Ottawa, May 12, 2022 (GLOBE NEWSWIRE) -- The global cell therapy market size was estimated at US$ 10.35 billion in 2021. The governments all over the world are constantly investing in the biopharmaceutical industry's development. This has a direct impact on the worldwide cell therapy market's growth. For the introduction of innovative cell treatments into the worldwide market, leading industry participants are partnering with government authorities.

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Furthermore, for the growth and development of the global cell therapy market, industry participants are focusing on existing and developing areas. The high cost of cell therapies, on the other hand, is a major impediment to the worldwide cell therapy market's expansion. Furthermore, the cell treatment market's expansion is hampered by a scarcity of experienced personnel. However, due to the vast range of applications for cell therapy, the worldwide cell therapy market is likely to rise rapidly in the near future.

Regional Snapshot

North America is the largest segment for cell therapy market in terms of region. The U.S. is dominating the cell therapy market in the North America region. For the development of the cell therapy industry, variables such as rising chronic disease occurrences and increasing investments are important. Furthermore, expanding uses of stem cell technology for the treatment of various ailments are propelling the cell therapy market in North America. In addition, the market for cell treatment in North America is rising due to increased research and development activities.

Asia-Pacific region is the fastest growing region in the cell therapy market. China holds the highest market share in the Asia-Pacific cell therapy market. The expansion of the cell therapy market in this region is aided by favorable government policies. In addition, as a result of enhanced healthcare facilities, reduced costs, and rise in awareness of cell therapy, growing nations are expected to rise.

Scope of the Report

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Report Highlights

Market Dynamics

Drivers

Growing approvals for cell-based therapies

The cell therapies are getting approved easily by government agencies. Since FDA approved products are readily available in developing regions, cell treatments are commonly used. For example, the FDA granted Novartis Kymriah regenerative medicine enhanced therapy designation in April 2020 for the treatment of refractory follicular lymphoma in adults. The FDA authorized brexucabtagene autoleucel, a CAR T-cell treatment for patients with mantle cell lymphoma in July 2020.

Restraints

High capital investments for cell therapy plants

People seeking the most up to date alternative remedies for the various ailments have become increasingly interested in stem cell therapy nowadays. Every day, new sorts of therapies are launched and individuals all over the globe are turning to them instead of standard drug regimens and hospital visits. Despite the high demand for stem cell therapies, they are still prohibitively costly to develop. Simple joint injections can set back about $1,000 while more complex procedures can cost up to $100,000 depending on the issue.

Opportunities

Growing government initiatives

The government is heavily investing in research and development activities. The Australian government published The Stem Cell Therapies Mission, journey of 10 years for stem cell research, in November 2019. The Medical Research Future Fund would receive $102 million to support stem cell research in order to develop novel medicines. Thus, the growing government initiatives are creating lucrative opportunities for the growth of global cell therapy market.

Challenges

Lack of skilled professionals

The lack of skilled professionals is a major challenge faced by global cell therapy market. As per the National Accrediting Agency for Clinical Laboratory Sciences, there is a global demand supply mismatch for competent personnel. According to a research study conducted by the Gatsby Foundation, the UK will require an additional 700,000 professionals to sustain the economy by 2030.

Related Reports

Recent Developments

Market Segmentation

By Use Type

By Therapy Type

By End User

By Geography

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Cell Therapy Market Size to Surpass US$ 60.67 Billion by 2030 - GlobeNewswire

An experimental cancer therapy that infuses designer immune cells into patients has shown early promise in a clinical trial by shrinking tumours in the digestive system.

Interim results from the first phase of the clinical trial found that the tumours in nearly half 48.6% of the 37 patients treated so far reduced in size after the therapy.

While the findings come from an initial safety assessment of the approach, researchers running the trial in Beijing believe it demonstrates the potential for genetically altered immune cells to treat advanced gastrointestinal cancers.

So-called Car T-cell therapy takes white blood cells, or T cells, from patients and modifies them so that they can recognise and kill cancer cells. The approach has met with dramatic success as a treatment for blood cancers such as leukaemia, but solid tumours have proved more difficult to target.

Writing in Nature Medicine, researchers led by Dr Lin Shen at the Peking University Cancer Hospital and Institute describe how they made Car T cells that target tumours bearing a protein called CLDN18.2. The protein is found in many cancers, but particularly in gastrointestinal tumours.

The researchers infused Car T cells into 37 patients with advanced cancers of the stomach, digestive tract or pancreas and found that while all experienced side-effects, the therapy had an acceptable safety profile. The treatment seemed most effective in those with stomach cancer, with more than 57% responding to the infusions.

The scientists stress that the findings need to be verified in the complete trial, but say the interim results suggest the approach has the potential to become an important treatment modality for patients with advanced gastric cancer. About 6,500 people are diagnosed with stomach cancer in the UK each year, roughly half of whom are over 75.

Waseem Qasim, professor of cell and gene therapy at the Institute of Child Health and Great Ormond Street hospital, who works on Car T-cell therapies, said the preliminary results were promising.

The report provides some strong hints that engineered Car T cells can help shrink gastric cancers, in this case by targeting a particular flag on the surface of cells. As for other advanced solid cancers, achieving complete remissions is challenging, but the experiences shows there is potential for interventions that redirect the immune system against cancer, he said.

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Prof Charles Swanton, Cancer Research UKs chief clinician, said: Car T-cell therapies, which harness modified versions of our own immune cells to fight cancer, have so far had limited success in solid tumours, which make up most cancers. So its particularly promising to see these results, which show a high percentage of people with digestive cancers seeing the benefits of treatment last beyond six months.

This is encouraging, as people with digestive cancers have very few treatment options. The study is still at an early stage, and larger-scale clinical trials will need to be done before Car T-cell therapies can be used routinely in this setting.

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Car T-cell therapy shows early promise in treating gastric cancers - The Guardian

A few hours after Tom (not his real name) was born, he became restless and did not want to be breastfed. His mother noticed that his left arm and leg were shaking rhythmically something was not right.

Tom was immediately transferred to the neonatal intensive care unit. An MRI scan revealed that he had suffered a severe stroke. Doctors told Toms parents that there was no treatment they could give the child. He would probably be disabled.

Most people think of stroke as something that mainly affects the elderly, but it can also occur in newborn babies. These perinatal strokes happen when one of the major arteries to the brain becomes blocked, leading to a lack of blood supply and hence oxygen to certain brain areas. About one in 5,000 newborns have a stroke. It usually happens in the first few days after they are born.

Most of the babies will have problems later in life, with the severity of the problems depending on which brain areas were injured. These problems can include muscle tightness in the arms and legs (cerebral palsy), behaviour problems, learning difficulties and epilepsy.

No therapy exists for newborns with stroke. Researchers, including our own team at University Medical Center Utrecht, have been working on new treatments, one of which involves stem cells.

Stem cells have the ability to turn into many different cells in the body, and they are little factories of several growth factors (proteins that stimulate the growth of specific tissues). The theory is that if we can get stem cells into the damaged part of a babys brain, the stem cells growth factors will stimulate the brain to repair itself.

Earlier studies in animals showed that injecting stem cells into the brains of newborn mice with stroke dramatically reduced the amount of brain damage and disability they suffered. The experiments showed that the treatment was safe and had no side-effects in the mice. These animal studies gave us hope that the treatment would work in newborn babies, too, preventing a lifetime of disability.

But how do you deliver stem cells to a babys brain without having to use needles or surgery? We decided to try an intranasal route (through the nose), which was tested in mice. After we delivered the stem cells intranasally, the cells travelled rapidly and specifically to the injured brain areas. The injured brain area sends out alarm signals which guide the stem cells to the right spot in the brain.

Once the stem cells arrived at the damaged area, they secreted growth factors that boosted the repair systems of the mices brains. Within a few days, the stem cells were broken down and not traceable in the brain any longer. After several experiments with this method, we concluded that dripping stem cells in the nose is the safest and most efficient way to deliver them to the brain.

After many years of laboratory research, we have finally tested the treatment in babies. The results have been published in The Lancet Neurology.

Baby Tom, mentioned earlier, was the first baby to participate in the study and received stem cells within a week of being born. To ask parents to enrol in an experimental therapy in the first week of their newborn childs life is a very delicate process.

After we had a long conversation with his parents, they decided to let their son take part in the study. He received stem cells via nose droplets, a procedure that took only several minutes. Afterwards, Tom was monitored closely for a few days before he went home.

We treated ten newborns who were transferred from hospitals across the Netherlands to the University Medical Center Utrecht after suffering from a stroke. In all ten newborns, the stem cell droplets were administered without any complications. There was one baby who had a mild fever after the treatment, which quickly cleared up on its own.

A follow-up MRI scan of the brain made three months after the stroke showed less injury than expected, possibly because of the stem cells. At four months, the treated babies, including Tom, performed well when the quality of their movements was tested. When the children are two years old, we will check their development again.

We are now looking for opportunities to proceed with a randomised controlled trial (the gold standard for medical studies) to prove that stem cell therapy can effectively repair brain injury after perinatal stroke.

The discovery of a new and safe therapy with stem cells also opens up opportunities for other babies with brain injury, such as babies who are born too early, or babies that suffer from a lack of oxygen during birth (perinatal asphyxia). Stem cell therapy gives hope to the most vulnerable patient group, with possible lifelong benefits.

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Stem cell therapy offers a new hope to repair brain damage in newborns - The Conversation

Newswise Philadelphia, May 11, 2022 Ten years ago, Tom and Kari Whitehead came to Childrens Hospital of Philadelphia (CHOP) looking for a miracle. Their 6-year-old daughter, Emily, had relapsed in her battle with acute lymphoblastic leukemia (ALL), after many months of unsuccessful chemotherapy and a disease that had progressed so rapidly that she was ineligible for a bone marrow transplant to treat it. Her local medical team had told her family there was nothing left to do but bring Emily home and allow her to die peacefully, surrounded by loved ones.

Unwilling to accept this outcome, her family came to CHOP in the hopes that Dr. Stephan Grupp, a pioneer in the field of cellular immunotherapy, could provide the miracle they were looking for. Dr. Grupp had been working in close collaboration with researchers Drs. Carl June, Bruce Levine, and David Porter at Penn Medicines Abramson Cancer Center to establish a protocol to infuse, for the first time in children, a brand-new CAR T-cell therapy product targeted against leukemia. Then an experimental treatment in its earliest days, CAR T-cell therapy harnesses the power of a patients own immune system by reengineering their T cells to attack proteins found on the surface of cancer cells.

Dr. Grupp and the research team were about to open the first phase 1 trial for CAR T-cell therapy in pediatric patients with ALL, based on early success Penn scientists had already seen in three adult patients with chronic lymphocytic leukemia. With no time to lose, Emily became the first patient to enroll in the new trial, making her the first pediatric patient ever to receive the treatment and the first patient of any age to receive it for ALL.

Ten years later, it is clear the Whiteheads found the miracle they sought. The journey was uncharted and at times bumpy, as the research team encountered the unexpected twists and turns that come with being the first to administer a brand-new treatment. But the treatment worked far better than anyone might have anticipated, and to this day, Emily is cancer free.

What we learned from Emily has defined the entire field of CAR T-cell therapy, said Dr. Grupp, Section Chief of the Cellular Therapy and Transplant Section, and Inaugural Director of the Susan S. and Stephen P. Kelly Center for Cancer Immunotherapy at Childrens Hospital of Philadelphia.

Ten years ago, we had no idea what to expect. Would the treatment work? Would it last? In the end, her outcomes far exceeded our most optimistic expectations not only did the treatment work for completely uncontrolled disease, but her engineered T cells endured and prevented relapse for what has now been 10 years. We have since treated more than 440 patients at CHOP with this therapy, and thousands of pediatric patients around the world have received it as well. It has truly been a revolution in pediatric cancer care, and it started with Emily.

Each of the earliest patients to receive CAR T cell therapy was a brave pioneer we have learned something from each patient, and each of them has served as a link to the next patients to improve the way we care for them and keep our teams working hard in the lab to apply this approach to help both adults and children with even more types of cancer, said Dr. June, the Richard W. Vague Professor in Immunotherapy in the Perelman School of Medicine at the University of Pennsylvania and director of Penns Center for Cellular Immunotherapies. The Whiteheads and other families whove participated in our trials have been extraordinary partners in the transformation of cancer care.

Learning on the Fly

Emilys CAR T journey began in March 2012, when her T cells were harvested and sent to the Cell and Vaccine Production Facility at Penn, where the team modified Emilys cells with a chimeric antigen receptor, or CAR, that targeted CD19, a protein found on the surface of ALL cancer cells. A month later, after Emily had undergone chemotherapy to reset her immune system, the engineered CAR-modified T-cells were infused in her body over a period of three days.

However, soon after the infusion, she became critically ill. Her blood pressure plummeted, her temperature skyrocketed, and she was having difficulty breathing. She ended up in the pediatric intensive care unit (PICU), while the medical team worked day and night to identify the source of the problem. Over the course of a few days, Emilys condition deteriorated, and the team and Emilys family prepared for the eventuality that Emily might not survive.

Just when the outlook seemed most bleak, the team received measurements of Emilys cytokines. Cytokines are proteins that control immune responses, but they can cause severe reactions and death when the immune system becomes too activated. The Penn and CHOP teams conferred after noticing that one protein (interleukin-6 or IL-6) was particularly elevated. In a stroke of serendipity, IL-6 was one of the few cytokines in 2012 with an FDA-approved drug that blocks it. In a Hail Mary moment, Dr. Grupp gave Emily the drug, an arthritis treatment called tocilizumab, hoping it would bring her reaction under control and give her a fighting chance.

Remarkably, Emilys condition improved rapidly within hours. She not only recovered from her condition, which was unnamed at the time but is now known as cytokine release syndrome (CRS), but the engineered T cells did exactly what they were intended to do: they eradicated the cancer and put Emily into remission.

Through Emily, we learned how to control CRS when it gets serious in these patients, and that information has been disseminated throughout world and used by all physicians that treat patients with CAR T-cell therapy, Dr. Grupp said. Tocilizumab is now a standard part of the CAR T treatment protocol for patients who present with CRS.

Beyond ALL and Beyond CAR T

On August 30, 2017, five years after Emily was treated, the FDA approved the CAR T-cell therapy product used to treat Emily, now called tisagenlecleucel or Kymriah. It was the first CAR T treatment in the world, as well as the first gene therapy in the US, and this brand-new field of medicine began with this approval for pediatric ALL. Since then, the FDA has approved a total of six CAR T-cell therapies, for conditions ranging from diffuse large B cell lymphoma to multiple myeloma.

Since Emilys treatment, researchers have made inroads into treating other pediatric cancers with CAR T. Investigators, including CHOPs Assistant Vice President and Chief Clinical Research Officer Dr. Richard Aplenc and the Chief of the Hematologic Malignancies Program Dr. Sarah K. Tasian, are studying the use of CAR T to treat acute myeloid leukemia (AML). AML is an aggressive blood cancer that requires more intensive chemotherapy and generally has a poor prognosis. CAR T for AML is still in the early stages, but studies are ongoing.

Researchers are also looking into the potential use of CAR T-cell therapy to treat solid tumors, which have been more challenging to treat with immunotherapy because the tumors find ways of excluding T cells and preventing them from entering and killing the tumor. Dr. John M. Maris, Giulio D'Angio Chair in Neuroblastoma Research at CHOP, is working with the Kelly Center team on an upcoming trial of CAR T-cells targeted against GPC2 and is currently investigating the use of CAR T-cell therapy that targets other unique cancer targets. Both are designed to treat neuroblastoma, an aggressive pediatric cancer with poor cure rates.

Beyond cancer, the principles that led to Emilys successful treatment engineering her own cells to fight disease and infusing those cells back in her body are being used in other clinical areas to develop potentially curative therapies. Currently, Dr. Grupp leads the study steering committee for clinical trials investigating the use of the gene editing tool CRISPR to treat patients with sickle cell disease, a process that involves harvesting patients cells, editing them, and transfusing the corrected cells back into patients with the goal of curing the patients. Although this approach is fundamentally different than CAR T-cell therapy, both the concept and the engineered cell therapy approach stems from this first FDA approval, and the foundation laid by the experience of patients like Emily.

The C Word

Patients receiving conventional cancer treatment are generally considered cured once they have been in remission for five years. However, given the novelty of Emilys treatment, Dr. Grupp and his research team felt it was premature to call Emily cured at her five-year follow-up appointment.

I've always been cautious about calling this a cure, Dr. Grupp said. We actually refer to it as the C word. But now we're 10 years out. Do I believe Emily is cured? Do I believe other children who are 5 or 9 years out from their CAR T therapy are cured? I believe they are.

Not all patients who receive CAR T for relapsed ALL reach the same outcome as Emily. Currently, more than 90% of patients who receive CAR T-cell therapy for relapsed ALL will go into remission; approximately 50% of those patients will remain cancer free. Although the other 50% eventually relapse, prior to CAR-T only 9% of patients with relapsed ALL remained cancer free. Cellular therapy has vastly improved those outcomes, and researchers are continuing to advance the field so that more patients never relapse.

Everybody talks about bench to bedside research, and it's incredibly important, but there is also now this opportunity of bedside to bench, Dr. Grupp said. We are studying the cells of patients who receive this treatment and achieve exceptional responses like Emily and many others and are trying to reverse engineer what we see so we can achieve a sustained response in even more patients. So not only are we helping the patients we treat, but the patients are actually teaching us more about how to help future patients. Thats what Emily did.

What a Cure Looks Like

Emily is now almost 17 and a junior in high school. She recently received her drivers license and is driving as much as she can. Soon, she will take the SATs and begin drafting college essays, with the intention of applying to colleges in the fall. Eventually, shed like to pursue a career in film or environmental science.

Her father, Tom, says seeing her behind the wheel, living a normal teenage life, is something he has dreamed about since the CAR T-cell therapy put Emily into remission.

To look at her every day and to see what a cure for cancer actually looks like it's pretty amazing for us, Tom said. Our goal is to spread the word about the potential of this treatment so that other families can have the same outcome as us. I tell people all the time that the best move we ever made with Emily was bringing her to Children's Hospital of Philadelphia when we did.

Given their experience with CAR T at CHOP, the Whitehead family started the Emily Whitehead Foundation in 2015 to help more families by funding the most promising cutting-edge cancer research, including CAR T-cell therapy and other immunotherapies. Now in its eighth year, the foundation has supported numerous cancer researchers, including those at CHOP.

Emily doesnt remember much about her treatment, but she is grateful for the doctors and nurses who have allowed her to think about her future and not about her past.

Not only are those doctors and nurses helping kids get better, but they're saving their families as well, she said. Having the opportunity to leave the hospital and come home and just live a normal life getting a license or going to college its so important to families who have had to go through cancer treatment.

Based on Emilys success, researchers like Dr. Grupp imagine a future where minimal chemotherapy could be given to patients with ALL, followed by CAR T. Doing so would transform how leukemia is treated and would be a huge improvement for families and patients, who traditionally have needed up to three years of chemotherapy. The field isnt there yet, but when Dr. Grupp looks back at the past 10 years, he suspects it is only a matter of time.

If you had told me when we first treated Emily what the next 10 years would look like, I would have said youre dreaming. I would have said that there's no chance that any of this could work as well as it has, that we could have gone from treating Emily to FDA approval in 5 years, that we could have multiple FDA-approved products based on the initial experience treating patients at Penn and CHOP, Dr. Grupp said. It has all succeeded way beyond any of our wildest imaginations.

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About Childrens Hospital of Philadelphia:A non-profit, charitable organization, Childrens Hospital of Philadelphia was founded in 1855 as the nations first pediatric hospital. Through its long-standing commitment to providing exceptional patient care, training new generations of pediatric healthcare professionals, and pioneering major research initiatives, the 595-bed hospital has fostered many discoveries that have benefited children worldwide. Its pediatric research program is among the largest in the country.The institution has a well-established history of providing advanced pediatric care close to home through itsCHOP Care Network, which includes more than 50 primary care practices, specialty care and surgical centers, urgent care centers, and community hospital alliances throughout Pennsylvania and New Jersey, as well as anew inpatient hospitalwith a dedicated pediatric emergency department in King of Prussia.In addition, its unique family-centered care and public service programs have brought Childrens Hospital of Philadelphia recognition as a leading advocate for children and adolescents. For more information, visithttp://www.chop.edu.

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Emily Whitehead, First Pediatric Patient to Receive CAR T-Cell Therapy, Celebrates Cure 10 Years Later - Newswise

Patients with relapsed/refractory B-cell non-Hodgkin lymphoma who experienced grade 3 or higher immune effector cellassociated neurotoxicity syndrome who were treated with early intrathecal therapy experienced improved survival.

Early intrathecal therapy may help combat grade 3 or higher immune effector cellassociated neurotoxicity syndrome (ICANS) and decrease treatment-related mortality for patients with relapsed/refractory B-cell non-Hodgkin lymphoma, according to a study published in JAMA Oncology.

ICANS resolved in all 7 patients, and findings from the temporal course indicated that the improvement was associated with intrathecal therapy. The estimated 1-year progression-free survival (PFS) and overall survival (OS) was 57.1%, and the median follow-up for surviving patients was 611 days from the time of CAR T-cell infusion. Four patients had steroid-refractory ICANS. Investigators reported an estimated 1-year PFS and OS of 18.8% for all patients and 0% for those with steroid-refractory ICANS. As of the last follow-up, all living patients remained in complete remission.

Intrathecal therapy may be a valuable central nervous system-directed treatment for high-grade and/or steroid-refractory ICANS and an alternative to systemic immunosuppression, potentially reducing treatment-related mortality associated with CAR T-cell therapy. Further prospective investigation is indicated to validate these findings, investigators of the study wrote.

This study used data from 2 clinical trials (NCT03019055 and NCT04186520) examining CAR 20/19 T cells in relapsed/refractory B-cell malignancies. Data were also used from patients who were treated with commercial CAR T-cell therapy. The analysis included those who developed high-grade ICANS after treatment with either anti-CD19 CAR T-cells or bispecific lentiviral anti-CD19 and anti-CD20 CAR T-cells between 2018 and 2021.

A total of 74 patients were analyzed who received CAR T-cell therapy, 15 of whom developed high-grade ICANS following treatment. The mean age was 64.9 years and 8 patients were men. Additionally, 8 patients were treated with axicabtagene ciloleucel (Yescarta) and 7 were treated with an investigational agent.

Of those who developed high-grade ICANS, 7 patients were steroid-refractory and were treated with intrathecal therapy within 5 days of development. In 6 patients, CAR T-cells were detected in the cerebrospinal fluid.

Additional treatment with anakinra (Kineret) was included for patients with steroid-refractory ICANS. Patients received a median cumulative corticosteroid dose of 713 mg of dexamethasone equivalents for a median duration of 35 days. From the onset of high-grade ICANS, it took 6 days to resolved to grade 1 ICANS. After administration of intrathecal therapy for high-grade ICANS, investigators reported that it took a median of 2 days to resolve to grade 2 and a median of 5 days to improve to grade 1. All patients treated with anakinra died of infection complications. Intrathecal therapy was not administered to 7 patients, and 1 patient received late intrathecal therapy 24 days after developing ICANS.

A total of 2 patients with non-steroid refractory ICANS were alive and in complete remission at the last follow-up. Moreover, 3 patients with steroid-refractory ICANs received additional treatment. Those with steroid-refractory ICANS had a median duration of treatment with corticosteroids of 50 days and a median cumulative dose of 962.5 mg of dexamethasone equivalents. Steroid-refractory ICANS did not resolve for 2 patients, and it took 13 and 22 days, respectively, for it to improve to grade 1 in the remaining 2 patients.

Zurko JC, Johnson BD, Aschenbrenner E, et al. Use of early intrathecal therapy to manage high-grade immune effector cell-associated neurotoxicity syndrome.JAMA Oncol. Published Online March 10, 2022. doi:10.1001/jamaoncol.2022.0070

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Early Intrathecal Therapy Appears Feasible, Efficacious for ICANS in R/R B-cell Non-Hodgkin Lymphoma - Cancer Network