CellResearch Corporation (CRC) to present promising new stem cell products for the treatment of chronic diabetic foot ulcers at the world’s premier…

- CRC data on cord lining media for the treatment of diabetic foot ulcers has been accepted at the DFCon, with Dr Wong Keng Lin Francis, CRC's latest KOL, presenting his findings to world leaders in the field of DFU. - Similarly, the results of Corlicyte's Phase 1 study on the treatment of chronic diabetic foot has also been accepted with the presentation being given by Dr Cecilia Low-Wang, the trials Principal Investigator. - DFCon is a global specialist multi-disciplinary congress that attracts specialists in the field of the diabetic foot and is considered the most influential event in the industry. It is co-founded by Dr David Armstrong, a pre-eminent expert in diabetic foot. - Dr Armstrong, who also serves on CRC's scientific advisory board, will be giving the opening address for CRC's breakfast symposium on their lead products Sollagen and Corlicyte. - CorLiCyte is an umbilical cord lining stem cell therapy, for patients suffering with diabetic foot ulcers (DFU), Sollagen is a brand targeting diabetic's skin. - Global diabetes patient population is set to grow from 537 million in 2021 to 783 million in 20451- DFU is a global health emergency that will affect close to 20% of the diabetic population in their lifetime

LOS ANGELES, Sept. 26, 2022 /PRNewswire/ -- CRC is delighted to announce attendance at DFCon, the global specialist multidisciplinary congress focused on the diabetic foot held in late September 2022 in Los Angeles, USA. The meeting is a gathering of a wide range of both generalists and specialists who diagnose and manage diabetic feet, to discuss best practice in diagnostics and interventions for both treatment and amputation prevention. It was co-founded and is co-chaired by Dr David Armstrong, a pre-eminent expert in diabetic foot who also serves on CRC's scientific advisory board.

Dr David Armstrong will be introducing CRC's headline symposium on Saturday morning where Dr Paul Kemp, the inventor of Apligraf and scientific advisory board member, and esteemed researchers Dr Brian Freed and Dr Wong Keng Lin Francis will present an overview of CRC's technology and data.

Furthermore, CRC have two scientific posters approved for presentation at DFCon on the data generated in Corlicyte and Sollagen:

The first poster "Results of the phase 1 open-label safety study of umbilical cord lining (Corlicyte) to heal chronic diabetic foot ulcers" details the Phase I study in Corlicyte and is authored by Cecilia Low Wang and the team from the University of Colorado who conducted the study.

The second poster by Dr Wong from Sengkang General Hospital/Duke NUS is titled "Early evaluation of Sollagen, a topical exosomal skin conditioner derived from Umbilical cord lining cell media, in treatment of persistent chronic DFU" and details the impressive early data generated with Sollagen in chronic diabetic foot ulcers.

Both posters are a testament to the immense potential of Corlicyte and Sollagen for the treatment of diabetic foot ulcer, a huge issue for patients and health care systems alike.

CRC's presence at such a specialized and well-regarded scientific and medical forum reflects the exciting data the company is generating. It is a strong indication of the academic and clinical network that the company is building to deliver products that can make a dramatic difference to patients with a large unmet medical need.

About CellResearch Corporation (CRC)

CellResearch Corporation was founded in 2002 as a contract research provider focusing on skin cells. In 2004, the company made the discovery that the umbilical cord lining of mammals was an abundant source of both mesenchymal and epithelial stem cells. Today, the company owns this technology through a family of patents and holds the rights to commercialize this technology in most major markets globally. While the closure of diabetic foot ulcers is the company's first allogeneic therapy to make it to the end of Phase 1 USFDA clinical trials, CellResearchCorp has a broad therapeutic pipeline at the pre-clinical stage. Further therapies include solid tumor therapy, inflammatory diseases, cardiac muscle repair, Parkinson's Disease, Age-related Macular Degeneration and Diabetes.

CellResearch Consumer Health, a wholly owned subsidiary of CellResearch Corp, is the commercialization vehicle for CALECIMProfessional and the newly launching Sollagen. It produces an innovative range of skincare and haircare products using cord lining stem cell media to power its products. It is used in clinics/hospitals and as part of an at-home anti-aging skincare regime. It is distributed globally through over 600 aesthetic physicians and online via their own website. It has a key distribution partnership with Menarini Group across Southeast Asia.

CellResearch Corp partner, Cordlife offers parents the opportunity to bank their child's umbilical cord tissue alongside their cord blood. Cordlife has what is believed to be the largest licensed bank of umbilical cord tissue globally. As cell therapies move into the clinic, Cordlife will have the ability to expand stem cells from a banked umbilical cord for autologous and donor-related uses.

http://www.cellresearchcorp.com

https://calecimprofessional.com

Business Development and Investor Relations:

Xavier Simpson

+65 8815 6139

xaviersimpson@cellresearchcorp.com

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CellResearch Corporation (CRC) to present promising new stem cell products for the treatment of chronic diabetic foot ulcers at the world's premier...

Neurona Therapeutics Presents Clinical Case Study from First Human Trial of Regenerative Cell Therapy, NRTX-1001, in Adults with Drug-Resistant Focal…

Clinical assessments three-months post-treatment report no serious adverse events and reduced seizure frequency to date in first trial participant

Data Safety Monitoring Board clears advancement of trial to continue enrollment

Pioneering cell therapy approach could provide a disease-modifying treatment for drug-resistant focal epilepsy

Data presented at ISSCR-ASGCT Conference: Emerging Therapies at the Intersection of Genetic and Cellular Technologies

SAN FRANCISCO, Sept. 21, 2022 (GLOBE NEWSWIRE) -- Neurona Therapeutics, a clinical-stage biotherapeutics company advancing regenerative cell therapies for the treatment of neurological disorders, today announced the presentation of a clinical case study from the initial dose cohort of the Phase 1/2 first-in-human epilepsy clinical trial of its lead program, NRTX-1001. The data from three months post-cell therapy administration to the first patient in this study show that there were no serious adverse events associated with NRTX-1001 treatment and that the patient has thus far experienced reduced seizure frequency from an average prior history of 30+ seizures per month to four seizures in total during three months of follow-up to date. The data are being presented by Catherine Priest, Ph.D., Neuronas chief development officer at the ISSCR-ASGCT Conference: Emerging Therapies at the Intersection of Genetic and Cellular Technologies being held in Madison, WI, September 21 -23, 2022.

The reduced number of seizures reported by the first person to receive NRTX-1001 is very encouraging, and we remain cautiously optimistic that this reduction in seizure frequency will continue and extend to others entering this cell therapy trial. NRTX-1001 administration has been well tolerated thus far in the clinic, which is in line with the extensive preclinical safety data collected by the Neurona team, said Cory R. Nicholas, Ph.D. Neuronas president and chief executive officer. With recent clearance from the Data Safety Monitoring Board we are excited to continue patient enrollment. We are very grateful to these first participants, and thank the clinical teams for the careful execution of this pioneering study.

In addition to the preclinical data supporting the clinical program, the presentation highlights initial data from the first patient treated in Neuronas clinical trial who received a starting dose of NRTX-1001. The patient is a young adult male with a 9-year history of seizures and was diagnosed with unilateral mesial temporal lobe epilepsy (MTLE). In the six months prior to the administration of NRTX-1001, the patient experienced an average of 32 seizures per month, despite being on several antiepileptic medications. The patient received NRTX-1001, and the treatment was well tolerated; there have been no serious adverse events to date. The patient has reported having four seizures during the first three months since receiving NRTX-1001.

The clinical trial is funded in part by the California Institute for Regenerative Medicine (DISC2-10525; TRAN1-11611; CLIN2-13355).

About Neuronas Clinical Trial of NRTX-1001 for Mesial Temporal Lobe Epilepsy (MTLE) Neuronas multicenter, Phase 1/2 clinical trial is designed to evaluate the safety and efficacy of a single administration of NRTX-1001 for drug-resistant MTLE. The first stage of the trial is an open-label dose-escalation study in up to 10 people with MTLE, with five patients to be treated at a starting dose and five at a higher dose. Patients treated with a single infusion of NRTX-1001 cells will be monitored for safety, tolerability, and effects on their epilepsy disease symptoms. Patient recruitment is underway at epilepsy centers across the United States. For more information, please visit http://www.clinicaltrials.gov (NCT05135091). The first part of the clinical trial is supported by a recently announced $8.0 million grant from the California Institute for Regenerative Medicine (CIRM; CLIN2-13355).

About NRTX-1001 NRTX-1001 is a regenerative neural cell therapy candidate derived from human pluripotent stem cells. The fully-differentiated neural cells, called interneurons, secrete the inhibitory neurotransmitter gamma-aminobutyric acid (GABA). Delivered as a one-time dose, the human interneurons are intended to integrate and innervate on-target, providing long-term GABAergic inhibition to repair hyper-excitable neural networks.

About Mesial Temporal Lobe Epilepsy (MTLE) An estimated three million Americans have epilepsy, and 25 to 35 percent live with ongoing seizures despite treatment with approved drugs, which means that there is a huge unmet medical need in this community. MTLE is the most common type of focal epilepsy in adults and primarily affects the internal structures of the temporal lobe, where seizures often begin in a structure called the hippocampus. For people with seizures that are resistant to anti-seizure drugs, epilepsy surgery, where the damaged temporal lobe is surgically removed or ablated by laser, can be an option. However, the current surgical options are not available or effective for all, are tissue-destructive, and can have significant adverse effects.

About Neurona Neuronas regenerative cell therapy candidates have single-dose curative potential. Neurona is developing off-the-shelf, allogeneic neuronal, glial, and gene-edited cell therapy candidates that are designed to provide long-term repair of dysfunctional neural networks for multiple neurological disorders. For more information about Neurona, visit http://www.neuronatherapeutics.com

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Neurona Therapeutics Presents Clinical Case Study from First Human Trial of Regenerative Cell Therapy, NRTX-1001, in Adults with Drug-Resistant Focal...

Reprogramming pig cells leads way for new regenerative therapies – National Hog Farmer

A new approach is paving the way for improved stem cell therapies and regenerative applications using cells from pigs. Led by Wan-Ju Li, a SCRMC researcher and associate professor in the Department of Orthopedics and Rehabilitation and the Department of Biomedical Engineering, this new study published in Scientific Reports offers a viable strategy to enhance the generation of induced pluripotent stem cellsfrom large animal cells and provides researchers with insight into the underlying mechanism controlling the reprogramming efficiency of cells. In turn, this approach will allow researchers to reprogram cells more efficiently into iPSCs which can be used to study regenerative therapies aimed at treating everything from osteoarthritis to heart disease.

While this approach can be applied to regenerative therapies targeting any organ or tissue, Li and his Musculoskeletal Biology and Regenerative Medicine Laboratory study cartilage, so he developed the model by deriving iPSCs from the fibroblast cells of three different breeds of miniature pigs including Wisconsin miniature swine, Yucatan miniature swineand Gttingen minipigs. Fibroblast cells are easily obtained for cellular reprogramming and Li is interested in using these cells to efficiently develop cartilage cells that can be used to help patients experiencing osteoarthritis. But, while his goal for the study was specific, the model has wide-reaching implications.

"This model we created can be used for many applications," says Li. "In successfully developing iPSCs from three different breeds of minipigs, we learned we can take somatic skin cells from these pigs that we programmed ourselves into iPSCs and then inject them back into the same animal to treat the disease. Or we can take the cell that carried the disease gene and put that into the culture dish and use that as a disease model to study disease formation."

Li explained that iPSCs can be created from nearly any type of somatic cell, such as skin or blood cells, that are reprogrammed back into an embryonic-like pluripotent cells. These pluripotent stem cells are the bodys master cells and are, therefore, able to become nearly any cell in the body. Harnessing the power of such a cell and being able to grow these versatile cells in the lab is invaluable to medicine as these cells can be used for the regeneration or repair of damaged tissue and in drug testing to see how medication will impact heart, liver, or other cells within the body.

Through this research, Li and his lab have provided researchers with insight into the underlying mechanism controlling the reprogramming efficiency of iPSCs, allowing researchers to harness to power of iPSCs and develop them more efficiently. Specifically, he discovered that the expression level of the switch/sucrose nonfermentable component BAF60A, which is essentially a protein that can remodel the way DNA is packaged, helps to determine the efficiency of iPSC generation. He also noted that the BAF60A is regulated by STAT3, a transcription factor protein that plays a role in cell growth and death. Through this, Li discovered that the efficiency of iPSC generation is based on the expression level of these proteins and that the expression levels vary among pig breeds.

"While we successfully developed iPSCs and programmed iPSCs from the three different strains of pig, we noticed that some pigs had a higher reprogramming efficiency,"says Li. "So, the second part of our findings, which is significant in biology, is understanding how these differences occur and why."

Li shared that understanding why different pig breeds have varying levels of reprogramming efficiency will directly translate to understanding differences in the effectiveness of iPSC generation between individual humans. In fact, a previous study by Mackey et al., has shown that a person's ethnicity may impact their cell's reprogramming efficiency. So, understanding what mechanisms control cellular reprogramming will be crucial to developing effective protocols of iPSC generation for individualized therapies.

"With this model, we can study musculoskeletal regeneration particularly cartilage regeneration for osteoarthritis patient,"says Li. "But we think the impact is way beyond the application of orthopedics because from now on, anybody on campus who is interested in using the technology we have developed for a minipig model, can reprogram their cells into iPSCs and then these cells and the animal can be used to investigate heart disease, kidney disease, neuronal diseaseor any type of a disease."

Translating this research to improve human health, is deeply important to Li. He has spent much of his career studying novel approaches to regenerate cartilage and bone for orthopedic applications and developing a translational model like this means that science is one step closer to healing more patients using stem cells.

"I feel really touched by the stories people share. You cannot imagine how many emails come in asking me if they can become the first human patient in our future clinical trial,"Li says. "People are in desperate need for something, especially when those people feel the current surgical procedure or intervention is not suitable for them. I have to keep saying, 'wait for another two, three years, maybe we'll be ready for a clinical trial,'but for me, it's time to move on and really do our larger animal studies to fulfill our promise. At least that way, I can fill the gap between the lab and clinical trials as the larger animals must be studied before you go into a clinical trial."

Li's development of a reliable and translational model for the generation of iPSCs in a large animal is critical as it has been a challenge to generate pig iPSCs with efficiency. The reprogramming efficiency of pig cells is relatively low compared to that of human or mouse cells, but large animal studies remain a crucial step in bringing treatments to clinical trials.

Interest in moving these treatments forward has grown and while this study was funded in part by NIH, Li also received support from the Plunkett Family Foundation in Milwaukee through their donation to the UW Stem Cell and Regenerative Medicine Center. After hearing of Li's research, Gwen Plunkett and her daughter Karen visited Li and his lab in 2019 to learn more and were inspired to support research into stem cells for cartilage regeneration.

"Innovation in medicine sparks critical change, for the world and the survival of our species and the Plunkett Family mission is to be a catalyst in stem cell and regenerative medicine research,"says Karen Plunkett. "We supported Jamie Thomson's lab in the early days when federal funding for human stem cell research was restricted. More recently, we continued our commitment to this research by supporting Dr. Wan-Ju Li's stem-cell based approaches for regenerating skeletal tissues, cartilageand bone for orthopedic applications. Additionally, it is personally gratifying to be able to support the SCRMC while my son completes his senior year studying neurobiology at UWMadison.We are happy to be part of the University of Wisconsin family."

Li shared that the donation was profoundly impactful and allowed him to further his goal of using stem cells to help patients struggling with osteoarthritis as well as other joint diseases.

"I want to make sure that our findings in stem cell research can be used to help people,"says Li. "I just feel this internal drive to study this area and I feel good knowing this model carries significant weight in terms of its potential for translational stem cell research and the development of therapeutic treatments."

This research was supported by grants from the National Institutes of Health (R01 AR064803) and the Plunkett Family Foundation. The UW Department of Pathology and Laboratory Medicine and UWCCC (P30 CA014520) and the Small Animal Imaging andRadiotherapy Facility and Flow Cytometry Laboratory, supported by UWCCC (P30 CA014520) also provided facilities and services.

Source: University of Wisconsin-Madison, whichis solely responsible for the information provided, and wholly owns the information. Informa Business Media and all its subsidiaries are not responsiblefor any of the contentcontained in this information asset.

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Reprogramming pig cells leads way for new regenerative therapies - National Hog Farmer

Treg Cell-based Therapies Pipeline Landscape Analysis of 22+ Companies by DelveInsight – GlobeNewswire

New York, USA, Sept. 26, 2022 (GLOBE NEWSWIRE) -- Treg Cell-based Therapies Pipeline Landscape Analysis of 22+ Companies by DelveInsight

Given the various benefits offered, including high target specificity, customization potential and ability to generate immunological memory, regulatory T-cell (Treg) therapies have garnered significant attention among key industry stakeholders for the treatment of various oncological and non-oncological disease indications.

DelveInsights 'Treg Cell-based Therapies Pipeline Insight 2022' report provides comprehensive global coverage of available, marketed, and pipeline Treg cell-based therapies in various stages of clinical development, major pharmaceutical companies are working to advance the pipeline space and future growth potential of the Treg cell-based therapies pipeline domain.

Key Takeaways from the Treg Cell-based Therapies Pipeline Report

Request a sample and discover the recent advances in Treg cell-based therapies @Treg Cell-based Therapies Pipeline Outlook

The Treg cell-based therapies pipeline report provides detailed profiles of pipeline assets, a comparative analysis of clinical and non-clinical stage Treg cell-based therapies, inactive and dormant assets, a comprehensive assessment of driving and restraining factors, and an assessment of opportunities and risks in the Treg cell-based therapies pipeline landscape.

Treg Cell-based Therapies Overview

Treg cells, which account for 5-7% of CD4+ T cells, develop both directly in the thymus (tTreg cells) and peripherally (pTreg cells). pTreg cells develop from CD4+ conventional T cells, particularly in the gut, in the presence of high levels of transforming growth factor (TGF) and retinoic acid in the environment or in response to metabolites produced by microbiota.

Clinical trials for cellular therapies based on regulatory T (Treg) cells are currently underway for the treatment of autoimmune diseases, transplant rejection, and graft-versus-host disease. Early Treg cell therapy experiences in patients with graft-versus-host disease, type 1 diabetes, and organ transplantation have demonstrated that it is feasible, safe, and potentially efficacious in some settings.

Although there is a clear immunologic rationale for Treg cell therapy, there are numerous challenges at this early stage of implementation and testing. The magnitude of Treg cell ex vivo expansion can vary greatly depending on the patient population and underlying diseases.

Find out more about Treg cell-based therapies @Treg Cell-based Therapies in Development

A snapshot of the Treg Cell-based Therapies Pipeline Drugs mentioned in the report:

Learn more about the emerging Treg cell-based therapies @ Treg Cell-based Therapies Clinical Trials

Treg Cell-based Therapies Therapeutics Assessment

TheTreg cell-based therapies pipelinereport proffers an integral view of the emerging Treg cell-based therapies segmented by stage, product type, molecule type, mechanism of action, and route of administration.

Scope of the Treg Cell-based Therapies Pipeline Report

Dive deep into rich insights for Treg cell-based therapies assessment, visit @Treg Cell-based Therapies Therapeutics Assessment

Table of Contents

For further information on the Treg cell-based therapies pipeline therapeutics, reach out @Treg Cell-based Therapies Pipeline Landscape

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Treg Cell-based Therapies Pipeline Landscape Analysis of 22+ Companies by DelveInsight - GlobeNewswire

Congress Introduced with Access to Future Cures Act Aimed at Enabling Precision Medicine for Future Cellular & Gene Therapies – GlobeNewswire

Norwalk, CT, Sept. 26, 2022 (GLOBE NEWSWIRE) -- H.R.8912, the Access to Future Cures Act, was introduced to Congress on September 20th which aims to expand Health Savings Account (HSA), Health Reimbursement Arrangement (HRA), and Flexible Spending Account (FSA) eligibility to include storage of blood or biomaterial derived from blood to enable future cell and gene therapy treatments.

Currently, there are 25 FDA-approved cell and gene therapy products and thousands of clinical trials in development. In fact, the FDA has forecasted 10 to 20 new approvals annually by 2025. As approvals continue to climb, so do the promising results of cellular therapy. For instance, a type 1 diabetes patient received successful treatment with a stem cell-derived pancreatic islet cell replacement therapy called VX-880. According to the Harvard Stem Cell Institute, the patientwho was injection-dependent since their diagnosis 40 years agohad significant restoration of their insulin-producing islet cells after receiving VX-880. This suggests that VX-880 and future cellular therapies may negate the need for people with diabetes to continue using self-injecting insulin.

While many current therapies rely on donor cells, the use of one's own biomaterial allows for better patient outcomes in precision medicine and since cellular health declines over time your healthiest cells are the ones you have today.

I commend this Congress for considering the Access to Future Cures Act which will give millions of Americans with flexible spending and healthcare savings accounts access to high-value preventive healthcare services, said Chris Garcia, Chairman and CEO of GoodCell. With promising cell therapies in development to treat major chronic and debilitating diseases, FSA and HSA eligibility for personal cell storage allows average Americans to store their healthy cells for access to future personalized therapies.

To learn more about GoodCell and how to become a member, visit http://www.GoodCell.com.

About GoodCell:

GoodCell, a life sciences company, delivers proactive, preventive healthcare services that allow members to participate in precision medicine by storing their own biomaterial for potential future personalized cellular therapy. As the pace of cell and gene therapy breakthroughs and FDA approvals continues to accelerate, so do the advantages of Personal Biobanking. Storing healthy cells now gives GoodCell members greater control of their health in the future and may extend quality of life. Learn more at http://www.GoodCell.com.

GoodCell is partnered with Quest Diagnostics for a convenient member experience. Scheduling a blood draw is fast and easy at one of the 3,000+ Quest Labs nationwide. Samples are then sent to GoodCell labs for bioprocessing where the most valuable components of the blood are extracted and safely and securely stored in GoodCells state-of-the-art biorepository.

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Congress Introduced with Access to Future Cures Act Aimed at Enabling Precision Medicine for Future Cellular & Gene Therapies - GlobeNewswire

Strategies to improve the effect of mesenchymal stem cell therapy on inflammatory bowel disease – Newswise

Inflammatory bowel disease (IBD) includes Crohns disease and ulcerative colitis and is an idiopathic, chronic inflammatory disease of the colonic mucosa. The occurrence of IBD, causes irreversible damage to the colon and increases the risk of carcinoma. The routine clinical treatment of IBD includes drug treatment, endoscopic treatment and surgery. The vast majority of patients are treated with drugs and biological agents, but the complete cure of IBD is difficult. Mesenchymal stem cells (MSCs) have become a new type of cell therapy for the treatment of IBD due to their immunomodulatory and nutritional functions, which have been confirmed in many clinical trials. This review discusses some potential mechanisms of MSCs in the treatment of IBD, summarizes the experimental results, and provides new insights to enhance the therapeutic effects of MSCs in future applications.

Core Tip: Mesenchymal stem cell (MSC) transplantation is a novel treatment method for inflammatory bowel disease (IBD) that has exhibits certain achievements in clinical trials. Here, we reviewed the developed strategies for enhancing the therapeutic effect of MSCs, and among these, pretreatment with MSCs is the most common method. The pretreatments include bioactive substances, hypoxia and modification of culture methods and are able to enhance the migration ability of MSCs to repair the damaged intestinal mucosa or upregulate the expression of cytokines. These methods provide new ideas for the future clinical application of MSCs in the treatment of IBD.

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Strategies to improve the effect of mesenchymal stem cell therapy on inflammatory bowel disease - Newswise

Development and validation of a predictive model to guide the use of plerixafor in pediatric population | Bone Marrow Transplantation – Nature.com

The main patient characteristics are described in Table2. Type of tumor and mobilization were similar between the groups.

Based on AIC minimization, the combined variability structure was selected. The equation of the estimated base model was AP-CD34+=1.63+1.02 (PB-CD34+)+e where e had a zero-mean normal distribution N (0, s2 (k+prediction)2).

The parameter values for intercept, PB-CD34+, k, and were 1.63 (SE=0.72), 0.12 (SE=0.01), 1.76 and 0.49, respectively.

The base model showed a satisfactory goodness-of-fit plot. In the predicted vs the observed scatterplot, the dots were well scattered around the identity line indicating unbiased model predictions. Additionally, the plot of residual values confirmed non-homogeneous variance with greater residual variability for larger predicted values of the AP-CD34+ cell counts. In terms of predictive accuracy, the base model was able to properly predict the percentage of patients achieving both 2 106 and 5 106 AP-CD34+ cells/kg (Fig.2).

AP-CD34+ cluster of differentiation 34+ cells on the first day of apheresis, CI confidence interval.

The base model can be used to characterize the necessary counts of PB-CD34+ to achieve thresholds of 2 106 and 5 106 AP-CD34+ cells/kg (Fig.3).

AP-CD34+ cluster of differentiation 34+ cells on the first day of apheresis, PB-CD34+ peripheral blood-cluster of differentiation 34.

According to the base model, an estimated PB-CD34+ counts of 57.01 (90% CI: 21.76130.76) and 125.24 (90% CI: 72.09330.71) 106/L were necessary to reach thresholds of 2 106 and 5 106 AP-CD34+ cells/kg, respectively, with a probability of 0.90.

Based on AIC minimization, the best model includes the tumor type (neuroblastoma and other) as covariate. The equation of the estimated final model was as follows:

$${{{{{{{mathrm{Neuroblastoma}}}}}}}}:{{{{{{{mathrm{AP}}}}}}}} {mbox{-}} {{{{{{{mathrm{CD}}}}}}}}34^ + = 3.01 + 0.13 times left( {{{{{{{{mathrm{PB}}}}}}}} {mbox{-}} {{{{{{{mathrm{CD}}}}}}}}34^ + } right) + e$$

$${{{{{{{mathrm{Other}}}}}}}};{{{{{{{mathrm{tumor}}}}}}}};{{{{{{{mathrm{types}}}}}}}}:{{{{{{{mathrm{AP}}}}}}}} {mbox{-}} {{{{{{{mathrm{CD}}}}}}}}34^ + = 0.01 + 0.13 times left( {{{{{{{{mathrm{PB}}}}}}}} {mbox{-}} {{{{{{{mathrm{CD}}}}}}}}34^ + } right) + e$$

where e had a zero-mean normal distribution N (0, s2 (k+prediction)2).

The parameter values for intercept-neuroblastoma, intercept-other, PB-CD34+, and were 3.01 (SE=1.10), 0.01 (SE=0.006), 0.13 (SE=0.01), (simeq) 0.00 and 0.54, respectively.

According to the model, the predicted count of AP-CD34+ cells was slightly larger for neuroblastoma tumor types than for the other tumor types. It should be noted that the final model was selected considering the type of tumor as an additional covariate (in addition to PB-CD34+) based on statistical information criterion (AIC), and that the tumor type was correlated with the age of the patients - the patients with Neuroblastoma tumor type, with mean age of 3.7 years (standard deviation, SD=2.1 years), being younger than the others with mean age of 8.9 years (SD=4.8 years). However, the choice of considering tumor type in the final model instead of age was driven by the fact that the fit of the data was improved when tumor type was considered as predictor, as compared to age, which reflected in lower value of the statistical information criterion with tumor type (AIC=288.6) than with age (AIC=310.1).

The final model also showed a good predictive property in terms of goodness-of-fit plot and prediction of the percentages of patients achieving both 2 106 and 5 106 AP-CD34+ cells/kg (Fig.4). The model predicts that a smaller PB-CD34+ cell count was needed to reach 2 106 and 5 106 AP-CD34+ cells/kg with a probability of 0.90 in patients with neuroblastoma tumor type than in those with other tumor types (Fig.5). According to the final model, in patients with neuroblastoma tumor type, the estimated PB-CD34+ counts necessary to reach apheresis thresholds of 2 106 and 5 106 AP-CD34+ cells/kg with a probability of 0.90 were 27.32 (90% CI: 0.1650.51) and 103.20 (90% CI: 56.15165.18) 106/L, respectively. The estimated PB-CD34+ counts necessary to reach thresholds of 2 106 and 5 106 AP-CD34+ cells/kg with a probability of 0.90 in patients with other tumor type were 50.51 (90% CI: 29.3079.12) and 126.39 (90% CI: 77.25198.28) 106/L, respectively.

AP-CD34+ cluster of differentiation 34+ cells on the first day of apheresis, CI confidence interval.

AP-CD34+ cluster of differentiation 34+ cells on the first day of apheresis, PB-CD34+, peripheral blood-cluster of differentiation 34+.

The uncertainty related to these PB-CD34+ estimated values with the final model was slightly less in comparison to the base model probably due to a reduced residual variability.

The physiological process of stem cell mobilization via CXCR4 is comparably the same in subjects of all ages, and when adult data on CXCR4 is extrapolated into children it should closely mirror that seen in children [19]. We complemented our analyses with data from the adult NHL and MM patients who participated in the two plerixafor studies [15, 16], focusing on the first day of apheresis similar to the MOZAIC study. The details of the analyses can be found in theSupplementary section.

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Development and validation of a predictive model to guide the use of plerixafor in pediatric population | Bone Marrow Transplantation - Nature.com

CellOrigin Biotech Announces Global Strategic Collaboration with Qilu Pharma to Develop "Off-the-Shelf" CAR-iMAC Cell Therapy – BioSpace

HANGZHOU, China, Sept. 26, 2022 /PRNewswire/ -- CellOrigin Biotech (Hangzhou) Co., Ltd. announced it has made a global strategic collaboration agreement with Qilu Pharma to develop, manufacture and commercialize proprietary "off-the-shelf" induced pluripotent stem cell- (iPSC) derived Chimeric Antigen Receptor Macrophages (CAR-iMAC) for cancer immunotherapy.

The collaboration will take advantages of technologies and expertise from both parties, as well as integrate capabilities of R&D, manufacturing and marketing to develop CAR-iMAC clinical products aiming for solid tumors.

"Innovation and offering the best products that benefit patients are the core values that CellOrigin Biotech and Qilu Pharma both appreciate," said Dr. Jin Zhang, the Co-Founder of CellOrigin Biotech and a Principal Investigator of Zhejiang University, one of the top universities in China. "This is what brings us together."

"We are very excited to collaborate with Qilu Pharma because of its prestige in the field of Chinese pharmaceutical industry, as well as its tremendous track records on drug development," said Dr. Jiansong Tong, the Chief Executive Officer at CellOrigin Biotech. "Meanwhile, we will continue to seek other potential collaborators to jointly develop our innovative anti-tumor CAR-iMac cell products."

"CellOrigin Biotech is a startup company established by a group of outstanding scientists who have tremendous experiences both in R&D research and cGMP manufacture. It focused on developing innovative technologies in cell therapy and building valuable pipeline of products. It is an ideal strategic partner for novel cell therapy, and it is our pleasure to collaborate with such a great biotech company," said Qilu Pharma.

About CellOrigin Biotech

CellOrigin Biotech (Hangzhou) Co., Ltd. is dedicated to the development of genetically engineered pluripotent stem cell- (iPSC) derived immune cell therapies (such as macrophages, NK cells), with its own proprietary intellectual property. The founders are experienced leaders from Zhejiang University, Harvard University and top pharmaceutical and biotech companies around the world. They apply cutting-edge technologies in editing and differentiating iPSCs to immune cells in order to deliver novel allogeneic off-the-shelf cell therapies for the treatment of cancer patients around the world.

About Qilu Pharma

Qilu Pharma is a leading vertically integrated pharmaceutical companies in China focused on discovering, developing, manufacturing and commercializing innovative medicines. With a diverse pipeline of noval therapeutics, 10 manufacturing sites and more than 36,000 employees worldwide, Qilu is dedicated to transforming scientific innovation by internal R&D across 5 R&D platforms based in the US (Seattle WA, Boston MA, San Francisco CA) and China (Shanghai, Jinan), and external partnership globally into healthcare solutions to address unmet medical needs. To date, Qilu has launched 200+ products with 30+ products "First to launch" in China and 3 products "D181 launch" in US with approximately US$5.2 billion sales revenue in 2021. For more information, please visit http:en.qilu-pharma.com.

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CellOrigin Biotech Announces Global Strategic Collaboration with Qilu Pharma to Develop "Off-the-Shelf" CAR-iMAC Cell Therapy - BioSpace

University of Washington joins industry-academia alliance to accelerate research in neuroscience – EurekAlert

image:Microscopy image showing the cytoskeleton within neurons, which are differentiating from induced pluripotent stem cells. view more

Credit: UC San Francisco

The University of Washington has joined the Alliance for Therapies in Neuroscience (ATN), a long-term research partnership between academia and industry geared to transform the fight against brain diseases and disorders of the central nervous system.

Launched in 2021 by the University of California, San Francisco, UC Berkeley, Genentech a member of the Roche group and Roche Holding AG, the ATN seeks to accelerate the development of new therapies for a broad range of brain and central nervous system conditions, such as Alzheimers disease, Lou Gehrigs disease, Huntingtons disease, Parkinsons disease, autism, depression and psychiatric disorders. As part of the ATN, Genentech and Roche committed up to $53 million over 10 years for research at the ATNs participating academic institutions, a collaboration that is unique for both its duration and the breadth of its ambitions.

The Alliance for Therapies in Neuroscience is a new and transformative template for research and academia to partner, and it is an ideal collaboration for the University of Washington, said Tom Daniel, the Emeritus Joan and Richard Komen Endowed Chair and professor of biology at the UW and incoming CEO of the Washington Research Foundation, who led efforts to join the ATN. Scientists at the UW will be integrated with academic and industry partners in a way that has simply never been done before. And the UW will bring its cross-disciplinary strengths and expertise in neuroscience which span medicine, engineering and basic and clinical research to address the urgent need for new therapies, remedies and treatments in neurological diseases and disorders.

The new alliance builds on an existing academic partnership. In 2019, the UW, UCSF and UC Berkeley formed the Weill Neurohub, a $106-million, multidisciplinary endeavor supported by the Weill Family Foundation to speed discovery and innovation across neurological and psychiatric disorders, including basic research, technology development and patient care. With the UWs accession to the ATN, scientists at all three Weill Neurohub institutions can now access this novel pipeline to channel academic discoveries toward new therapies and treatments.

Pairing academic researchers with industry partners early in the research process will accelerate the transformation of academic research into clinical applications, said Dr. Stephen Hauser, the Robert A. Fishman Distinguished Professor of Neurology at UCSF and director of the UCSF Weill Institute for Neurosciences. And this long-term, 10-year commitment from Genentech and Roche means that researchers at UCSF, UC Berkeley and now the UW will benefit from years-long, close collaborations with industry. It is a type of partnership that hasnt been seen before in academic or industry research.

Membership of the UW in ATN fully leverages the vision that we and the Weills have for the Weill Neurohub, said Ehud Isacoff, the Evan Rausch Chair in Neuroscience at UC Berkeley and director of the Berkeley Brain Initiative. This collaboration with Roche and Genentech world leaders in pharma and biotech opens powerful new directions for Weill Neurohub researchers, with crucial resources and proven track records of bringing new treatments to patients and families.

Teams of scientists at ATN institutions will drive efforts to profile the progression of disease, identify new targets for therapies and model their effectiveness. Existing organizational infrastructure within the Weill Neurohub will serve to coordinate the expanded ATN efforts. In addition to Daniel, the other UW leader within the Weill Neurohub and the ATN is Dr. Jrgen Untzer, professor and chair of the Department of Psychiatry & Behavioral Sciences.

ATN endeavors are intended to meet current demands in neurological disease research and treatment, as well as lay the groundwork for future innovations in understanding and treating nervous system disorders.

The ATN is focusing on pressing needs in neurological disorders across the board: not just therapies to treat conditions like Alzheimers or Parkinsons, but also methods to diagnose them at early stages, as well as understand them at the cellular and molecular level, said Jon-Eric VanLeeuwen, director of strategic initiatives at the UCSF Weill Institute for Neurosciences.

The UW brings a variety of strengths to the ATN, according to Daniel. Neuroscience expertise at the UW spans clinical trials, cell and molecular studies, computational modeling and even research into artificial intelligence. Neuroscientists are based across the UWs STEM schools and colleges, including the School of Medicine, the College of Arts & Sciences and the College of Engineering. UW researchers have a strong track record of innovative cross-institutional collaborations in neuroscience with scientists across the region, including at the Fred Hutchinson Cancer Center and the Allen Institute, which they can also draw on for ATN research.

Through the ATN, all partners will bring their best and brightest to bear on these boiling hot, challenging problems in neuroscience, said Daniel.

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For more information, contact Daniel at danielt@uw.edu and VanLeeuwen at Jon-Eric.VanLeeuwen@ucsf.edu.

Disclaimer: AAAS and EurekAlert! are not responsible for the accuracy of news releases posted to EurekAlert! by contributing institutions or for the use of any information through the EurekAlert system.

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Citius Pharmaceuticals Announces a Clinical Collaboration with the University of Pittsburgh to Evaluate T-reg Cell Depletion with I/ONTAK (E7777) in…

I/ONTAK plus PD-1 checkpoint inhibitor pembrolizumab to be evaluated in solid tumor patients

University of Pittsburgh dose-ranging study expected to begin in the fourth quarter of 2022

Collaboration marks second investigator-initiated study of I/ONTAK as combination immunotherapy

CRANFORD, N.J., Sept. 22, 2022 /PRNewswire/ -- Citius Pharmaceuticals, Inc. ("Citius" or the "Company") (Nasdaq: CTXR), a late-stage biopharmaceutical company developing and commercializing first-in-class critical care products,today announced a collaboration with Dr. Haider Mahdi at the University of Pittsburgh in an investigator-initiated trial to evaluate I/ONTAK ("denileukin diftitox" or "E7777") in combination with pembrolizumab in the treatment of recurrent or metastatic solid tumors.

"We are honored to support Dr. Mahdi and his team at the University of Pittsburgh in this Phase 1 investigator-initiated study to evaluate I/ONTAK as a combination therapy in the treatment of solid tumors. This study will expand the body of knowledge about I/ONTAK's unique mechanism-of-action targeting the CD25 component of the IL-2 receptor which is present on both malignant T-cells (T-cell leukemias and lymphomas) and immunosuppressive regulatory T-cells (T-regs)," stated Dr. Myron Czuczman, Chief Medical Officer of Citius. "Preclinical research in a syngeneic solid tumor mouse model shows that E7777 (denileukin diftitox) enhances anti-tumor activity and significantly extends survival benefit of anti-PD-1 therapy. This data provides a positive signal of denileukin diftitox's potential in the immuno-oncology space. There remains a significant ongoing need for innovative, effective, and well-tolerated treatments for cancer patients with solid tumors, and we are excited that I/ONTAK may provide meaningful antitumor activity in combination with the PD-1 inhibitor pembrolizumab (KEYTRUDA)," added Dr. Czuczman.

"Encouraging clinical data emerging in the field of tumor immunotherapy have demonstrated that therapies focused on enhancing T-cell responses against cancer result in a significant survival benefit in patients with advanced malignancies. Overexpression of PD-L1 on tumor cells has been reported to impede anti-tumor immunity, resulting in immune evasion. The interruption of the PD-1:PD-L1 pathway combined with diminishing the suppressive effect by T-regs may represent an attractive strategy for restoring tumor-specific T-cell immunity. This first in human I/ONTAK plus anti-PD-1 combination immunotherapy study is a significant step towards advancing a T-cell-based therapeutic approach to treating solid tumors," stated Dr. Haider Mahdi, University of Pittsburgh, Assistant Professor, Department of Obstetrics, Gynecology & Reproductive Sciences. Education & Training.

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Additionally, Citius is collaborating with an investigator-initiated study at the University of Minnesota (UMN). This Phase 1 dose-finding study to evaluate I/ONTAK prior to tisagenleucel (KYMRIAH) CAR-T therapy in patients with diffuse large B-cell lymphoma (DLBCL) enrolled its first patient in May 2021.

About the University of PittsburghStudy

The investigator-initiated trial at UPMC is an open label, Phase I/Ib study to evaluate T-reg cell depletion with I/ONTAK (E7777) in combination with pembrolizumab in recurrent or metastatic solid tumors. The study consists of two parts. Part I is a dose escalation study of four cohorts (3,6,9,12 mcg of I/ONTAK) and is expected to enroll 18-30 patients. Part II is a dose expansion study of approximately 40 patients to evaluate the safety and tolerability of the recommended combination dose of I/ONTAK and pembrolizumab. The study will also investigate the alteration of the immune microenvironment within tumors and peripheral blood. Secondary endpoints include the objective response (complete response plus partial response), progression-free survival, and overall survival.

About I/ONTAK

I/ONTAK is a recombinant fusion protein that combines the interleukin-2 (IL-2) receptor binding domain with diphtheria toxin fragments. The agent specifically binds to IL-2 receptors on the cell surface, causing diphtheria toxin fragments that have entered cells to inhibit protein synthesis. I/ONTAK, a purified version of denileukin diftitox, is a reformulation of previously FDA-approved oncology treatment ONTAK. ONTAK was marketed in the U.S. from 1999 to 2014, when it was voluntarily withdrawn from the market. Manufacturing improvements resulted in a new formulation, which maintains the same amino acid sequence but features improved purity and bioactivity. The new formulation received regulatory approval in Japan in 2021 for the treatment of CTCL and PTCL. In 2011 and 2013, the FDA granted orphan drug designation (ODD) to I/ONTAK for the treatment of PTCL and CTCL, respectively.

About Citius Pharmaceuticals, Inc.

Citius is a late-stage biopharmaceutical company dedicated to the development and commercialization of first-in-class critical care products, with a focus on oncology, anti-infectives in adjunct cancer care, unique prescription products, and stem cell therapies. The Company's diversified pipeline includes two late-stage product candidates, Mino-Lok, an antibiotic lock solution for the treatment of patients with catheter-related bloodstream infections (CRBSIs), which is currently enrolling patients in a Phase 3 Pivotal superiority trial, and I/ONTAK (E7777), a novel IL-2R immunotherapy for an initial indication in cutaneous T-cell lymphoma (CTCL), for which a BLA submission is being prepared for the second half of 2022. Mino-Lokwas granted Fast Track designation by the U.S. Food and Drug Administration (FDA). I/ONTAK has received orphan drug designation by the FDA for the treatment of CTCL and peripheral T-cell lymphoma (PTCL). In the first half of 2022, Citius initiated a Phase 2b trial for Halo-Lido, a topical formulation for the relief of hemorrhoids. The Company anticipates completing enrollment in the Halo-Lido trial by the end of 2022. For more information, please visit http://www.citiuspharma.com.

Safe Harbor

This press release may contain "forward-looking statements" within the meaning of Section 27A of the Securities Act of 1933 and Section 21E of the Securities Exchange Act of 1934. Such statements are made based on our expectations and beliefs concerning future events impacting Citius. You can identify these statements by the fact that they use words such as "believe," "anticipate," "estimate," "expect," "plan," "should," and "may" and other words and terms of similar meaning or use of future dates. Forward-looking statements are based on management's current expectations and are subject to risks and uncertainties that could negatively affect our business, operating results, financial condition and stock price. Factors that could cause actual results to differ materially from those currently anticipated are: risks relating to the results of research and development activities, including those from existing and new pipeline assets; uncertainties relating to preclinical and clinical testing; our ability to successfully undertake and complete clinical trials and the results from those trials for our product candidates; our ability to commercialize our products if approved by the FDA; the estimated markets for our product candidates and the acceptance thereof by any market; the ability of our product candidates to impact the quality of life of our target patient populations; our need for substantial additional funds; the early stage of products under development; our ability to attract, integrate, and retain key personnel; our dependence on third-party suppliers; market and other conditions; risks related to our growth strategy; patent and intellectual property matters; our ability to obtain, perform under and maintain financing and strategic agreements and relationships; our ability to identify, acquire, close and integrate product candidates and companies successfully and on a timely basis; our ability to procure cGMP commercial-scale supply; government regulation; competition; as well as other risks described in our SEC filings. These risks have been and may be further impacted by Covid-19. Accordingly, these forward-looking statements do not constitute guarantees of future performance, and you are cautioned not to place undue reliance on these forward-looking statements. Risks regarding our business are described in detail in our Securities and Exchange Commission ("SEC") filings which are available on the SEC's website at http://www.sec.gov, including in our Annual Report on Form 10-K for the year ended September 30, 2021, filed with the SEC on December 15, 2021 and updated by our subsequent filings with the SEC. These forward-looking statements speak only as of the date hereof, and we expressly disclaim any obligation or undertaking to release publicly any updates or revisions to any forward-looking statements contained herein to reflect any change in our expectations or any changes in events, conditions or circumstances on which any such statement is based, except as required by law.

Investor Contact:

Ilanit Allen ir@citiuspharma.com 908-967-6677 x113

Media Contact:

STiR-communications Greg Salsburg Greg@STiR-communications.com

Citius Pharmaceuticals, a late-stage biopharmaceutical company (PRNewsfoto/Citius Pharmaceuticals, Inc.)

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Citius Pharmaceuticals Announces a Clinical Collaboration with the University of Pittsburgh to Evaluate T-reg Cell Depletion with I/ONTAK (E7777) in...