Inspiring new documentary about stem cell research

Poster for the documentary “Ending Disease”

2020 has been, to say the very least, a difficult and challenging year for all of us. But while the focus of the world has, understandably, been on the coronavirus there was also some really promising advances in stem cell research. Those advances are captured in a great new documentary called Ending Disease.

The documentary is by Emmy award-winning filmmaker Joe Gantz. In it he follows ten people who are facing life-threatening or life-changing diseases and injuries and who turn to pioneering stem cell therapies for help.

It’s an inspiring documentary, one that reminds you of the real need for new treatments and the tremendous hope and promise of stem cell therapies. Here’s a look at a trailer for Ending Disease.

You can see an exclusive screening of Ending Disease on Friday, January 8th, 2021 at 5:00pm PST.

After the livestream, there will be a live Q&A session where former members of the successful Proposition 14 campaign team – which refunded CIRM with an additional $5.5 billion – will be joined by CIRM’s President and CEO Dr. Maria Millan, talking about what lies ahead for CIRM and the future of stem cell research.

To purchase a ticket, click here. It only costs $12 and 50% of the ticket sales proceeds will go to Americans for Cures to help them continue to advocate for the advancement of stem cell research, and more importantly, for the patients and families to whom stem cell research provides so much hope.

If you need any extra persuading that it’s something you should definitely put on our calendar, here’s a letter from the film maker Joe Gantz.

I am the director of the documentary Ending Disease: The Stem Cell, Anti-Cancer T-Cell, & Antibody Revolution In Medicine, a film that will help inform people about the progress that’s been made in this field and how people with their lives on the line are now able to benefit from these new regenerative therapies. 

I was granted unprecedented access to ten of the first generation of clinical trials using stem cell and regenerative medicine to treat and cure many of the most devastating diseases and conditions including: brain cancer, breast cancer, leukemia and lymphoma, HIV, repairing a broken spinal cord, retinitis pigmentosa and SCID. The results are truly inspiring.

This is personal for me.  After spending four years making this documentary, I was diagnosed with bladder cancer. Upon diagnosis, I immediately felt the same desperation as millions of families who are in search of a medical breakthrough. I understood, on a personal level, what the patients we followed in the film all knew: when you are diagnosed with a disease, there is a narrow window of time in which you can effectively seek a life-saving treatment or cure. If treatment becomes available outside of that window, then it is too late. However, Ending Disease shows that with continued support for regenerative medicine, we can create a near future in which one-time cures and highly mitigating therapies are available to patients for a whole host of diseases.

Best regards,

Joe

CIRM-Funded Project Targeting Sickle Cell Disease Gets Green Light for Clinical Trial

Dr. Matthew Porteus

The US Food and Drug Administration (FDA) has granted Investigational New Drug (IND) permission enabling Graphite Bio to test the investigational, potentially revolutionary gene editing therapy GPH101 developed under the supervision of Matthew Porteus, MD, PhD, in a clinical trial for people with sickle cell disease (SCD).

The California Institute for Regenerative Medicine (CIRM) has been supporting this project with a $5.2 million grant, enabling Dr. Porteus and his team at the Institute of Stem Cell Biology and Regenerative Medicine at Stanford University to conduct the preclinical manufacturing and safety studies required by the FDA.

“We congratulate the Graphite Bio team for obtaining the IND, a critical step in bringing the GPH101 gene therapy forward for Sickle Cell Disease,” says Dr. Maria T. Millan, CIRM’s President & CEO. “CIRM is committed to the national Cure Sickle Cell initiative and are delighted that this technology, the product of CIRM funded research conducted by Dr. Porteus at Stanford, is progressing to the next stage of development”

Sickle cell disease is caused by a genetic mutation that turns normally smooth, round red blood cells into rigid, sickle shaped cells. Those cells clump together, clogging up blood vessels, causing intense pain, damaging organs and increasing the risk of strokes and premature death. There are treatments that help control the damage, but the only cure is a bone marrow stem cell transplant, which can only happen if the patient has a stem cell donor (usually a close relative) who has matching bone marrow.  

The investigational therapy GPH101 harnesses the power of CRISPR and natural DNA repair mechanisms to cut out the single mutation in the sickle globin gene and paste in the correct “code.” Correction of this mutation would reverse the defect and result in healthy non-sickling red blood cells.  

CEDAR, a Phase 1/2, multi-center, open-label clinical study is designed to evaluate the safety, preliminary efficacy and pharmacodynamics of GPH101 in adult and adolescent patients with severe SCD.

For patient advocate Nancy Rene, the news is personal: “It’s always exciting to hear about the progress being made in sickle cell research.  If successful it will mean that my grandson, and especially other young adults, can look forward to a life free of pain and organ damage.  They can actually begin to plan their lives, thinking about careers and families. I want to thank Dr. Porteus and all of the scientists who are working so hard for people with sickle cell disease. This is wonderful news.”

CIRM has funded four clinical trials for Sickle Cell Disease using different approaches and has a unique partnership with the National Heart, Lung and Blood Institutes under the NIH “Cure Sickle Cell” initiative.

Positive results from CIRM-funded LAD-I trial presented at the 62nd American Society of Hematology Annual Meeting

Gaurav Shah, M.D., CEO and President of Rocket Pharmaceuticals

Leukocyte Adhesion Deficiency-I (LAD-I) is a rare pediatric disease caused by a mutation in a specific gene that causes low levels of a protein called CD18. Due to low levels of CD18, the adhesion of immune cells is affected, which negatively impacts the body’s ability to combat infections.

Rocket Pharmaceuticals is conducting a CIRM-funded ($6.56 M) clinical trial that is testing a treatment that uses a gene therapy called RP-L201. The therapy uses a patient’s own blood stem cells and inserts a functional version of the gene.  These modified stem cells are then reintroduced back into the patient. The goal is to establish functional immune cells, enabling the body to combat infections. Previous studies have indicated that an increase in CD18 to 4-10% is associated with survival into adulthood. 

The company presented interim data from the trial at the 62nd American Society of Hematology (ASH) Annual Meeting in the form of an oral presentation. The data presented is from three pediatric patients with severe LAD-I, which is defined by CD18 expression of less than 2%. The patients were all treated with RP-L201. Patient One was 9-years of age at enrollment and had been followed for 12-months as of a cutoff date of November 2020. Patient Two was 3-years of age at enrollment and had been followed for over 6-months. Patient Three was 7-months of age at enrollment and was recently treated with RP-L201.

Key highlights from the presentation include:

  • RP-L201 was well tolerated, no safety issues reported with infusion or post-treatment
  • All patients achieved hematopoietic (blood) reconstitution within 5-weeks
    • 12 months post-treatment, Patient One demonstrated durable CD18 expression of approximately 40%,
    • 6-months post-treatment, Patient Two demonstrated CD18 expression of 23%
    • 2-months post-treatment, Patient Three demonstrated CD18 expression of 76%

In a press release from Rocket, Gaurav Shah, M.D., CEO and President of Rocket, expressed excitement about these results.

“…we continue to see encouraging evidence of efficacy for RP-L201 for the treatment of LAD-I. Patients have shown sustained CD18 expression of 23% to 40%, far exceeding the 4-10% threshold associated with survival into adulthood…”

To view the presentations at the conclusion of the oral presentation, click the link here.

CIRM funded trial for sickle cell disease gives patient a chance for a better future

Evie Junior is participating in a CIRM funded clinical trial for sickle cell disease that uses a stem cell gene therapy approach. Image credit: UCLA Broad Stem Cell Research Center

For Evie Junior, personal health and fitness have always been a top priority. During his childhood, he was active and played football, basketball, and baseball in the Bronx, New York. One would never guess that after playing these sports, some nights he experienced pain crises so severe that he was unable to walk. One would also be shocked to hear that he had to have his gallbladder and spleen removed as a child as well.

The health issues that Evie has faced all of his life are related to his diagnosis of sickle cell disease (SCD), a genetic, blood related disorder. SCD causes blood stem cells in the bone marrow, which make blood cells, to produce hard, “sickle” shaped red blood cells. These “sickle” shaped blood cells die early, causing there to be a lack of red blood cells to carry oxygen throughout the body. Due to their “sickle” shape, these cells also get stuck in blood vessels and block blood flow, resulting in excruciating bouts of pain that come on with no warning and can leave patients hospitalized for days.

SCD affects 100,000 people in the United States, the majority of whom are from the Black and Latinx communities, and millions more people around the world,. It can ultimately lead to strokes, organ damage, and early death.

Growing up with SCD inspired Evie to become an emergency medical technician, where he would be able to help patients treat their pain en route to the hospital, in much the same way he has managed his own pain crises for his whole life. Unfortunately as time passed, Evie’s pain crises became harder and harder to manage.

Then in July 2019, Evie decided to enroll in a CIRM funded clinical trial for a stem cell gene therapy to treat SCD. The therapy, developed by Dr. Don Kohn at UCLA, is intended to correct the genetic mutation in a patient’s blood stem cells to allow them to produce healthy red blood cells. Dr. Kohn has already applied the same concept to successfully treat several genetic immune system deficiencies in two other CIRM funded trials, including a cure for a form of Severe Combined Immunodeficiency, also known as bubble baby disease, as well as X-Linked Chronic Granulomatous Disease.

After some delays related to the coronavirus pandemic, Evie finally received an infusion of his own blood stem cells that had been genetically modified to overcome the mutation that causes SCD in July 2020.

Although the results are still very preliminary, so far they look very promising. Three months after his treatment, blood tests indicated that 70% of Evie’s blood stem cells had the new corrected gene. The UCLA team estimates that a 20% correction would be enough to prevent future sickle cell complications. What is also encouraging is that Evie hasn’t had a pain crisis since undergoing the treatment.

In a press release from UCLA, Dr. Kohn discusses that he is cautiously optimistic about these results.

“It’s too early to declare victory, but it’s looking quite promising at this point. Once we’re at six months to a year, if it looks like it does now, I’ll feel very comfortable that he’s likely to have a permanent benefit.”

In the same press release, Evie talks about what a cure would mean for his future and his life going forward.

“I want to be present in my kids’ lives, so I’ve always said I’m not going to have kids unless I can get this cured. But if this works, it means I could start a family one day.”

You can learn more about Evie’s story and the remarkable CIRM funded work at UCLA by watching the video below.

CIRM-funded therapy to ease the impact of chemotherapy

Treatments for cancer have advanced a lot in recent years, but many still rely on the use of chemotherapy to either shrink tumors before surgery or help remove cancerous cells the surgery missed. The chemo can be very effective, but it’s also very toxic. Angiocrine Bioscience Inc. is developing a way to reduce those toxic side effects, and they just got a nice vote of confidence for that approach.

The US Food and Drug Administration (FDA) has granted Angiocrine Regenerative Medicine Advanced Therapy (RMAT) designation for their product AB-205.

RMAT is a big deal. It means the therapy, in this case AB-205, has already shown it is safe and potentially beneficial to patients, so the designation means that if it continues to be safe and effective it may be eligible for a faster, more streamlined approval process. And that means it can get to the patients who need it, outside of a clinical trial, faster.

What is AB-205? Well it’s made from genetically engineered cells, derived from cord blood, designed to help alleviate or accelerate recovery from the toxic side effects of chemotherapy for people undergoing treatment for lymphoma and other aggressive cancers of the blood or lymph system.

CIRM awarded Angiocrine Bioscience $6.2 million in 2018 to help carry out the Phase 2 clinical trial testing the therapy. In a news release ,CIRM President & CEO, Dr. Maria Millan, said there is a real need for this kind of therapy.

“This is a project that CIRM has supported from an earlier stage of research, highlighting our commitment to moving the most promising research out of the lab and into people. Lymphoma is the most common blood cancer and the 6th most commonly diagnosed cancer in California. Despite advances in therapy many patients still suffer severe complications from the chemotherapy, so any treatment that can reduce those complications can not only improve quality of life but also, we hope, improve long term health outcomes for patients.”

In a news release Dr. Paul Finnegan, Angiocrine’s CEO, welcomed the news.

“The RMAT designation speaks to the clinical meaningfulness and the promising efficacy data and safety profile of AB-205 based on our Phase 1b/2 study. This is an important step in accelerating the development of AB-205 towards its first market approval. We appreciate the thorough assessment provided by the FDA reviewers and the support from our partner, the California Institute for Regenerative Medicine.” 

The investment in Angiocrine marked a milestone for CIRM. It was the 50th clinical trial we had funded. It was a cause for celebration then. We’re hoping it will be a cause for an even bigger celebration in the not too distant future.

The company hopes to start a Phase 3 clinical trial in the US and Europe next year.

CIRM-Funded Clinical Trial for Sickle Cell Gives Hope to People Battling the Disease

Marissa Cors (right) with her mother Adrienne Shapiro

Marissa Cors has lived with Sickle Cell Disease (SCD) for more than 40 years. The co-founder of The Sickle Cell Experience Live, an online platform designed to bring more awareness to Sickle Cell Disease around the world, says it’s hard, knowing that at any moment you may have to put your life on hold to cope with another attack of excruciating pain.

“It is incredibly frustrating to have a disease that is constantly disrupting and interfering with your life. The daily pain and fatigue make it difficult to have a normal life. You may be experiencing manageable pain one minute and then a crisis will hit – knocking you to the ground with horrible pain and requiring pain management and hospitalization. It makes going to school or having a job or even a normal adult relationship near impossible.”

SCD is an inherited disease caused by a single gene mutation resulting in abnormal hemoglobin, which causes red blood cells to ‘sickle’ in shape.  Sickling of red blood cells clogs blood vessels and leads to progressive organ damage, pain crises, reduced quality of life, and early death. 

The disease affects around 100,000 Americans, mostly Black Americans but also members of the Latinx community. Marissa says coping with it is more than just a medical struggle. “Born into the cycle of fatigue, pain and fear. Depending on a healthcare system filled with institutionalized bias and racism. It is a life that is difficult on all facets.” 

CIRM is committed to trying find new treatments, and even a cure for SCD. That’s why the CIRM Board recently awarded $8,333,581 to Dr. David Williams at Boston Children’s Hospital to conduct a gene therapy clinical trial for sickle cell disease.  This is the second project that is part of an agreement between CIRM and the National Heart, Lung, and Blood Institute (NHLBI), part of the National Institutes of Health, to co-fund cell and gene therapy programs under the NHLBI’s  “Cure Sickle Cell” Initiative.  The goal of this agreement is to markedly accelerate clinical development of cell and gene therapies to cure SCD.

In recent years we have made impressive strides in developing new approaches to treating sickle cell disease,” says Dr. Maria T. Millan, President & CEO of CIRM. “But we still have work to do. That’s why this partnership, this research is so important. It reflects our commitment to pushing ahead as fast as we can to find a treatment, a cure, that will help all the people battling the disease here in the U.S. and the estimated 20 million worldwide.”

The team will take a patient’s own blood stem cells and insert a novel engineered gene to silence abnormal hemoglobin and induce normal fetal hemoglobin expression.  The modified blood stem cells will then be reintroduced back into the patient.  The goal of this therapy is to aid in the production of normal shaped red blood cells, thereby reducing the severity of the disease. 

For Marissa, anything that helps make life easier will be welcome not just for people with SCD but their families and the whole community. “A stem cell cure will end generations of guilt, suffering, pain and early death. It will give SCD families relief from the financial, emotional and spiritual burden of caring someone living with SCD. It will give all of us an opportunity to have a normal life. Go to school, go to work, live with confidence.” 

CIRM Board Approves Four New Clinical Trials

A breakdown of CIRM’s clinical trials by disease area

This past Thursday the governing Board of the California Institute for Regenerative Medicine (CIRM) approved four new clinical trials in addition to ten new discovery research awards.

These new awards bring the total number of CIRM-funded clinical trials to 68.  Additionally, these new additions have allowed the state agency to exceed the goal of commencing 50 new trials outlined in its five year strategic plan.

$8,970,732 was awarded to Dr. Steven Deeks at the University of California San Francisco (UCSF) to conduct a clinical trial that modifies a patient’s own immune cells in order to treat and potentially cure HIV. 

Current treatment of HIV involves the use of long-term antiretroviral therapy (ART).  However, many people are not able to access and adhere to long-term ART.

Dr. Deeks and his team will take a patient’s blood and extract T cells, a type of immune cell.  The T cells are then genetically modified to express two different chimeric antigen receptors (CAR), which enable the newly created duoCAR-T cells to recognize and destroy HIV infected cells.  The modified T cells are then reintroduced back into the patient.

The goal of this one time therapy is to act as a long-term control of HIV with patients no longer needing to take ART, in effect a form of HIV cure.  This approach would also address the needs of those who are not able to respond to current approaches, which is estimated to be 50% of those affected by HIV globally. 

$3,728,485 was awarded to Dr. Gayatri Rao from Rocket Pharmaceuticals to conduct a clinical trial using a gene therapy for infantile malignant osteopetrosis (IMO), a rare and life-threatening disorder that develops in infancy.  IMO is caused by defective bone cell function, which results in blindness, deafness, bone marrow failure, and death very early in life. 

The trial will use a gene therapy that targets IMO caused by mutations in the TCIRG1 gene.  The team will take a young child’s own blood stem cells and inserting a functional version of the TCIRG1 gene.  The newly corrected blood stem cells are then introduced back into the child, with the hope of halting or preventing the progression of IMO in young children before much damage can occur. 

Rocket Pharmaceuticals has used the same gene therapy approach for modifying blood stem cells in a separate CIRM funded trial for a rare pediatric disease, which has shown promising results.

$8,996,474 was awarded to Dr. Diana Farmer at UC Davis to conduct a clinical trial of in utero repair of myelomeningocele (MMC), the most severe form of spina bifida.  MMC is a birth defect that occurs due to incomplete closure of the developing spinal cord, resulting in neurological damage to the exposed cord.  This damage leads to lifelong lower body paralysis, and bladder and bowel dysfunction.

Dr. Farmer and her team will use placenta tissue to generate mesenchymal stem cells (MSCs).  The newly generated MSCs will be seeded onto an FDA approved dural graft and the product will be applied to the spinal cord while the infant is still developing in the womb.  The goal of this therapy is to help promote proper spinal cord formation and improve motor function, bladder function, and bowel function. 

The clinical trial builds upon the work of CIRM funded preclinical research.

$8,333,581 was awarded to Dr. David Williams at Boston Children’s Hospital to conduct a gene therapy clinical trial for sickle cell disease (SCD).  This is the second project that is part of an agreement between CIRM and the National Heart, Lung, and Blood Institute (NHLBI), part of the National Institutes of Health, to co-fund cell and gene therapy programs under the NHLBI’s  “Cure Sickle Cell” Initiative.  The goal of this agreement is to markedly accelerate clinical development of cell and gene therapies to cure SCD.

SCD is an inherited disease caused by a single gene mutation resulting in abnormal hemoglobin, which causes red blood cells to ‘sickle’ in shape.  Sickling of red blood cells clogs blood vessels and leads to progressive organ damage, pain crises, reduced quality of life, and early death. 

The team will take a patient’s own blood stem cells and insert a novel engineered gene to silence abnormal hemoglobin and induce normal fetal hemoglobin expression.  The modified blood stem cells will then be reintroduced back into the patient.  The goal of this therapy is to aid in the production of normal shaped red blood cells, thereby reducing the severity of the disease.

“Today is a momentus occasion as CIRM reaches 51 new clinical trials, surpassing one of the goals outlined in its five year strategic plan,” says Maria T. Millan, M.D., President and CEO of CIRM.  “These four new trials, which implement innovative approaches in the field of regenerative medicine, reflect CIRM’s ever expanding and diverse clinical portfolio.”

The Board also approved ten awards that are part of CIRM’s Quest Awards Prgoram (DISC2), which promote promising new technologies that could be translated to enable broad use and improve patient care.

The awards are summarized in the table below:

  APPLICATION  TITLE  INSTITUTION  AWARD AMOUNT  
    DISC2-12169  Human-induced pluripotent stem cell-derived glial enriched progenitors to treat white matter stroke and vascular dementia.  UCLA  $250,000
  DISC2-12170Development of COVID-19 Antiviral Therapy Using Human iPSC-Derived Lung Organoids  UC San Diego  $250,000
  DISC2-12111Hematopoietic Stem Cell Gene Therapy for X-linked Agammaglobulinemia  UCLA  $250,000
  DISC2-12158Development of a SYF2 antisense oligonucleotide (ASO) treatment for ALSUniversity of Southern California  $249,997
    DISC2-12124Dual angiogenic and immunomodulating nanotechnology for subcutaneous stem cell derived islet transplantation for the treatment of diabetes  Lundquist Institute  $250,000
  DISC2-12105Human iPSC-derived chimeric antigen receptor-expressing macrophages for cancer treatment  UC San Diego  $250,000
  DISC2-12164Optimization of a human interneuron cell therapy for traumatic brain injury  UC Irvine  $250,000
  DISC2-12172Combating COVID-19 using human PSC-derived NK cells  City of Hope  $249,998
  DISC2-12126The First Orally Delivered Cell Therapy for the Treatment of Inflammatory Bowel Disease  Vitabolus Inc.  $249,000
    DISC2-12130Transplantation of Pluripotent Stem Cell Derived Microglia for the Treatment of Adult-onset Leukoencephalopathy (HDLS/ALSP)  UC Irvine  $249,968

Stem cell therapy for deadly childhood immune disorder goes four for four

The gold standard for any new therapy in the U.S. is approval by the Food and Drug Administration (FDA). This approval clears the therapy for sale and often also means it will be covered by insurance. But along the way there are other designations that can mean a lot to a company developing a new approach to a deadly disease.

That’s what recently happened with Mustang Bio’s MB-107. The therapy was given Orphan Drug Designation for the treatment of X-linked Severe Combined Immunodeficiency (SCID) also known as “bubble baby disease”, a rare but deadly immune disorder affecting children. This is the same therapy that CIRM is funding in a clinical trial we’ve blogged about in the past.  

Getting Orphan Drug Designation can be a big deal. It is given to therapies intended for the treatment, diagnosis or prevention of rare diseases or disorders that affect fewer than 200,000 people in the U.S. It comes with some sweet incentives, such as tax credits toward the cost of clinical trials and prescription drug user fee waivers. And, if the product becomes the first in its class to get FDA approval for a particular disease, it is entitled to seven years of market exclusivity, which is independent from intellectual property protection.

This is not the first time Mustang Bio’s MB-107 has been acknowledged as a potential gamechanger. It’s also been given three other classifications both here in the US and in Europe.

  • Rare Pediatric Disease Designation: this also applies to treatments for diseases affecting fewer than 200,000 people in the US that have the potential to provide clinically meaningful benefits to patients. It provides the company with a “voucher” that they can use to apply for priority review for another therapy they are developing. The hope is that this will encourage companies to develop treatments for rare childhood diseases that might not otherwise be profitable.
  • Regenerative Medicine Advanced Therapy (RMAT) designation: this allows for faster, more streamlined approvals of regenerative medicine products
  • Advanced Therapy Medicinal Product classification: this is granted by the European Medicines Agency (EMA) to medicines that are based on genes, tissues or cells and can offer groundbreaking opportunities for the treatment of disease.

Of course, none of these designations are a guarantee that Mustang Bio’s MB-107 will ultimately get FDA approval, but they’re a pretty good indication that a lot of people have confidence they’ll get there.

Want to help us solve a mystery?

Patient that has recovered from Covid-19 donating blood plasma. Photo courtesy Science Photo

Convalescent plasma has been in the news a lot lately as a potential treatment for people infected with the coronavirus. In August the US Food and Drug Administration (FDA) granted emergency use authorization (EUA) to use these products based on preliminary data that suggested it might help people battling COVID. But there are still a lot of unanswered questions about this approach.

And that’s where you come in.

Plasma is a component of blood that carries proteins called antibodies that are usually involved in defending our bodies against viral infections.  We also know that blood plasma from patients that have recovered from COVID-19, referred to as convalescent plasma, contain antibodies against the virus that can be used as a potential treatment for COVID-19. 

That’s the theory, but the reality is that there are still a lot we don’t know, basic questions such as does it really work, how does it work, does it work for everyone or just some patients? A clinical  grant includes testing the plasma in COVID-19 Positive patients that CIRM is funding with City of Hope, UC Irvine and Translational Genomics Research Institute (TGen) hopes to answer those questions. 

The first step is getting the plasma from people who have recovered from COVID and then testing it to make sure it’s safe and to identify what blood type it is, so you can match that blood type with the person receiving it.

But plasma doesn’t contain just one kind of antibody, there are many antibodies and each one works in a slightly different way. For example, two antibodies, IGM and IGG, target in on the spike protein on the coronavirus. The goal is to block that spike and prevent the virus from spreading throughout the body. IGM has up to 10 ‘arms’ and so has the potential to bind multiple copies of the spike, whereas IGG has only 2 arms, but lasts longer. Both IGM and IGG also come in many different flavors, allowing them to bind to many different parts of the spike, some being more protective than others.

That’s one of the things that this trial is trying to find out. And you can help them do that. The trial needs volunteers, volunteers to donate the plasma and volunteers to try the therapy.

The team is evaluating changes that occur before and after plasma treatment.  Many recipients have no immediate response, a few get dramatically better, and some continue to have symptoms long after discharge from the hospital.  These so-called “long-haulers” can have debilitating problems, months after becoming infected. The study hopes to evaluate these variable responses to plasma treatment.

But more people are needed if we are to truly understand what works best. We need people who are newly infected, those being treated with plasma, and those that have recovered from the virus.

We are particularly interested in recruiting people from the Black and Latinx communities, groups that are often underserved when it comes to access to medical care.

The team has created a website to make it easy to find out more about the clinical trial, and to see if you are a good candidate to be part of it, either as a donor or recipient.

Lives are at stake and time is short so join us, help us find answers to the most pressing medical issue of our times. It’s a chance to do something that might benefit your family, your friends and your community.

Cures, clinical trials and unmet medical needs

When you have a great story to tell there’s no shame in repeating it as often as you can. After all, not everyone gets to hear first time around. Or second or third time. So that’s why we wanted to give you another opportunity to tune into some of the great presentations and discussions at our recent CIRM Alpha Stem Cell Clinic Network Symposium.

It was a day of fascinating science, heart-warming, and heart-breaking, stories. A day to celebrate the progress being made and to discuss the challenges that still lie ahead.

There is a wide selection of topics from “Driving Towards a Cure” – which looks at some pioneering work being done in research targeting type 1 diabetes and HIV/AIDS – to Cancer Clinical Trials, that looks at therapies for multiple myeloma, brain cancer and leukemia.

The COVID-19 pandemic also proved the background for two detailed discussions on our funding for projects targeting the coronavirus, and for how the lessons learned from the pandemic can help us be more responsive to the needs of underserved communities.

Here’s the agenda for the day and with each topic there’s a link to the video of the presentation and conversation.

Thursday October 8, 2020

View Recording: CIRM Fellows Trainees

9:00am Welcome Mehrdad Abedi, MD, UC Davis Health, ASCC Program Director  

Catriona Jamieson, MD,  View Recording: ASCC Network Value Proposition

9:10am Session I:  Cures for Rare Diseases Innovation in Action 

Moderator: Mark Walters, MD, UCSF, ASCC Program Director 

Don Kohn, MD, UCLA – View Recording: Severe combined immunodeficiency (SCID) 

Mark Walters, MD, UCSF, ASCC Program Director – View Recording: Thalassemia 

Pawash Priyank, View Recording: Patient Experience – SCID

Olivia and Stacy Stahl, View Recording: Patient Experience – Thalassemia

10 minute panel discussion/Q&A 

BREAK

9:55am Session II: Addressing Unmet Medical Needs: Driving Towards a Cure 

Moderator: John Zaia, MD, City of Hope, ASCC Program Direction 

Mehrdad Abedi, MD, UC Davis Health, ASCC Program Director – View Recording: HIV

Manasi Jaiman, MD, MPH, ViaCyte, Vice President, Clinical Development – View Recording: Diabetes

Jeff Taylor, Patient Experience – HIV

10 minute panel discussion/Q&A 

BREAK

10:40am Session III: Cancer Clinical Trials: Networking for Impact 

Moderator: Catriona Jamieson, MD, UC San Diego, ASCC Program Director 

Daniela Bota, MD, PhD, UC Irvine, ASCC Program Director – View Recording:  Glioblastoma 

Michael Choi, MD, UC San Diego – View Recording: Cirmtuzimab

Matthew Spear, MD, Poseida Therapeutics, Chief Medical Officer – View Recording: Multiple Myeloma  

John Lapham, Patient Experience –  View Recording: Chronic lymphocytic leukemia (CLL) 

10 minute panel discussion/Q&A 

BREAK

11:30am Session IV: Responding to COVID-19 and Engaging Communities

Two live “roundtable conversation” sessions, 1 hour each.

Roundtable 1: Moderator Maria Millan, MD, CIRM 

CIRM’s / ASCC Network’s response to COVID-19 Convalescent Plasma, Cell Therapy and Novel Vaccine Approaches

Panelists

Michael Matthay, MD, UC San Francisco: ARDS Program

Rachael Callcut, MD, MSPH, FACS, UC Davis: ARDS Program 

John Zaia, MD, City of Hope: Convalescent Plasma Program 

Daniela Bota, MD, PhD, UC Irvine: Natural Killer Cells as a Treatment Strategy 

Key questions for panelists: 

  • Describe your trial or clinical program?
  • What steps did you take to provide access to disproportionately impacted communities?
  • How is it part of the overall scientific response to COVID-19? 
  • How has the ASCC Network infrastructure accelerated this response? 

Brief Break

Roundtable 2: Moderator Ysabel Duron, The Latino Cancer Institute and Latinas Contra Cancer

View Recording: Roundtable 2

Community Engagement and Lessons Learned from the COVID Programs.  

Panelists

Marsha Treadwell, PhD, UC San Francisco: Community Engagement  

Sheila Young, MD, Charles R. Drew University of Medicine and Science: Convalescent Plasma Program in the community

David Lo, MD, PhD,  UC Riverside: Bringing a public health perspective to clinical interventions

Key questions for panelists: 

  • What were important lessons learned from the COVID programs? 
  • How can CIRM and the ASCC Network achieve equipoise among communities and engender trust in clinical research? 
  • How can CIRM and the ASCC Network address structural barriers (e.g. job constrains, geographic access) that limit opportunities to participate in clinical trials?