Tafasitamab Tafasitamab is a humanized Fc-modified cytolytic CD19 targeting monoclonal antibody. In 2010, MorphoSys licensed exclusive worldwide rights to develop and commercialize tafasitamab from Xencor, Inc. Tafasitamab incorporates an XmAb(R) engineered Fc domain, which mediates B-cell lysis through apoptosis and immune effector mechanism including Antibody-Dependent Cell-Mediated Cytotoxicity (ADCC) and Antibody-Dependent Cellular Phagocytosis (ADCP).

Monjuvi(R) (tafasitamab-cxix) is approved by the U.S. Food and Drug Administration (FDA) in combination with lenalidomide for the treatment of adult patients with relapsed or refractory diffuse large B-cell lymphoma (DLBCL) not otherwise specified, including DLBCL arising from low grade lymphoma, and who are not eligible for autologous stem cell transplant (ASCT). This indication is approved under accelerated approval based on overall response rate. Continued approval for this indication may be contingent upon verification and description of clinical benefit in a confirmatory trial(s).

In January 2020, MorphoSys and Incyte entered into a collaboration and licensing agreement to further develop and commercialize tafasitamab globally. Monjuvi is being co-commercialized by Incyte and MorphoSys in the United States. Incyte has exclusive commercialization rights outside the United States.

Tafasitamab is being clinically investigated as a therapeutic option in B-cell malignancies in a number of ongoing combination trials.

Monjuvi(R) is a registered trademark of MorphoSys AG.

XmAb(R) is a registered trademark of Xencor, Inc.

About MorphoSys MorphoSys (FSE & NASDAQ: MOR) is a commercial-stage biopharmaceutical company dedicated to the discovery, development and commercialization of exceptional, innovative therapies for patients suffering from serious diseases. The focus is on cancer. Based on its leading expertise in antibody, protein and peptide technologies, MorphoSys, together with its partners, has developed and contributed to the development of more than 100 product candidates, of which 27 are currently in clinical development. In 2017, Tremfya(R), developed by Janssen Research & Development, LLC and marketed by Janssen Biotech, Inc., for the treatment of plaque psoriasis, became the first drug based on MorphoSys' antibody technology to receive regulatory approval. In July 2020, the U.S. Food and Drug Administration (FDA) granted accelerated approval of MorphoSys' proprietary product Monjuvi(R) (tafasitamab-cxix) in combination with lenalidomide in patients with a certain type of lymphoma.

Headquartered near Munich, Germany, the MorphoSys group, including the fully owned U.S. subsidiary MorphoSys US Inc., has ~500 employees. More information at http://www.morphosys.com or http://www.morphosys-us.com.

Monjuvi(R) is a registered trademark of MorphoSys AG.

Tremfya(R) is a registered trademark of Janssen Biotech, Inc.

About Incyte Incyte is a Wilmington, Delaware-based, global biopharmaceutical company focused on finding solutions for serious unmet medical needs through the discovery, development and commercialization of proprietary therapeutics. For additional information on Incyte, please visit Incyte.com and follow @Incyte.

MorphoSys Forward-looking Statements This communication contains certain forward-looking statements concerning the MorphoSys group of companies, including the expectations regarding Monjuvi's ability to treat patients with relapsed or refractory diffuse large B-cell lymphoma, the further clinical development of tafasitamab-cxix, including ongoing confirmatory trials, additional interactions with regulatory authorities and expectations regarding future regulatory filings and possible additional approvals for tafasitamab-cxix as well as the commercial performance of Monjuvi. The words "anticipate," "believe," "estimate," "expect," "intend," "may," "plan," "predict," "project," "would," "could," "potential," "possible," "hope" and similar expressions are intended to identify forward-looking statements, although not all forward-looking statements contain these identifying words. The forward-looking statements contained herein represent the judgment of MorphoSys as of the date of this release and involve known and unknown risks and uncertainties, which might cause the actual results, financial condition and liquidity, performance or achievements of MorphoSys, or industry results, to be materially different from any historic or future results, financial conditions and liquidity, performance or achievements expressed or implied by such forward-looking statements. In addition, even if MorphoSys' results, performance, financial condition and liquidity, and the development of the industry in which it operates are consistent with such forward-looking statements, they may not be predictive of results or developments in future periods. Among the factors that may result in differences are MorphoSys' expectations regarding risks and uncertainties related to the impact of the COVID-19 pandemic to MorphoSys' business, operations, strategy, goals and anticipated milestones, including its ongoing and planned research activities, ability to conduct ongoing and planned clinical trials, clinical supply of current or future drug candidates, commercial supply of current or future approved products, and launching, marketing and selling current or future approved products, the global collaboration and license agreement for tafasitamab, the further clinical development of tafasitamab, including ongoing confirmatory trials, and MorphoSys' ability to obtain and maintain requisite regulatory approvals and to enroll patients in its planned clinical trials, additional interactions with regulatory authorities and expectations regarding future regulatory filings and possible additional approvals for tafasitamab-cxix as well as the commercial performance of Monjuvi, MorphoSys' reliance on collaborations with third parties, estimating the commercial potential of its development programs and other risks indicated in the risk factors included in MorphoSys' Annual Report on Form 20-F and other filings with the U.S. Securities and Exchange Commission. Given these uncertainties, the reader is advised not to place any undue reliance on such forward-looking statements. These forward-looking statements speak only as of the date of publication of this document. MorphoSys expressly disclaims any obligation to update any such forward-looking statements in this document to reflect any change in its expectations with regard thereto or any change in events, conditions or circumstances on which any such statement is based or that may affect the likelihood that actual results will differ from those set forth in the forward-looking statements, unless specifically required by law or regulation.

Incyte Forward-looking Statements Except for the historical information set forth herein, the matters set forth in this press release, including statements regarding whether or when tafasitamab might be approved in Switzerland for the treatment of, and whether or when tafasitamab might provide a successful treatment option for, in combination with lenalidomide, certain patients with relapsed or refractory diffuse large B-cell lymphoma (DLBCL), and the L-MIND and RE-MIND clinical trial programs. These forward-looking statements are based on the Company's current expectations and subject to risks and uncertainties that may cause actual results to differ materially, including unanticipated developments in and risks related to: unanticipated delays; further research and development and the results of clinical trials possibly being unsuccessful or insufficient to meet applicable regulatory standards or warrant continued development; the ability to enroll sufficient numbers of subjects in clinical trials; determinations made by European regulatory authorities or other regulatory authorities, including the U.S. FDA; the Company's dependence on its relationships with its collaboration partners; the efficacy or safety of the Company's products and the products of the Company's collaboration partners; the acceptance of the Company's products and the products of the Company's collaboration partners in the marketplace; market competition; sales, marketing, manufacturing and distribution requirements; greater than expected expenses; expenses relating to litigation or strategic activities; and other risks detailed from time to time in the Company's reports filed with the Securities and Exchange Commission, including its Form 10-Q for the quarter ending September 30, 2020. The Company disclaims any intent or obligation to update these forward-looking statements. # # #

Contacts:

References [1] Sarkozy C, et al. Management of relapsed/refractory DLBCL. Best Practice Research & Clinical Haematology. 2018 31:209-16. doi.org/10.1016/j.beha.2018.07.014. [2] Skrabek P, et al. Emerging therapies for the treatment of relapsed or refractory diffuse large B cell lymphoma. Current Oncology. 2019 26(4): 253-265. doi.org/10.3747/co.26.5421. [3] DRG Epidemiology data. [4] Kantar Market Research (TPP testing 2018). [5] Friedberg, Jonathan W. Relapsed/Refractory Diffuse Large B-Cell Lymphoma. Hematology Am Soc Hematol Educ Program 2011; 2011:498-505. doi: 10.1182/asheducation-2011.1.498.

05.01.2021 Dissemination of a Corporate News, transmitted by DGAP - a service of EQS Group AG. The issuer is solely responsible for the content of this announcement.

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MorphoSys and Incyte Announce the Acceptance of the Swissmedic Marketing Authorization Application f - PharmiWeb.com

Healthcare resource utilization and costs among patients with relapsed and/or refractory multiple myeloma treated with proteasome inhibitors in…

This article was originally published here

J Med Econ. 2021 Jan 4:1. doi: 10.1080/13696998.2020.1867469. Online ahead of print.

ABSTRACT

AIMS: To assess the real-world healthcare resource utilization (HRU) and costs associated with different proteasome inhibitors (PIs) for the treatment of patients with relapsed and/or refractory multiple myeloma (RRMM) in Germany.

METHODS: We conducted a retrospective medical chart review of treatment patterns, outcomes, and HRU for patients with RRMM treated with bortezomib, carfilzomib, or ixazomib in second- or third-line (2L or 3L) therapy in Germany. Data were collected between 1 January 2017 and 30 June 2017. Costs were calculated based on drug prices and unit costs in Germany.

RESULTS: Physicians provided data on 302 patients. Mean monthly total direct costs per patient receiving PI-based therapy were 7,925 and 10,693 for 2L and 3L, respectively, of which approximately 90% was anti-myeloma drug costs. Overall, the highest costs were associated with patients receiving 3L therapy. Regardless of treatment line, costs were higher for patients who had received a stem cell transplant (SCT) in a previous treatment line than for those who had not; the data suggest that this reflects the use of triplet regimens following a SCT. Patients with a complete response (CR) experienced no unplanned hospitalizations during the study period, whereas patients with progressive disease experienced the highest number of unplanned and planned hospitalizations. In 2L therapy, the highest proportion of patients with a CR was observed in those receiving carfilzomib (12% carfilzomib; 4% bortezomib; 0% ixazomib).

LIMITATIONS: Patients with missing or incomplete follow-up data were included in the study and were accounted for using monthly cost estimates.

CONCLUSIONS: Anti-myeloma drugs were the main contributor to total HRU costs associated with RRMM in Germany. Improved treatment response was associated with lower costs and reduced hospitalizations.

PMID:33390079 | DOI:10.1080/13696998.2020.1867469

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Healthcare resource utilization and costs among patients with relapsed and/or refractory multiple myeloma treated with proteasome inhibitors in...

Global Circulating Tumor Cells and Cancer Stem Cells Market To Reach A New Threshold of Growth By 2026 – The Courier

The globalCirculating Tumor Cells (CTCS) and Cancer Stem Cells (CSCS) Marketresearch report gives point to point breakdown along with the data of Circulating Tumor Cells (CTCS) and Cancer Stem Cells (CSCS) markets analytical study, regional analysis, growth factors and leading companies. The research report about the market provides the data about the aspects which drive the expansion of Circulating Tumor Cells (CTCS) and Cancer Stem Cells (CSCS) industry. The market consists of large key companies who play a vital role in the production, manufacturing, sales and distribution of the products so that the supply & demand chain are met. A complex examination of the worldwide market share of past as well as future with certain trends is catered to in current report.

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The global Circulating Tumor Cells (CTCS) and Cancer Stem Cells (CSCS) market research report provides crucial info related to overall global market in conjunction with segmentation, regional and statistical data that helps in indentifying the suitable business intelligence essentials.

The segmentation of Circulating Tumor Cells (CTCS) and Cancer Stem Cells (CSCS) market CellSearch, Oncoquick, ISET, MACS, Others is primarily based on market size, application, end use industry, type, and various other factors.

The major players Aviva Biosciences Corporation, ApoCell, BioView, Janssen, IVDiagnostics, Silicon Biosystems, Creatv MicroTech, Gilupi, ScreenCell, Miltenyi Biotec, Qiagen, Fluidigm, Biofluidica, YZY Bio, Ikonisys, Clearbridge Biomedics, AdnaGen, Cynvenio, On-chip, Fluxion, Celsee, CytoTrack, Advanced Cell Diagnostics who are currently ruling the Circulating Tumor Cells (CTCS) and Cancer Stem Cells (CSCS) market are included in the report.

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The analytical investigation given in the global Circulating Tumor Cells (CTCS) and Cancer Stem Cells (CSCS) market research report provides comprehensive info about regional growth of the industry along with capital acquired through the development and growth of Circulating Tumor Cells (CTCS) and Cancer Stem Cells (CSCS) market.

Multiple business models have been used in the study of the global Circulating Tumor Cells (CTCS) and Cancer Stem Cells (CSCS) market.

Circulating Tumor Cells (CTCS) and Cancer Stem Cells (CSCS) Market COVID-19 Impact Analysis

As the world is still dealing with COVID-19 situation, many of the countries have slowly started to revive its economic situation by starting its trade and businesses. There has been enormous loss in these few months both in terms of economy and human lives. As the WHO has already suggested that there are very less chances that the virus will completely go, hence we will have start living with it. Many of the drug companies are getting positive response of their COVID-19 vaccines, but there is still time for its availability in the global market.

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Summary

The global Circulating Tumor Cells (CTCS) and Cancer Stem Cells (CSCS) market research report gives a comprehensive data and analysis about the worldwide market. The Circulating Tumor Cells (CTCS) and Cancer Stem Cells (CSCS) report further gives the data that one could rely on; which comes with in-depth analysis of market. Different factors like in-depth description of Circulating Tumor Cells (CTCS) and Cancer Stem Cells (CSCS) market, growth factors, segmentation, regional analysis, sales, supply, demand, manufacture analysis, recent trends, and competing companies are included in the report. The exquisite data provided in global Circulating Tumor Cells (CTCS) and Cancer Stem Cells (CSCS) market research report is explanatory in terms of quantity as well as quality.

There are 15 Sections to show the global Circulating Tumor Cells (CTCS) and Cancer Stem Cells (CSCS) market

Sections 1, Definition, Specifications and Classification of Circulating Tumor Cells (CTCS) and Cancer Stem Cells (CSCS), Applications of Circulating Tumor Cells (CTCS) and Cancer Stem Cells (CSCS), Market Segment by Regions; Section 2, Assembling Cost Structure, Crude Material and Providers, Assembling Procedure, Industry Chain Structure; Sections 3, Technical Data and Manufacturing Plants Analysis of Circulating Tumor Cells (CTCS) and Cancer Stem Cells (CSCS), Capacity and Commercial Production Date, Manufacturing Plants Distribution, R&D Status and Technology Source, Raw Materials Sources Analysis; Sections 4, Generally Market Analysis, Limit Examination (Organization Fragment), Sales Examination (Organization Portion), sales Value Investigation (Organization Section); Sections 5 and 6, Regional Market Investigation that incorporates United States, China, Europe, Japan, Korea and Taiwan, Circulating Tumor Cells (CTCS) and Cancer Stem Cells (CSCS) segment Market Examination (by Sort); Sections 7 and 8, The Circulating Tumor Cells (CTCS) and Cancer Stem Cells (CSCS) Segment Market Analysis (by Application) Major Manufacturers Analysis of Circulating Tumor Cells (CTCS) and Cancer Stem Cells (CSCS) ; Sections 9, Market Trend Analysis, Regional Market Trend, Market Trend by Product Type CellSearch, Oncoquick, ISET, MACS, Others Market Trend by Application Breast Cancer Diagnosis and Treatment, Prostate Cancer Diagnosis and Treatment, Colorectal Cancer Diagnosis and Treatment, Lung Cancer Diagnosis and Treatment, Other Cancers Diagnosis and Treatment; Sections 10, Regional Promoting Type Investigation, Worldwide Exchange Type Examination, Inventory network Investigation; Sections 11, The Customers Examination of global Circulating Tumor Cells (CTCS) and Cancer Stem Cells (CSCS); Sections 12, Circulating Tumor Cells (CTCS) and Cancer Stem Cells (CSCS) Research Findings and Conclusion, Appendix, system and information source; Sections 13, 14 and 15, Circulating Tumor Cells (CTCS) and Cancer Stem Cells (CSCS) deals channel, wholesalers, merchants, traders, Exploration Discoveries and End, appendix and data source.

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Global Circulating Tumor Cells and Cancer Stem Cells Market To Reach A New Threshold of Growth By 2026 - The Courier

The Worldwide Cell Isolation/Cell Separation Industry is Expected to Grow at a CAGR of 16.8% Between 2020 to 2025 – PRNewswire

DUBLIN, Jan. 4, 2021 /PRNewswire/ -- The "Cell Isolation/Cell Separation Market by Product (Reagents, Beads, Centrifuge), Cell Type (Human, Animal), Cell Source (Bone Marrow, Adipose), Technique (Filtration), Application (Cancer, IVD), End-User (Hospitals, Biotechnology) - Global Forecast to 2025" report has been added to ResearchAndMarkets.com's offering.

The global cell isolation market is expected to reach USD 14,995.98 million by 2025 from USD 6894.32 million in 2020, at a CAGR of 16.8% during the forecast period.

Market growth is driven by factors The growing investments in personalized medicine can primarily be attributed to the growing demand for advanced treatments with minimal side-effects and the rising prevalence of diseases such as cancer. With the rising focus on the development of personalized medicine, the number of personalized medications available in the market has steadily increased over the last decade, and this trend is expected to continue in the coming years.

The consumables accounted for the highest growth rate in the cell isolation market, by product during the forecast period

Based on the product, the cell isolation market is segmented into consumables and instruments. The consumables segment accounted for the largest share in the cell isolation market in the forecasted period. The increasing investments by companies to develop technologically advanced products as well as the repetitive use of consumables as compared to instruments are the major factors driving the growth of this segment.

Human cells segment accounted for the highest CAGR

Based on cell type, the cell isolation market is segmented into human cells and animal cells. The human cells segment accounted for the largest share of the global cell isolation market in the forecasted period. The increasing investments by public and private organizations for research on human cells, growing application areas of human stem cells, and the high and growing incidence of diseases such as cancer are the major factors driving this segment's growth.

Biotechnology and biopharmaceutical companies segment accounted for the highest CAGR

The cell isolation market is segmented into hospitals and diagnostic laboratories, biotechnology and biopharmaceutical companies, research laboratories and institutes, and other end users based on end users. In 2019, the biotechnology and biopharmaceutical companies segment accounted for the largest share. The widespread adoption of advanced instruments in cell-based experiments and cancer research in biotechnology and biopharmaceutical companies, as well as the increasing number of R&D facilities globally, are the major factors driving this segment's growth.

Asia Pacific: The fastest-growing region cell isolation market

The global cell isolation market is segmented into North America, Europe, Asia Pacific, and the Rest of the world. The Asia Pacific region is projected to register the highest CAGR during the forecast period. Growth in this region is expected to be centered on China and Japan. Factors such as the expansion by key market players in emerging Asian countries and the increasing trend of pharmaceutical outsourcing to Asian countries like India and China are driving the growth of the cell isolation market in this region.

Key Topics Covered:

1 Introduction

2 Research Methodology

3 Executive Summary

4 Premium Insights 4.1 Cell Isolation: Market Overview 4.2 North America: Cell Isolation Market, by Product (2019) 4.3 Geographical Snapshot of the Cell Isolation Market

5 Market Overview 5.1 Introduction 5.2 Market Dynamics 5.2.1 Drivers 5.2.1.1 Increasing Government Funding for Cell-Based Research 5.2.1.2 Increasing Number of Patients Suffering from Cancer and Infectious Diseases 5.2.1.3 Technological Advancements 5.2.1.4 Growing Focus on Personalized Medicine 5.2.2 Restraints 5.2.2.1 Ethical Issues Related to Embryonic Stem Cell Isolation 5.2.2.2 High Cost of Cell-Based Research 5.2.3 Opportunities 5.2.3.1 Emerging Markets 5.3 COVID-19 Impact on the Cell Isolation/Cell Separation Market

6 Cell Isolation Market, by Product 6.1 Introduction 6.2 Consumables 6.2.1 Reagents, Kits, Media, and Sera 6.2.1.1 Owing to the Disposable Nature of Reagents and Assay Kits, this Market is Driven by Their Consistent Usage and Frequent Purchases 6.2.2 Beads 6.2.2.1 Growing Demand for Magnetic Beads in T-Cell and Stem Cell Isolation is a Major Factor Driving Growth in this Product Segment 6.2.3 Disposables 6.2.3.1 Increasing Investments in Research by Governments and Companies are a Major Factor Boosting the Growth of the Cell Isolation Disposables Market 6.3 Instruments 6.3.1 Centrifuges 6.3.1.1 Growing Use of Centrifuges in the Pharma-Biotech Industry and Multi-Functionality Options Offered by These Instruments are Driving the Growth of this Product Segment 6.3.2 Flow Cytometers 6.3.2.1 Launch of Innovative and Cost-Effective Flow Cytometers is Likely to Drive the Growth of the Market 6.3.3 Magnetic-Activated Cell Separator Systems 6.3.4 Filtration Systems 6.3.4.1 Increasing Research Activities in Cell Biology to Boost the Market

7 Cell Isolation Market, by Cell Type 7.1 Introduction 7.2 Human Cells 7.2.1 Differentiated Cells 7.2.1.1 Growing Investments by Market Players to Develop New and Innovative Products is Expected to Support the Growth of the Differentiated Cell Isolation Market 7.2.2 Stem Cells 7.2.2.1 Rising Government Initiatives Focused on Supporting Stem Cell Research Expected to Drive Market Growth 7.3 Animal Cells 7.3.1 Biopharmaceutical Companies are the Major End-users of Isolated Animal Cells

8 Cell Isolation Market, by Cell Source 8.1 Introduction 8.2 Bone Marrow 8.2.1 a Number of Bone Marrow-Derived Stem Cells Have Been Commercialized in the Last Decade 8.3 Adipose Tissue 8.3.1 Adipose Stem/Stromal Cells Can Generate a Variety of Other Cell Types 8.4 Cord Blood/Embryonic Stem Cells 8.4.1 Market Growth is Driven by the High Therapeutic Potency of These Stem Cells

9 Cell Isolation Market, by Technique 9.1 Introduction 9.2 Centrifugation-Based Cell Isolation 9.2.1 Cost-Effectiveness of this Technique in Both Small-Scale and Large-Scale Operations - A Major Driver 9.3 Surface Marker-Based Cell Isolation 9.3.1 Wide Usage of this Technique in Biopharmaceutical and Biotech Industries is a Major Reason for the Growth of this Market 9.4 Filtration-Based Cell Isolation 9.4.1 The Major Factor Driving the Growth of this Market Segment is the Low Cost of the Filtration Technique

10 Cell Isolation Market, by Application 10.1 Introduction 10.2 Biomolecule Isolation 10.2.1 Biomolecule Isolation Dominates the Cell Isolation Applications Market 10.3 Cancer Research 10.3.1 High Disease Incidence Has Fuelled the Demand for Advanced Treatment 10.4 Stem Cell Research 10.4.1 Increasing Funding in Stem Cell Research to Support Market Growth 10.5 Tissue Regeneration & Regenerative Medicine 10.5.1 Funding for Regenerative Medicine Initiatives Has Risen 10.6 in Vitro Diagnostics 10.6.1 Rising Disease Incidence Has Driven Demand for Innovative Therapies and Diagnostics

11 Cell Isolation Market, by End-user 11.1 Introduction 11.2 Biotechnology & Biopharmaceutical Companies 11.2.1 Favorable Investments Have Boosted Overall Pace of Research 11.3 Research Laboratories & Institutes 11.3.1 Rising Funding for Cell-Based Research to Drive Market Growth 11.4 Hospitals & Diagnostic Laboratories 11.4.1 Increasing Number of Hospitals in Emerging Countries Will Contribute to Market Growth 11.5 Other End-users

12 Cell Isolation Market, by Region 12.1 Introduction 12.2 North America 12.3 Europe 12.4 Asia-Pacific 12.5 Row

13 Competitive Landscape 13.1 Overview 13.2 Market Ranking Analysis, 2019 13.3 Key Strategies 13.3.1 Product Launches, 2017-2020 13.3.2 Expansions, 2017-2020 13.3.3 Partnerships, 2017-2020 13.3.4 Acquisitions, 2017-2020 13.4 Competitive Leadership Mapping (2019) 13.4.1 Stars 13.4.2 Emerging Leaders 13.4.3 Pervasive Players 13.4.4 Participants

14 Company Profiles 14.1 Thermo Fisher Scientific, Inc. 14.2 Becton, Dickinson and Company 14.3 Beckman Coulter Inc. (Subsidiary of Danaher Corporation) 14.4 Merck KGaA 14.5 Terumo Bct (Subsidiary of Terumo Corporation) 14.6 GE Healthcare 14.7 Bio-Rad Laboratories, Inc. 14.8 Corning Incorporation 14.9 Roche Diagnostics (A Division of F. Hoffman-La Roche Ltd.) 14.10 Alfa Laval 14.11 Miltenyi Biotec 14.12 Pluriselect Life Science Ug (Haftungsbeschrankt) & Co. Kg 14.13 Stemcell Technologies, Inc. 14.14 Akadeum Life Sciences 14.15 Bio-Techne 14.16 Biolegend 14.17 Biolegend

15 Appendix 15.1 Insights of Industry Experts 15.2 Discussion Guide

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The Worldwide Cell Isolation/Cell Separation Industry is Expected to Grow at a CAGR of 16.8% Between 2020 to 2025 - PRNewswire

Catheters Market: Europe and North America Emerge as Leading Regional Market with Well-established Healthcare Infrastructure – BioSpace

Catheters Market: Snapshot

A catheter refers to a thin tube inserted in the human body for performing a surgical procedure or during the treatment of several diseases. In healthcare sector, catheters are used for a wide range of purposes. These devices are used in numerous medical procedures including cardiac electrophysiology, neurosurgery, and angioplasty. Thus, these are considered integral part of healthcare industry worldwide.

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Catheters are manufactured using various medical materials such as silicon rubber, plastic, nylon, and polyvinyl chloride (PVC). Based on the end-use, the companies working in the catheters market make essential changes to the material used while manufacturing their products.

Depending on the purpose of use, catheters are named as urological, cardiovascular, neurovascular, ophthalmic, and gastrointestinal catheters. Among all product types, the vendors working in the global catheters market experience extensive demand for cardiovascular catheters. Key factors for this scenario are the increased number of patients living with cardiovascular health issues and increased heart surgeries in all worldwide locations. Apart from this, the global catheters market witnesses remarkable demand for urological catheters.

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The enterprises working in the global catheters market are growing focus toward the development of high quality products. Many enterprises in the market for catheters are strengthening their product portfolio. At the same time, several enterprises in the global catheters market are concentrating on expanding their regional presence.

Due to recent COVID-19 pandemic, the healthcare industry is experiencing remarkable drop in number of surgeries carried out in all worldwide locations. The hospitals from all across the globe were focused on performing emergency surgical procedures. As a result, there was sudden plunge in demand for catheters. However, with the considerable improvement in the pandemic situation, the healthcare sector is now getting back to regular activities. As a result, the global catheters market is expected to experience upward graph of sales in the forthcoming years.

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Global Catheters Market: Snapshot

The demand for catheters is expected to remain high in the coming years observes Transparency Market Research. Development and commercialization of various types of catheters for a wide range of applications has significantly propelled the global market in recent years. Catheterization is an important procedure before performing major surgeries. Thus, growing incidences of cardiovascular diseases, kidney disorders, urinary tract procedures, and increasing demand for minimally invasive surgeries has drastically spiked the demand for catheters in the recent years. Growing geriatric population is also projected to be an integral factor in driving the demand for catheters in the near future. According to the research report, the global catheters market is projected to be worth US$55,985.1 mn by the end of 2025. During the forecast years of 2017 and 2025, the global catheters market is expected to exhibit a CAGR of 7.4%.

Hospitals to Remain Key Users of Catheters over Forecast Period

On the basis of end users, the global catheters market is segmented into ambulatory surgical center, hospitals, and dialysis centers amongst others. Out of these, the hospitals segment dominates the global market as they are obvious key users of catheters. The ambulatory services segment follows this one closely. The report points out that hospitals segment will continue to dominate throughout the forecast period due to growing number of private and government-run hospitals that are expected to come up in the near future. Furthermore, efforts taken by government initiatives to reduce the hospital-related expenditure are also projected to work in the favor of catheters market in the near future.

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Cardiovascular Catheters to Dominate Global Market as Cardiovascular Treatments Remain on the Rise

The various types of catheters available in the global market are cardiovascular catheters, urology catheters, intravenous catheters, specialty catheters, and neurovascular catheters. Out of these, the demand for cardiovascular catheters is projected to remain the highest. The high prevalence of cardiovascular diseases and the rising number of surgeries pertaining to treating the same are stoking the demand for cardiovascular catheters. The World Health Organization states that the cardiovascular diseases are the main cause of deaths across the world. Statistics revealed by WHO states that 17.7 million met a fatal end due to cardiovascular diseases in 2015. These alarming figures are projected to be the primary growth driver for the cardiovascular catheters segment. Furthermore, the increasing demand for minimally-invasive procedures has also supplemented the growth of the market.

Europe and North America Emerge as Leading Regional Market with Well-established Healthcare Infrastructure

Geographically, the global catheters market is segmented into Europe, North America, Asia Pacific, Latin America, and the Middle East and Africa. Out of this, the North America catheters market is expected to lead the way. This regional segment will be driven by the well-established healthcare infrastructure in the region. This has definitely augmented the number of catheterization procedures, thereby boost the regional markets revenue earnings. Europe is projected to follow North Americas lead in the coming years. The growing pool of geriatrics, high incidences of lifestyle disorders, and tremendous technological advancements and acceptance of the same are expected to keep these two regional markets motivated throughout the forecast period.

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On the other hand, the Asia Pacific catheters market too is expected to show rapid growth rate in the coming years. Rise of medical tourism, increasing efforts by the governments of the developing countries to better the healthcare infrastructure, and technological advancements are expected to offer many lucrative opportunities to this regional market.

Some of the leading players operating in the global catheters market are Abbott Laboratories, Dickinson and Company, Becton, C. R. Bard, Inc., B. Braun Melsungen AG, Medtronic plc., Teleflex Incorporated, JOHNSON & JOHNSON, Cook Group Incorporated, and Boston Scientific Corporation.

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Catheters Market: Europe and North America Emerge as Leading Regional Market with Well-established Healthcare Infrastructure - BioSpace

Near-infrared oxidative phosphorylation inhibitor integrates acute myeloid leukemiatargeted imaging and therapy – Science Advances

Abstract

Acute myeloid leukemia (AML) is a deadly hematological malignancy with frequent disease relapse. The biggest challenge for AML therapy is the lack of methods to target and kill the heterogeneous leukemia cells, which lead to disease relapse. Here, we describe a near-infrared (NIR) fluorescent dye, IR-26, which preferentially accumulates in the mitochondria of AML cells, depending on the hyperactive glycolysis of malignant cell, and simultaneously impairs oxidative phosphorylation (OXPHOS) to exert targeted therapeutic effects for AML cells. In particular, IR-26 also exhibits potential for real-time monitoring of AML cells with an in vivo flow cytometry (IVFC) system. Therefore, IR-26 represents a novel all-in-one agent for the integration of AML targeting, detection, and therapy, which may help to monitor disease progression and treatment responses, prevent unnecessary delays in administering upfront therapy, and improve therapeutic efficiency to the residual AML cells, which are responsible for disease relapse.

Acute myeloid leukemia (AML) is a deadly hematological malignancy, comprising the genetically and morphologically heterogeneous groups of aggressive malignant cells (1, 2). Although deep sequencing and recent molecular discoveries have provided tremendous insights into the underlying biology of AML, the long-term survival for AML patients is still unsatisfactory. This is due to the current treatment strategies failing to eliminate all malignant cells, which will eventually lead to disease relapse (3). Disease relapse is the most common cause of death in AML patients, and the lack of subsequent treatment strategies after relapse makes the cure of AML more challenging. Recent studies indicate the heterogeneous constitution of AML containing different types of leukemia cells with variable responses to chemotherapies. Among them, a rare population of residual chemotherapy-resistant leukemia cells is thought to drive the AML relapse after therapy (4, 5). Techniques such as real-time quantitative polymerase chain reaction (qPCR) or multiparameter flow cytometry have been used to assess malignant cells in AML based on specific mutations, which have provided prognostic information for patient outcomes and profoundly affect clinical decision-making for disease management (3, 6). However, most AML patients fail to present enough typical mutations for current detection due to genetic abnormal heterogeneity and genomic complexity (7, 8). The residual leukemia cells are a rare population of cells responsible for reinitiating and maintaining disease, which are infeasible to be collected to enough events at the right time to evaluate valid disease information using current techniques. Therefore, developing new AML-targeting methods based on the common vulnerability of malignant cells is urgently needed to accurately detect and eliminate the heterogeneous malignant cells in AML patients. Especially, strategies combining targeted therapy with on-time treatment response monitoring and real-time detection of residual cells will help to prevent unnecessary delays in administering upfront therapy in AML, improve treatment efficiency, and reduce disease relapse (9, 10). Thus, a new strategy simultaneously achieving malignant cells targeting detection and therapy is of particular significance in reducing AML relapse and is emerging as the next important direction for AML treatment.

Recently, studies on the fundamental roles of cellular metabolism reprogramming in tumor development and progression are given more emphasis (11). In particular, the increase of glycolysis even in the presence of oxygen, known as aerobic glycolysis, is reported as an important hallmark for cancer cells. AML is no exception to the general rule that increased glycolysis is the basic metabolic characteristic of leukemia cells, and hyperactive glycolysis is a common vulnerability for AML targeting and treatment (12). However, previous therapeutic strategies merely based on glycolytic inhibition fail to achieve satisfactory results in AML treatment. Treatment failure with glycolysis inhibitor occurs because increasing research studies have emphasized that, in addition to glycolysis, some tumors like brain cancer and AML depend more on enhanced mitochondria-specific oxidative phosphorylation (OXPHOS) for bioenergetic and biosynthetic processes (13). In particular, residual chemotherapy-resistant leukemia cells are demonstrated to show increased mitochondrial mass, retain active polarized mitochondria, and rely more on mitochondrial OXPHOS for survival (14). Therefore, current studies on the treatment vulnerability toward mitochondrial OXPHOS in leukemia cells are given more emphasis. Several strategies through inhibition of mitochondrial protein synthesis or inhibition of electron transport chain (ETC) complexes may hold great therapeutic potential in AML treatment (13, 15, 16). However, mitochondrion is the central checkpoint of cell metabolism and is involved in energetic and biosynthetic processes of cells; the integrity and functions of mitochondria are comparably important for almost all cells. The present application of OXPHOS inhibitors in anticancer therapy limits our understanding of mitochondria in cancer cells and the lack of tumor-targeting accumulation strategies, which may result in OXPHOS inhibitors not sufficiently reaching the tumors (17) and inducing unacceptable side effects, like neurotoxicity (18, 19) and nausea/vomiting (20). Thus, the development of new strategies with both malignant cell targeting property and mitochondrial OXPHOS inhibiting ability would hold great therapeutic promise in improving AML treatment efficacy and reducing side effects. In previous work, we have synthesized a class of heptamethine cyanine dyes with structure-inherent near-infrared (NIR) fluorescence and solid tumor targeting ability (21, 22). The heptamethine cyanine dyes are preferentially retained in the mitochondria of different kinds of solid tumor cells, relying on the hyperactivity of hypoxia-inducible factor1 (HIF-1)/glycolysis metabolism and the increase of SLCO1B3 transporters activity in tumor cells (2325). Because aerobic glycolysis is the basic metabolic characteristic of malignant cells and has profound effects on tumor genesis and progression, these dyes provide a new mechanism for tumor-targeting strategy based on the inherent functional properties of tumor cell metabolism. In this study, we aim to characterize a candidate NIR dye for hematological malignancy targeting and therapy by modifying with water-soluble amino acid ester groups in heptamethine cyanine dyes. Of the newly synthesized dyes, we have identified IR-26 as an all-in-one NIR dye for integrating AML targeting, detection, and therapy simultaneously. The newly designed IR-26 dye retains the preferential accumulation ability in the mitochondria of hematological malignant cells rather than normal cells depending on the same mechanism as in solid tumors. The water solubility of IR-26 is greatly improved by inhibiting the intermolecular hydrogen bond formation, which would decrease J1 aggregates and the serum protein binding rate of IR-26, favoring hematological malignant cell targeting. IR-26 also has the NIR fluorescent ability with the absorption and emission peak in the range of 700 to 900 nm, which has great advantages for cancer cell imaging with deep tissue penetration and low-background autofluorescent interference (26, 27). Therefore, IR-26 is demonstrated to dynamically detect the circulating malignant cells in vivo in a noninvasive way using a NIR in vivo flow cytometry (IVFC) system established previously (28), which holds significance in continuously monitoring of disease progression, treatment responses, and disease relapse. IR-26 is demonstrated to target the ETC proteins, SDHA, and ATP5B and inhibit the complex II and complex V activities to impair mitochondrial OXPHOS functions, resulting in increased apoptosis in AML cells. IR-26 exerts its excellent therapeutic efficiency in AML by selectively inhibiting the leukemia cell population and prolonging the survival of AML mice without inducing obvious side effects. Overall, our work may provide an entirely new mechanism for AML targeting based on the hyperactive glycolytic metabolism of malignant cells and a rational therapeutic strategy for integrating AML targeting, detection, and treatment by a glycolysis-dependent mitochondrial OXPHOS inhibitor, IR-26, which indicates a new opportunity to improve AML clinical treatment efficiency and reduce disease relapse.

On the basis of previous structure-activity studies, we have characterized that heptamethine core with lipophilic cationic property is essential for tumor targeting in heptamethine cyanine dyes (29, 30). In this study, we have synthesized a series of derivatives by modifying with various N-alkyl side chains on the heptamethine core to obtain new dyes that target AML cells. Eight candidate mitochondria-targeted dyes were chosen to study their AML cell-targeting properties. As shown in fig. S1A, IR-26 exhibited the highest NIR fluorescence contrast index values when compared with other dyes, suggesting a good preferential accumulation ability to AML cells. Moreover, IR-26 showed the highest cytotoxicity in AML cells (fig. S1B), with a half-maximal inhibitory concentration (IC50) of only 2.660 M. The synthetic route and chemical structure of IR-26 are shown in fig. S2 and Fig. 1A. The absorption and fluorescence spectra of IR-26 were investigated in methanol (MeOH), 10% fetal bovine serum (FBS), and phosphate-buffered saline (PBS; Fig. 1, B and C) and indicated that the absorption and emission peak of IR-26 were in the NIR region (700 to 900 nm). IR-26 showed good stability in 10% serum and was easy to disperse in the PBS solution without disturbing serum albumin (fig. S3). All these features make IR-26 a promising NIR dye for hematological malignancy biomedical imaging. Then, human AML cells, HL-60, or peripheral blood mononuclear cells (PBMCs) were incubated with IR-26 at similar conditions; cellular NIR fluorescence was detected by confocal microscopy. Figure 1D shows that IR-26 accumulated in HL-60 cells increasingly in a time-dependent manner, indicating its preferential accumulation ability in AML cells. This AML-targeted property was also observed in different types of AML cell lines (HL-60, NB4, and THP-1; Fig. 1E) when compared with the normal PBMCs. Last, athymic nude mice with green fluorescent protein (GFP)labeled HL-60 (lentiviral transfection) tumor xenografts at subcutaneous spaces were imaged after a single administration of IR-26 at 0.2 mg/kg through intravenous injection. Figure 1F and fig. S4A show that intense NIR signals can be clearly visualized, associated with the implanted GFP-labeled HL-60 tumor sites using Kodak In-Vivo Imaging System FX Pro. Histopathologic analysis of tumor frozen section indicated that NIR fluorescence was colocalized with GFP fluorescence in cancer cells (fig. S4B), further demonstrating the preferential accumulation of IR-26 in AML cells. Thus, IR-26 may be a promising NIR dye for hematological malignancy targeting and biomedical imaging based on our results.

(A) Chemical structure of IR-26. (B) Absorption spectra of 2 M IR-26 in 10% FBS, methanol (MeOH), and PBS. (C) Fluorescence emission spectra of IR-26 in 10% FBS, methanol (MeOH), and PBS. a.u., arbitrary units. (D) NIR fluorescence intensity in human peripheral blood mononuclear cells (PBMCs) and HL-60 cells was compared after incubation with the same concentration of IR-26 for various times (n = 3). MitoTracker Green was used to avoid the impact of cell size in comparing fluorescence of PBMCs to AML cells. (E) PBMCs and AML cell lines (HL-60, NB4, and THP-1) were incubated with IR-26 for the same condition and imaged by a laser confocal scanning microscope (Leica) with 633-nm excitation. (F) Preferential accumulation of IR-26 in athymic tumor-bearing nude mice preestablished with GFP-labeled HL-60 tumor xenografts. The animals were subjected to fluorescence imaging and x-ray imaging using Kodak In-Vivo Imaging System FX Pro (New Haven, CT). Photo credit: Tao Liu, Institute of Rocket Force Medicine, Third Military Medical University. Error bars denote means SD. *P < 0.05.

To further investigate whether the leukemia-targeted IR-26 could be used to detect AML cells in peripheral blood, PBMCs and preestablished GFP-labeled HL-60 cells were mixed to mimic the complex cellular components in peripheral blood and incubated with 5 M IR-26 under 37C. Then, the mixed cells were detected using flow cytometry, and the results showed that IR-26 could easily distinguish the HL-60 cells from PBMCs by NIR fluorescence (Fig. 2A). IR-26 could recognize the same population of leukemia cells as GFP-labeled cells in the mixed cells (Fig. 2, B and C) with a good accuracy in targeting AML cells. Under confocal microscopy, all GFP-labeled AML cells could be detected by IR-26 (Fig. 2D). The NIR fluorescent cell population was a little bigger than the GFP fluorescent cell population (Fig. 2E), indicating a better sensitivity of NIR fluorescent dye in AML cell detection than GFP. Impressively, IR-26 could also be used to detect AML cells from clinical patients when compared with PBMCs from healthy donor (Fig. 2F). To further investigate the detection property of IR-26 in leukemia cells in vivo, a mouse model of human AML was established by intravenous injection of GFP-labeled human AML cells into sublethally irradiated C57BL/6 mice (Fig. 2G). Histological examination and immunohistochemistry assay revealed that extensive infiltration of GFP-labeled leukemia blast cells was shown in the hematopoietic organs (fig. S5, A and B), and the spleens from the transplantation group were much heavier than those from the control group (fig. S5C). In addition, we have established a NIR IVFC that treats blood flow as the natural sheath flow for tracking of specific cells in the circulatory system noninvasively. The IVFC was used to observe, in the long term, GFP fluorescent cells in animal peripheral blood and showed that GFP-labeled HL-60 cells continuously existed in the circulatory system of transplanted mouse for more than 20 days (fig. S5D), further confirming the stability of AML animal models. To test whether IR-26 could be used to monitor AML cells in real time, the dual-channel (GFP and NIR fluorescence) IVFC was used to detect the NIR fluorescent leukemia cells in vivo after mice were intravenously injected with IR-26 (0.2 mg/kg), with GFP fluorescence as the internal reference of GFP-labeled HL-60 cells. Figure 2H shows a representative data trace of leukemia cells with both GFP and NIR fluorescence signal in the AML animal model, indicating that IR-26 could be used to specifically detect AML cells in vivo using the IVFC system. After 10 min of detection, the number of peaks per minute in GFP channel, NIR channel, or dual channel showed no statistical significance (Fig. 2I), suggesting the good sensitivity and accuracy of IR-26 in detecting AML cells in vivo. To further validate the leukemia targeting property of IR-26 in vivo, bone marrow, spleen frozen section, and peripheral blood were detected by confocal microscopy after mice were sacrificed. As shown in Fig. 2J, the NIR fluorescence signal overlapped with GFP-labeled leukemia cells in all these organs, which confirmed the targeting and detection property of IR-26 in AML cells. Last, we studied the indicated mechanisms for the leukemia-targeting property of IR-26. As shown in fig. S6A, inhibition of cellular glycolysis by 150 mM 2-deoxy-d-glucose or inhibition of SLCO1B3 transporters activity by 250 M sulfobromophthalein reduced the uptake of IR-26 in AML cells, which was similar to our previous studies in solid tumor targeting. In addition, the cellular level of HIF-1 was also demonstrated to be responsible for the preferential uptake of IR-26 in leukemia cells (fig. S6B). We further observed that the expression of SLCO1B3 was positively correlated with HIF-1 level in AML cells (fig. S6C). The expression of SLCO1B3 was also demonstrated to be up-regulated in AML patients (fig. S6, D and E), which was analyzed from the public data GSE9476. In conclusion, IR-26 was demonstrated to directly target AML cells based on the hyperactivity of HIF-1/glycolysis metabolism and increased SLCO1B3 transporters activity in leukemia cells, which was similar to the previous targeting mechanism in solid tumors (23). This entirely new AML-targeting mechanism may greatly help to improve AML treatment strategy in disease detection and therapy.

(A) Flow cytometry (BD FACSVerse, BD Biosciences) analysis of the AML-targeting property of IR-26 in PBMCs and GFP-labeled HL-60 mixed cells; NIR fluorescence was detected with 633-nm excitation and 780-nm emission after mixed cells were incubated with IR-26 or PBS. (B and C) Flow cytometry analyzing the accuracy of IR-26 in targeting the GFP-labeled leukemia cell population in the mixed cells. (D) Confocal microscope detected the colocalization of NIR fluorescence with GFP fluorescence after the mixed cells were incubated with IR-26. (E) Pie chart showing a better sensitivity of NIR fluorescent dye in detecting AML cells than GFP fluorescence. (F) Colocalization of IR-26 with AML cells in the clinical AML patient sample after incubation with 5 M IR-26 for 20 min. Images were obtained using a confocal microscope (Leica) with 633-nm excitation. Nuclei were stained with Hoechst (blue). (G) Schematic representation of the experimental design (see also Materials and Methods) for AML cell detection in vivo by IR-26. (H) Data showing fluorescence peaks in IVFC of GFP channel (green) and IR-26 channel (red) and representative dual positive peak in both channels, indicating the accurate tracing of GFP-labeled AML cells in peripheral blood. (I) Statistical histogram showing the number of peaks per minute in the GFP channel, the NIR channel, and the dual channel detected using IVFC in peripheral blood of AML mouse model (P > 0.05). (J) Histopathologic analysis of peripheral blood, spleen, and bone marrow frozen sections of the AML mouse model by confocal microscope. Nuclei were stained with 4,6-diamidino-2-phenylindole (DAPI; blue). Error bars denote means SD.

In consideration of the AML targeting and detection property of IR-26, further investigation of anti-leukemia effects of IR-26 may help to improve AML treatment strategies by integrating AML continuous detection and targeted treatment. IR-26 showed the highest cytotoxicity for AML cells among the eight candidate dyes. Further studies indicated that IR-26 effectively killed different types of AML cell lines (HL-60 and THP-1) in a concentration-dependent manner, with IC50 values of 2.629 and 2.351 M, respectively (Fig. 3A). Western blot analysis indicated that IR-26 induced mitochondrial apoptosis in HL-60 and THP-1 cells by inducing PARP [poly(adenosine diphosphateribose) polymerase], caspase-3, and caspase-9 cleavages (Fig. 3B). Annexin V and propidium iodide (PI) staining by flow cytometry detection also indicated that IR-26 induced apoptosis in AML cells (Fig. 3C). To examine the potency of IR-26, which is widely used across species, the response of IR-26 to mouse and human leukemia cell lines (C1498, P388D1, HL-60, and THP-1) was assessed using oxygen consumption rate (OCR) and galactose viability assay. Figure S7 showed that IR-26 was similarly active in mouse (average IC50 = 4.788 M) and human cells (average IC50 = 2.913 M). Then, the cytotoxicity of IR-26 on AML cells and normal PBMCs was compared, and Fig. 3D shows that IR-26 induced HL-60 cell death with no obvious cytotoxic effects on human hematopoietic stem cells (HSCs), suggesting the targeted killing effects of IR-26 on AML cells. Moreover, IR-26 was also demonstrated to inhibit cell colony formation in HL-60 cells (Fig. 3E) and decreased the CD34+CD38 subset of HL-60 cells with the increase of IR-26 (Fig. 3F), suggesting the inhibition effects of IR-26 on AML stem-like cells, which are responsible for chemotherapy resistance in AML. In summary, these studies indicated that IR-26 selectively induced apoptosis in AML cells and even in chemotherapy-resistant subset of cells, while the concentrations that appear pharmacologically achievable did not have similar negative effects on normal cells.

(A) Human AML cell lines (HL-60 and THP-1) were treated with various concentrations of IR-26 for 48 hours, and IC50 values were calculated. (B) HL-60 and THP-1 cells were treated with various concentrations of IR-26, and apoptosis-related markers were detected using Western blot. Glyceraldehyde-3-phosphate dehydrogenase (GAPDH) was taken as the loading control. (C) HL-60 and THP-1 cells were treated with IR-26 for 24 hours and stained with annexin V/PI to detect cell apoptosis by flow cytometry. (D) HL-60 cells and human hematopoietic stem cells (HSCs) were treated with different concentrations of IR-26 for 48 hours, and cell viability was measured and compared. (E) HL-60 cells were treated with IR-26 (5 M) or dimethyl sulfoxide (DMSO) for 6 hours; 800 cells per well were seeded in the methylcellulose medium and cultured for 2 weeks; cells colonies were imaged and counted under inverted microscope. (F) Flow cytometry analysis and percentage of CD34+CD38 cell subset after HL-60 cells were treated with different concentrations of IR-26. Error bars denote means SD. **P < 0.01.

To further assess the anti-leukemia treatment effects of IR-26 in vivo, two AML mouse models were established and used. First, the AML xenograft mouse models were established by subcutaneous injection of HL-60 cells in the nude mice. After tumors became palpable, the mice were randomly divided into three groups and received intraperitoneal injection of PBS, cytarabine (50 mg/kg), and IR-26 (5.0 mg/kg). As shown in Fig. 4A, a distinct inhibition of tumor growth was observed after IR-26 treatment, while the treatment effect of cytarabine was limited. Tumor weight, which was measured after mice sacrifice, also indicated the marked anti-leukemia effect of IR-26 in vivo (Fig. 4B). Compared with the control group, IR-26 treatment did not cause body weight change (Fig. 4C) and obvious pathologic changes in vital organs (fig. S8), indicating its satisfactory safety for in vivo treatment. To evaluate the anti-leukemia effects of IR-26 at different doses, nude mice bearing HL-60 subcutaneous xenografts received IR-26 at doses of 0, 1, 3, or 5 mg/kg intraperitoneally. Figure S9 indicated that treatment with IR-26 at doses of 1, 3, and 5 mg/kg were all effective and led to significant tumor regression with no obvious body weight loss. Moreover, nonobese diabetic/severe combined immunodeficient (NOD/SCID) mice were engrafted with GFP-labeled human AML cells HL-60 by tail vein injection to establish orthotopic AML mouse model. One week after primary transplant of GFP-labeled AML cells, mice were treated with cytarabine (50 mg/kg) or IR-26 (5.0 mg/kg) every other day by intraperitoneal injection for five times (Fig. 4D; n = 12). At day 25, Kodak In-Vivo Imaging System FX Pro showed that dissected organs from IR-26treated group displayed no obvious GFP fluorescence, while organs from other groups showed strong GFP fluorescence (Fig. 4E), suggesting that nearly all GFP-labeled AML cells disappeared after mice were treated with IR-26. Moreover, IR-26 markedly prolonged the median survival of mice in Kaplan-Meier analysis when compared with the cytarabine-treated group (Fig. 4F; P = 0.0075). IR-26 treatment remarkably reduced tumor burden, manifested with a prominent decrease in percentage of hCD45+ cells in the bone marrow (Fig. 4G). Hematoxylin and eosin staining revealed significantly reduced infiltration of leukemic cells and increased preservation of normal tissue structures in the bone marrow and other organs of mice treated with IR-26 when compared with the control group mice (Fig. 4H and fig. S10). The pharmacokinetic profiles are important for drug effectiveness and biosafety. The blood curve of IR-26 was also determined after intraperitoneal injection at a dose of 5 mg/kg (fig. S11), and the pharmacokinetic parameters were calculated (t1/2 = 56.43 6.38 hours, Cmax = 115.23 6.73 g/liter, Tmax = 4 1.73 hours).

(A) IR-26 effectively inhibits tumor growth in nude mice inoculated with HL-60 cells. Mice were treated with IR-26 (5 mg/kg every third day by intraperitoneal injection), cytarabine (50 mg/kg), or vehicle control; tumor volumes were calculated as length (width)2/2. n = 5, **P < 0.01 compared with the control group. (B) Tumor weights of mice were measured and compared (n = 5, **P < 0.01 compared with the control group). (C) Mice body weights were measured and compared (n = 5). (D) Schematic representation of the experimental design (see also in Materials and Methods) for anti-leukemia assay in mouse model, which is established by intravenous injection of GFP-labeled HL-60 cells into NOD/SCID mice. Mice were intraperitoneally (i.p.) injected with IR-26 (5 mg/kg), cytarabine (50 mg/kg), or PBS as vehicle control. (E) Detached liver, heart, spleen, and kidney were subjected to GFP and NIR imaging at day 25 after treatment, indicating a distinct decrease of GFP-labeled AML cells in IR-26treated mice. Photo credit: Yang Wang, Institute of Rocket Force Medicine, Third Military Medical University. (F) Kaplan-Meier curve analysis demonstrated a survival advantage for mice treated with IR-26 (n = 12, P = 0.0075). (G) Chimerism of human HL-60 cells in the mouse bone marrow was quantified and compared by detecting cells that express human CD45 at day 25. (H) Pathologic analysis of bow marrow morphologic information in control and IR-26treated mouse. Error bars denote means SD.

Because of the effective therapeutic benefits of IR-26 in AML, further investigation of the underlying mechanisms of IR-26induced cell death is needed. Our previous studies have indicated that this kind of lipophilic cationic heptamethine dyes is more ready to reach a higher concentration in mitochondria due to the negative charge (21), and some mitochondrial membrane transporters may also help to transport into mitochondria (25). A subcellular location assay was performed, and it indicated that IR-26 specifically accumulated in the mitochondria of AML cells by colocalization with the mitochondria-specific probe MitoTracker Green (Fig. 5A). Moreover, transmission electron microscopy showed that IR-26 treatment induced mitochondria swelling and vacuolation in AML cells (Fig. 5B). IR-26 treatment also decreased mitochondrial membrane potential in AML cells (Fig. 5C). All these mitochondrial changes after IR-26 treatment suggested that mitochondria might be an important therapeutic target of IR-26. Our data further showed that IR-26 treatment increased mitochondrial reactive oxygen species (ROS) production in AML cells (Fig. 5D), and the mitochondrial ROS-specific scavenger MitoTEMPO significantly reversed IR-26induced ROS production and cell death (Fig. 5E). Real-time analysis of mitochondrial respiration profiles using a seahorse XF96 analyzer indicated that IR-26 reduced the basal mitochondrial OCRs and the maximal respiration of mitochondria in HL-60 cells (Fig. 5F). In addition, the adenosine triphosphate (ATP) production was significantly decreased after cells were treated with increasing concentrations of IR-26 (Fig. 5G). These data suggested that mitochondrial OXPHOS of AML cells was markedly destroyed by IR-26 treatment. The adenosine monophosphateactive protein kinase (AMPK) is a key susceptor in the regulation of energy metabolism. IR-26 treatment significantly increased phospho-AMPK in AML cells, indicating the activated AMPK signaling in response to OXPHOS inhibition (Fig. 5H). All these data indicate that mitochondria are the important therapeutic target of IR-26, and directly impairing mitochondrial OXPHOS functions is the key mechanism of IR-26 to induce cell death in AML.

(A) Specific accumulation of IR-26 in the mitochondria of HL-60 cells by colocalization with the mitochondria-specific probe (MitoTracker Green). (B) Transmission electron microscopy observation of mitochondrial morphologies in HL-60 cells. Black arrow indicates mitochondria. (C) Mitochondrial membrane potential was evaluated by the JC-1 aggregate/monomer fluorescence ratio in HL-60 cells. (D) Mitochondrial ROS productions in HL-60 cells were detected using MitoSOX (Invitrogen, Carlsbad, CA) after cells were treated with IR-26 for 1 hour (n = 3). (E) HL-60 cell viabilities were detected after cells were treated with increasing concentrations of IR-26 in the presence or absence of the mitochondrial ROS-specific inhibitor MitoTEMPO. (F) Real-time analysis of mitochondrial respiration profile of HL-60 cells using a seahorse XF96 analyzer after cells were treated with 10 M IR-26 for 1 hour. (G) HL-60 cells ATP production were detected after treatment with 10 M IR-26 for different times. (H) Western blot analysis of the energy metabolism regulating protein and AMPK signaling expression in HL-60 and THP-1 cells after treatment with different concentrations of IR-26. Error bars denote means SD. *P < 0.05 and **P < 0.01.

To further explore the molecular mechanism through which IR-26 disrupts mitochondrial functions and OXPHOS in AML cells, metabolomic and molecular target analyses were performed in IR-26treated HL-60 cells. First, HL-60 cells were treated with different concentrations of IR-26 for 12 hours, and cell lysates were subjected to TSQ Quantiva (Thermo Fisher Scientific, CA) analysis to measure metabolites from central carbon metabolism. Figure 6A shows that IR-26 treatment elevated the level of mitochondrial complex II substrate, succinate, but reduced the levels of downstream metabolites, fumarate and malate, in the tricarboxylic acid (TCA) cycle. These changes are consistent with mitochondrial complex II activity inhibition. Moreover, after HL-60 cells were treated with different concentrations of IR-26, all activities of mitochondrial respiratory chain complexes were detected using a MitoTox OXPHOS complex activity assay kit (Abcam), indicating that complex II and complex V activities were distinctly inhibited by IR-26 treatment (Fig. 6B). We then identified the potential interactive proteins of mitochondrial respiratory chain with IR-26 using a previously established method (31) and indicated that SDHA and ATP5B might be the interactive proteins of IR-26. The pull-down assay using the specific antibodies of SDHA and ATP5B further determined that IR-26 interacted with complex II and complex V proteins, SDHA and ATP5B (Fig. 6C). Therefore, the data suggested that IR-26 directly targeted the mitochondrial ETC proteins SDHA and ATP5B to inhibit complex II and complex V activities and disturbed mitochondrial OXPHOS functions to induce targeted killing effects in AML cells.

(A) After treatment with different concentrations of IR-26, HL-60 cell lysates were subjected to TSQ Quantiva (Thermo Fisher Scientific, CA) analysis to measure the metabolites from tricarboxylic acid (TCA) cycle and the levels of TCA cycle intermediates, -ketoglutarate (-KG), succinate, fumarate, and malate after treatment with IR-26. AU, arbitrary units; CoA, coenzyme A. (B) Mitochondrial complex activities were measured after treatment with IR-26 using a commercially available kit (Abcam). (C) Pull-down assay was performed using mitochondrial protein ATP5B, SDHA, and NDUFS1 antibodies in IR-26treated cancer cell lysates, showing that ATP5B and SDHA antibodies pulled down proteins with NIR fluorescence, but NDUFS1 antibody pulled down proteins with no NIR fluorescence, indicating that IR-26 directly targets mitochondrial proteins ATP5B and SDHA. Error bars denote means SD. *P < 0.05. IgG, immunoglobulin G; IP, immunoprecipitation.

AML is one of the most common acute leukemia in adults. Standard chemotherapy treatment for AML with 7 days of cytarabine followed by 3 days of anthracycline has been used for more 30 years, but the novel targeted therapies for AML are very limited (32). Despite the fact that reduction of leukemic cells can be achieved with conventional chemotherapy in most AML patients, disease relapse is not solved and the long-term outcomes of AML patients have not significantly improved. This is due to the fact that heterogeneous organization of AML contains a rare subpopulation of leukemia cells that are resistant to the present chemotherapy. The subset of resistant AML cells with dormancy and self-renewal properties could initiate and maintain the disease; thus, even a rare number of residual cells could drive disease relapse after chemotherapy (33). However, current strategies fail to specifically target leukemic cells and eliminate all chemotherapy-resistant cells. Accurately targeting and determining how leukemic cells behave in vivo have significant impact for the early diagnosis of leukemia, for monitoring treatment response, and for detecting how minimal residual leukemia cells lead to disease relapse after treatment (34). Techniques such as real-time qPCR or multiparameter flow cytometry have been used to assess specific malignant cells in AML and have been proven to positively affect the clinical decision-making for disease management, providing prognostic information for patient outcomes. These methods could not collect enough events at the right time to evaluate valid disease information because the residual leukemia cells are a rare population of cells. Furthermore, these strategies aim at specific genetic mutations in leukemia cells, such as FLT3, NPM1, DNMP3A, and IDH1/2 (35, 36), to detect malignant cells. However, most AML patients do not present typical mutations because of the complexity of genomic mutation and the abnormal heterogeneity in different leukemia cells. Therefore, developing a new AML-targeting strategy based on the common vulnerability of malignant cells is urgently needed. In this study, the identified NIR fluorescence dye IR-26 is demonstrated to specifically target leukemia cells in vitro and in vivo based on the mechanism of hyperactive HIF-1/glycolysis metabolism and increased SLC1B3 transporters activity, which is similar to our previous studies in solid tumor targeting (19, 21). Because aerobic glycolysis is known as the basic metabolic characteristic and an important hallmark of malignant cells, our studies may represent an entirely new AML-targeting strategy based on the common vulnerability of malignant cells. IR-26 also has an intrinsic NIR fluorescent property with the absorption and emission peak in the NIR region (700 to 900 nm). With advantages of low background interference and deep tissue penetration, the NIR fluorescence imaging has already been dedicated immense attention in tumor detection. We have established a dual-channel (GFP and NIR) fluorescence IVFC system to treat blood flow as natural sheath flow for identifying and quantifying specific cells in circulatory system without extracting blood samples (28). Using the IVFC system, the NIR fluorescence dye IR-26 is demonstrated to specifically detect and continuously monitor hematologic malignant cells in peripheral blood of transplanted AML mouse model in a noninvasive way. Thus, our studies may set out a new strategy with AML cell-specific targeting and detection to continuously monitor AML disease progression and treatment response, which will greatly help to prevent unnecessary delays in administering upfront therapy and improve treatment efficiency. Especially, IR-26 could continuously detect the rare population of residual leukemia cells to monitor disease relapse in a noninvasive way, which is of particular significance for AML clinical treatment.

Considering that the rare residual leukemia cells in the heterogeneous constitution of AML are demonstrated as the key factor responsible for chemotherapy resistance and disease relapse, identifying the common therapeutic vulnerability of chemotherapy-resistant leukemia cells should be important for AML therapy. Current studies have indicated that chemotherapy-resistant AML cells have unique mitochondrial characteristics of increased mitochondrial biogenesis and prevailingly dependent on OXPHOS for energy production and survival. Targeting the AML-specific alterations of mitochondria may emerge as intriguing targets for AML treatment strategies, especially for the chemotherapy-resistant AML or relapse of AML (37, 38). The OXPHOS metabolic pathway is known to have a critical function in mitochondria by generating a sequential redox reaction within ETC pumping protons across the mitochondrial membrane to generate a gradient for ATP production. Thus, targeting the mitochondrial ETC complexes that directly affect the mitochondrial OXPHOS functions is definitely a theoretically potential target for tumor therapy. The anti-diabetic agent metformin, also known as an inhibitor of mitochondrial respiratory complex I, was evaluated in preclinical and clinical studies for solid tumor treatment and also showed promising results in AML treatment (39). The F0F1 ATP synthase inhibitor Gboxin was used to inhibit the growth of glioblastoma cells in a recent research (40). The inhibitor of complex I, IACS-010759, was identified as a clinical-grade small molecule for phase 1 clinical trials of relapsed/refractory AML, mantle cell lymphoma (MCL), and solid tumors (13). However, mitochondrion is the central checkpoint of cell metabolism, which is involved in energetic and biosynthetic processes for almost all cells; the integrity and functions of mitochondria are also comparably important for normal cells. Most of the present OXPHOS inhibitors are limited in anticancer therapy for the lack of tumor-targeting ability and potential severe side effects. Only Gboxin has been reported to accumulate in malignant cells depending on the high mitochondrial membrane potential and to exert cytotoxicity in glioblastoma (40). However, mitochondrial membrane potential is not the inherent characteristic of malignant cells and is much susceptible to many factors. In the study, we have characterized an AML-targeted dye, IR-26, that selectively accumulates in the mitochondria of AML cells based on the hyperactivity of HIF-1/glycolysis, which is the common metabolic vulnerability and a hallmark of malignant cells. IR-26 robustly inhibited human leukemia cells in both OCR and galactose viability assay with similar IC50 values (average IC50 values were 3.632 and 2.913 M; fig. S7), indicating that OXPHOS inhibition is an important mechanism for the anti-leukemia effect of IR-26 in human cells. IR-26 is also demonstrated to target the mitochondrial complex II protein SDHA and complex V protein ATP5B, decrease the functional activity of complexes II and V simultaneously to impair mitochondrial OXPHOS functions in AML cells, and exert targeted therapeutic effects in AML cells. In particular, IR-26 treatment has benefits for decreasing disease relapse and increasing the long-term survival in AML animal models. Therefore, the glycolysis-dependent OXPHOS inhibitor IR-26 may represent a new AML-targeted therapeutic strategy based on the common metabolic vulnerability of AML cells and may provide an opportunity for targeted killing of residual malignant cells by directly impairing mitochondrial OXPHOS functions.

In summary, our study reveals a new leukemia-targeted mechanism depending on the basic metabolic characteristic of hyperactive glycolysis in AML cells and provides a rational AML therapeutic strategy by integrating simultaneous AML cells detection and targeted treatment. Continuous detection of AML cells in vivo helps to monitor the rare population of residual chemotherapy-resistant leukemia cell behaviors in patients, which may indicate an opportunity for reducing the disease relapse. The AML-targeted therapy based on mitochondrial OXPHOS inhibition has great advantages in selective killing of AML cells rather than normal cells to improve the treatment efficiency in AML without inducing obvious side effects. The multifunctional mitochondrial OXPHOS inhibitor IR-26 represents a new all-in-one agent for the integration of AML targeting, detection, and therapy, which may help to monitor disease progression and treatment responses and improve therapeutic efficiency to the residual cells that are responsible for disease relapse.

The synthetic route of compound IR-26 was shown in fig. S2. Compounds 2 and 4 were prepared according to the previously reported methods (41). Next, compound 5 was synthesized by an amidation reaction between compound 2 (2.12 g, 10 mmol) and compound 4 (1.25 g, 10 mmol) in the presence of triethylamine (Et3N, 10 mmol) with a yield of 60%, white solid, and melting point of 51 to 52C. 1H nuclear magnetic resonance (NMR; 400 MHz, CDCl3) : 1.49 (m, 2H), 1.69 (m, 2H), 1.86 (m, 2H), 2.27 (t, J = 7.5 Hz, 2H), 3.41 (t, J = 6.7 Hz, 2H), 3.77 (s, 3H), 4.06 (d, J = 5.1 Hz, 2H), 5.99 (s, 1H). Subsequently, alkylation reaction between 2,3,3-trimethyl-3H indole and 5 was carried out under 110C for 10 hours in 1,2-dichlorobenzene to obtain compound 6 in the form of indole quaternary ammonium salt. Without purification of 6, it was reacted with 7 (1.03 g, 6 mmol) by a condensation reaction in 40 ml of absolute ethanol solution of sodium acetate (0.49 g, 6 mmol) to finally synthesize IR-26 (1.63 g, yield 30%, green sticky solid). Structural characterization was determined by 1H NMR, 13C NMR, and high resolution mass spectroscopy (HRMS).

Human leukemia cell lines HL-60, NB4, and THP-1 were cultured in RPMI 1640 culture media supplemented with 10% FBS. All cell lines were purchased from the American Type Culture Collection (Manassas, VA, USA) and incubated at 37C with 5% CO2. Lentiviral vector harboring the GFP gene was used to stably labeled HL-60 cells. The expression of GFP in antibiotic-resistant transfected cells was isolated by flow cytometry based on GFP fluorescence signals. HSCs were isolated from human cord blood with CD34+ cells and cultured in serum-free medium with recombinant human stem cell factor (rhSCF), recombinant human thrombopoietin (rhTPO), and FLT3.

To determine the preferential accumulation of IR-26 in leukemia cells, PBMCs from normal peripheral blood and different leukemia cells were incubated with 5 M IR-26 at 37C for 15 min. Cells were placed into a petri dish, and NIR fluorescence intensities were detected and compared by confocal microscopy (Leica) with 633-nm excitation and 780-nm emission. Moreover, GFP-labeled HL-60 cells were mixed with PBMCs and incubated with IR-26 at the same conditions. After washing with PBS, flow cytometry (BD FACSVerse, BD Biosciences) or confocal microscopy was used to determine the distribution of NIR fluorescence in GFP and non-GFP cells.

Animal protocols were in accordance with the Animal Care and Committee Guidelines of the Third Military Medical University. For the subcutaneous xenograft tumor models, male athymic nude mice (4 to 6 weeks old) were used. GFP-labeled HL-60 cells (5 106) were suspended in Dulbeccos minimum essential medium with the same volume of Matrigel (BD Biosciences) and subcutaneously injected into the flank of each mouse. For mouse model of human AML, male C57BL/6 mice (6 to 8 weeks old) were exposed to a sublethal irradiation at a dose of 6 Gy using a cobalt-60 source. GFP-labeled HL-60 cells (5 106) suspended in 300 l of PBS were injected into mice through the tail vein. GFP-labeled malignant cells in peripheral blood were monitored by IVFC for 20 days, and leukemia blasts infiltrated in peripheral blood, bone marrow, spleens, and liver were detected to confirm that leukemia mouse models were established successfully. NOD/SCID mice engrafted with GFP-labeled human AML cells by tail vein injection were used to detect anti-leukemia efficacy of IR-26 in vivo.

Athymic nude mice bearing tumor xenografts were injected intravenously with IR-26 at a dose of 0.3 mg/kg (n = 3). Whole body of mouse optical imaging was taken at day 2 after injection using Kodak In-Vivo Imaging System FX Pro (New Haven, CT) equipped with fluorescent filter sets (excitation/emission, 770/830 nm); all settings were applied as described previously (21). After mice were sacrificed, dissected organs and tumors were obtained for NIR fluorescent imaging at the day of sacrifice.

The NIR IVFC system used in this study was established by ourselves and equipped with two lasers: a 785-nm laser used to excite NIR fluorescent dyes, and a 488-nm laser used to excite GFP. Once a fluorescence cell in the blood passed through the laser slit, the fluorescence of both channels would be excited and detected at the same time. After the GFP-labeled leukemia cells were transplanted in the mice for 5 days, the mice were injected with IR-26 by tail vein. IVFC for tracking fluorescent cells in peripheral blood of mice was performed according to our previous protocols (24). Briefly, after the mouse was anesthetized with 1% sodium pentobarbital solution, it was placed on the platform, and the GFP and NIR fluorescence information in peripheral blood of mouse was recorded and analyzed using IVFC. The first measurements were acquired within 15 min after the first injection of IR-26. Additional measurements were acquired at the same vessel location.

To detect the anti-AML effects of IR-26 in vivo, xenograft tumor models, established by subcutaneous injection of HL-60 cells in the right flank of athymic nude mice (4 to 6 weeks old), were used. Drug treatment was started when tumor sizes reached 5 mm in diameter. The IR-26 treatment group (n = 5) received IR-26 (5.0 mg/kg) by intraperitoneal injection, and the cytarabine treatment group (n = 5) received cytarabine (50 mg/kg), whereas the control group (n = 5) received saline only. The compounds were injected three times a week. Tumor volumes were calculated as length (width)2/2. NOD/SCID mice (8 to 10 weeks old) were intravenously injected with 5 106 GFP-labeled HL-60 cells to establish human AML mouse model. The mice were kept in microisolators and fed with sterile food and acidified water. One week after injection of HL-60 cells, the IR-26 treatment group (n = 12) received IR-26 (5.0 mg/kg) in saline by intraperitoneal injection, and the cytarabine treatment group (n = 12) was intraperitoneally injected with cytarabine (5.0 mg/kg), whereas the control group (n = 12) received saline only. Leukemia cell distribution, pathological histology of vital organs, and mice survival rates were detected.

Cellular OCR was measured using XF96 Extracellular Flux Analyzer (Seahorse Bioscience, Billerica, MA). Briefly, HL-60 cells were seeded in XF96-well plates (20,000 cells per well in 80 l). After 1 hour, cells were incubated overnight at 37C, 5% CO2. The XF96 sensor cartridge was hydrated with 200 l of calibration buffer per well overnight at 37C. Cells were preincubated with or without IR-34 (5 M) for 1 hour before the bioenergetic profile was determined. Then, cells were washed twice with 200 l of prewarmed base medium containing 10 mM sodium pyruvate and 25 mM glucose. The sensor cartridge was loaded with assay media (ports A, B, and C) to measure basal OCR or with oligomycin (2.0 M, port A), carbonyl cyanide 4-(trifluoromethoxy) phenylhydrazone (2.0 M, port B), and rotenone (0.5 M, port C) to measure the bioenergetic profiles of different cells.

Pull-down assay using IR-26labeled AML cells were performed to detect IR-26specific interaction proteins. Briefly, HL-60 cells were incubated with 1.25 M IR-26 for 15 min. After washing with PBS, the cells were lysed to obtain the total protein. Then, the protein lysate was incubated with SDHA and ATP5B antibodies overnight at 4C. A total of 100 l of streptavidin-agarose (Santa Cruz Biotechnology) was added and incubated for 2 hours at room temperature, and the immunoglobulin G antibody was used as control. After the protein complex was centrifuged and washed, it was analyzed by SDSpolyacrylamide gel electrophoresis and imaging using Kodak In-Vivo Imaging System FX Pro to determine whether ATP5B or SDHA proteins were combined with the NIR fluorescence small-molecule IR-26 and then immunoblotted using anti-ATP5B or anti-SDHA antibodies to further verify the interactions.

The HL-60 cells were cultured in RPMI 1640 culture media supplemented with 10% FBS for 2 days. Next, 1 107 cells were seeded in 75 culture dishes and treated with different concentrations of IR-26 (0, 2.5, 5, and 10 M). After 8 hours, cells in different groups were harvested and counted. After centrifugation, cells were kept in liquid nitrogen for 30 s and stored under 80C condition. Then, metabolites were immediately extracted and subjected to targeted metabolomic analysis for central carbon metabolism. Electrospray ionization mass spectrometry (cation) or Agilent 6460 Triple Quad LC/MS (anion) was conducted by Biotree.

Data were presented as means SD from at least three independent experiments. SPSS 13.0 statistical software was used to conduct all statistical analysis. One-way analysis of variance was used to determine significance among groups. A value of P < 0.05 was considered to be statistically significant.

Acknowledgments: Funding: This work was supported by Natural Science Foundation Programs (81130026 and 81773352), Innovation Team Building Program of Chongqing University (CXTDG201602020), and Outstanding Youth Development Program of Third Military Medical University. Author contributions: C.Z., Yang Wang, T.L., and P.L. performed experiments. L.G. collected patient samples. L.M., Z.J., and Z.Y. helped to perform in vitro experiments. D.L., X.L., and Q.J. helped to perform in vivo experiments. X.T. and Yu Wang helped with optical imaging. S.L. contributed to design and synthesis of compounds and preparation of the manuscript. Yang Wang and C.S. contributed to study design, manuscript writing, and project supervision. Competing interests: The authors declare that they have no 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 data related to this paper may be requested from the authors.

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