Tag Archive for: Amy Hont

little girl with cancer

A destination for pediatric oncology care: Children’s National Hospital’s T-cell therapy trials

When children are diagnosed with pediatric cancer, most doctors are forced to reach for the same standard therapies that were available decades ago. Research oncologists at Children’s National Hospital are changing that with clinical trials that will hopefully train the body’s immune system – specifically its T cells – to fight the tumors.

Holly Meany, M.D., and her colleague Amy Hont, M.D., oncologists and research scientists at the Center for Cancer and Immunology Research, have put together a pair of clinical trials that are investigating two pathways for using T cells to go after solid tumors.

“At Children’s National, we have a novel immunotherapy to offer to patients with relapsed or refractory solid tumors,” said Meany, director of the Solid Tumor Program. “This is a patient population who has failed standard therapy, so new technologies and treatments are always needed in this group.”

Where we started

Meany’s trial laid the foundation. She began the center’s research using a patient’s own blood sample to develop a targeted therapy and evaluate the safety and efficacy of this approach. In her study, scientists isolated the T cells, grew millions in a lab and reinfused them into the patient. The cells were replicated in an environment that was rich in three proteins that are commonly found on the surface of solid tumor cancer cells.

“Our hope and hypothesis are that when we give the T cells back to the patient, those T cells circulate and hunt down the cancer cells that have the tumor proteins,” Meany said. “We are hoping to use the patient’s own immune system to attack the cancer in an enduring way.”

Where we are headed

Hont’s phase 1 trial, which is currently recruiting participants, builds on Meany’s work using a healthy donor whose T cells have not been impacted by chemotherapy or other treatments. The cells can be prepared, stored and readily available for patients who need them. They are also matched through specific proteins on the patient’s own cells to bolster their effectiveness. The participants in this trial have Wilms tumors, rhabdomyosarcoma, neurosarcoma, soft tissue sarcoma or neuroblastoma, but conventional therapies including chemotherapy, radiation or surgery were unable to fully treat the disease.

In both studies, Hont said that the T cells have been given in an outpatient setting with fewer side effects compared to other cancer treatments aimed at high-risk malignancies.

“This allows patients to really maintain a good quality of life during a particularly hard time,” Hont said. “Also, these T cells are designed to act in the body the way that our immune system acts in a physiologic way. This means patients typically don’t have the severe side effects that we think of with chemotherapy or other therapies.”

Children’s National leads the way

The team at Children’s National is one of the few in the country to offer this kind of T-cell therapy for solid tumors. “Immunotherapy has been challenging for this patient population because the tumors are adept at finding out ways to evade treatment,” Hont said. “Giving patients a chance to receive a targeted T-cell therapy, while also maintaining a high quality of life, is something that’s special here.”

Dr. Bollard and her laboratory

Catherine Bollard, M.D., M.B.Ch.B., selected to lead global Cancer Grand Challenges team

Dr. Bollard and her laboratory

Cancer Grand Challenges NexTGen team members (left to right): Amy Hont, M.D., AeRang Kim, M.D., Nitin Agrawal, Ph.D., Catherine Bollard, M.D., M.B.Ch.B., Conrad Russell Cruz, M.D., Ph.D., Patrick Hanley, Ph.D., and Anqing Zhang.

A world-class team of researchers co-led by Catherine Bollard, M.D., M.B.Ch.B., director of the Center for Cancer and Immunology Research at Children’s National Hospital, has been selected to receive a $25m Cancer Grand Challenges award to tackle solid tumors in children. Cancer Grand Challenges is a global funding platform, co-founded by Cancer Research UK and the National Cancer Institute in the U.S., that supports a community of diverse, global teams to come together, think differently and take on some of cancer’s toughest challenges.

The Cancer Grand Challenges NexTGen team, co-led by University College London’s Martin Pule, M.D., will be working to develop next-generation cell therapies for children with solid cancers. Cancer is a leading cause of death by disease in children worldwide. Although survival has increased for some pediatric cancers, such as blood cancers, survival for some solid tumors has seen little improvement for more than 30 years. The team hopes to build a much deeper understanding of childhood cancers and develop and optimize novel therapies for children with solid tumors, ultimately hoping to improve survival and diminish the lifelong toxicities often experienced by survivors.

“With our Cancer Grand Challenge, we hope to bring next-generation CAR T-cell therapies to children with solid tumors,” said Dr. Bollard. “What excites me most is the energized, passionate group of people we’ve brought together to take this challenge on. Big problems remain to be addressed, but we believe they can be solved, and that we’re the team to solve them.”

“NexTGen represents crucial and overdue work. It has hope written all over,” said Sara Wakeling, patient advocate on the team and CEO and co-founder of Alice’s Arc, a children’s charity for rhabdomyosarcoma. “NexTGen hopes to transform the way these aggressive solid tumors are treated with less toxic side-effects, giving the children a real chance at growing up and realizing their potential. I’m so proud to be part of this exceptional team of scientists, clinicians and advocates who want to change the story for those diagnosed.”

The NexTGen team unites scientists and clinicians with expertise in immunology, proteomics, mathematics and more, across eight institutions throughout the U.S., U.K. and France. The Children’s National investigators that will also join are:

  • Nitin Agrawal, Ph.D., associate professor in the Center for Cancer and Immunology Research at Children’s National.
  • Conrad Russell Cruz, M.D., Ph.D.,principal investigator for the Program for Cell Enhancement and Technologies for Immunotherapies at Children’s National.
  • Patrick Hanley, Ph.D., chief and director of the cellular therapy program at Children’s National and leader of the Good Manufacturing Practices laboratory.
  • Amy Hont, M.D., oncologist in the Center for Cancer and Immunology Research at Children’s National.
  • AeRang Kim, M.D., oncologist in The Center for Cancer and Blood Disorders at Children’s National.
  • Holly Meany, M.D., oncologist in The Center for Cancer and Blood Disorders at Children’s National.
  • Anqing Zhang, biostatistician in the Biostatistics and Study Methodology Department at Children’s National.

The team, co-funded by Cancer Research UK, the National Cancer Institute and The Mark Foundation for Cancer Research, aims to bring much needed new treatments to children with solid cancers.

The NexTGen team is one of four new teams announced today as part of Cancer Grand Challenges, representing a total investment of $100m to diverse, global teams to take on some of the toughest challenges in cancer research.

“Cancer is a global issue that needs to be met with global collaboration. This investment in team science encourages diverse thinking to problems that have long hindered research progress,” said David Scott, Ph.D., director of Cancer Grand Challenges, Cancer Research UK. “Cancer Grand Challenges provides the multidisciplinary teams the time, space and funding to foster innovation and a transformative approach. NexTGen is one of four newly funded teams joining a scientific community addressing unmet clinical needs across cancer research.”

Find out more

Cancer Grand Challenges supports a global community of diverse, world-class research teams with awards of £20m/$25m to come together, think differently and take on cancer’s toughest challenges. These are the obstacles that continue to impede progress and no one scientist, institution or country will be able to solve them alone. Cancer Grand Challenges teams are empowered to rise above the traditional boundaries of geography and discipline.

Founded by the two largest funders of cancer research in the world – Cancer Research UK and the National Cancer Institute* in the U.S. – Cancer Grand Challenges aims to make the progress against cancer we urgently need. Cancer Grand Challenges currently supports more than 700 researchers and advocates across 10 countries, representing 11 teams are supported to take on 10 of the toughest challenges in cancer research.

The Cancer Grand Challenges NexTGen team, announced June 16, 2022, is taking on the initiative’s Solid Tumours in Children challenge. It is led by Dr. Bollard (Children’s National) and Dr. Pule (University College London), along with 23 co-investigators and 7 patient advocates, and is spread across eight institutions across the U.S., U.K. and France: Cardiff University; Children’s Hospital of Philadelphia; Children’s National Hospital; INSERM; the Institute of Cancer Research; Stanford Medicine; Stanford University; University College London. The Cancer Grand Challenges NexTGen team is funded by Cancer Research UK, the National Cancer Institute in the U.S. and The Mark Foundation for Cancer Research.

*The National Cancer Institute is part of the National Institutes of Health.

 

Wilm's Tumor

PRAME-specific T cell product may facilitate rapid treatment in cancer settings

Wilms Tumor

PRAME is a cancer-testis antigen that plays a role in cancer cell proliferation and survival and is overexpressed in many human malignancies, including Wilms tumor. “Wilms Tumor (Nephroblastoma)” by euthman is licensed under CC BY 2.0.

Generated preferentially expressed antigen in melanoma (PRAME)-specific T cells from healthy donors can kill PRAME-expressing tumor cells in vitro, researchers at Children’s National Hospital found. Several novel epitopes, which are antigens that are recognized by the immune system, were also identified for enhanced matching, making this a potential therapeutic option for a broader patient group, according to a study published in Cytotherapy.

PRAME is a cancer-testis antigen that plays a role in cancer cell proliferation and survival and is overexpressed in many human malignancies, including melanoma, leukemia, sarcoma, renal cell cancer and Wilms tumor. PRAME also acts as a foreign substance in the body that can trigger the immune system by activating T cells, making it a good target for anticancer immunotherapy — especially for immunocompromised patients.

“The development of an effective off-the-shelf adoptive T-cell therapy for patients with relapsed or refractory cancers expressing PRAME antigen requires the identification of epitopes essential to the adaptive immune response, which are presented by major histocompatibility complex (MHC) class I and II, and are then recognized by the manufactured PRAME-specific T cell product,” said Amy Hont, M.D., oncologist for the Center for Cancer and Immunology Research at Children’s National Hospital. “We, therefore, set out to extend the repertoire of HLA-restricted PRAME peptide epitopes beyond the few already characterized and demonstrate the cytotoxic activity of PRAME-specific T cells to tumor cells known to express PRAME.”

Immunotherapy options for pediatric patients with high-risk malignancies, especially solid tumors, are few. Tumor-associated antigen-specific T cells (TAA-T) offer a therapeutic option for these patients, and Children’s National is building upon the success of the ongoing clinical trials to optimize this therapy and improve the treatment of our patients.

“These findings will also benefit patients because it better informs the pre-clinical studies of third party TAA-T to treat high-risk malignancies, so that we can move more quickly and safely to clinical trials,” said Dr. Hont.

Stanojevic et al. describes that the T-cell products killed partially HLA-matched tumors, and that this enhanced disintegration of tumor cells compared with non-specific T cells suggests an anti-tumor potential for a clinical trial evaluation to determine the safety and efficacy. Further research about the PRAME-specific T cells will help inform a treatment alternative for patients with solid tumors in the future.

The researchers generated a PRAME-specific T cell bank from healthy donor cells and demonstrated anti-tumor cytolytic activity against tumor lines partially HLA-matched to the T cells and known to express PRAME. By using epitope mapping, they identified several novel epitopes restricted to MHC class I or MHC class II to further inform HLA matching.

“Defining PRAME-specific T cells beyond HLA epitopes could be useful when developing T-cell therapies for worldwide application,” Stanojevic et al. write. “Moreover, creating off-the-shelf products has many potential advantages since such products are readily available for the treatment of patients with aggressive disease or patients for whom an autologous product cannot be manufactured.”

Additional authors from Children’s National are Maja Stanojevic, M.D., Ashley Geiger, M.S., Samuel O’Brien, Robert Ulrey, M.S., Melanie Grant, Ph.D., Anushree Datar, M.S., Ping-Hsien Lee, Ph.D., Haili Lang, M.D., Conrad R.Y. Cruz, M.D., Ph.D.,  Patrick J. Hanley, Ph.D., A. John Barrett, M.D, Michael D. Keller, M.D., and Catherine M. Bollard, M.D., M.B.Ch.B.

Vote for STAT Madness

It’s a three-peat! Children’s National again competes in STAT Madness

Vote for STAT Madness

Children’s National Hospital collects patients’ blood, extracts T-cells and replicates them in the presence of specific proteins found on cancer cells which, in essence, teaches the T-cells to target specific tumor markers. Training the T-cells, growing them to sufficient quantities and ensuring they are safe for administration takes weeks. But when patients return to the outpatient clinic, their T-cell infusion lasts just a few minutes.

For the third consecutive year, Children’s National was selected to compete in STAT Madness, an annual bracket-style competition that chooses the year’s most impactful biomedical innovation by popular vote. Children’s entry, “Immunotherapy of relapsed and refractory solid tumors with ex vivo expanded multi-tumor associated antigen specific cytotoxic T lymphocytes,” uses the body’s own immune system to attack and eliminate cancer cells in pediatric and adult patients with solid tumor malignancies.

In 2018, Children’s first-ever STAT Madness entry advanced through five brackets in the national competition and, in the championship round, finished second. That innovation, which enables more timely diagnoses of rare diseases and common genetic disorders, helping to improve kids’ health outcomes around the world, also was among four “Editor’s Pick” finalists, entries that spanned a diverse range of scientific disciplines.

An estimated 11,000 new cases of pediatric cancer were diagnosed in children 14 and younger in the U.S. in 2019. And, when it comes to disease, cancer remains the leading cause of death among children, according to the National Institutes of Health. An enterprising research team led by Children’s National faculty leveraged T-cells – essential players in the body’s immune system – to treat pediatric and adult patients with relapsed or refractory solid tumors who had exhausted all other therapeutic options.

“We’re using the patient’s own immune system to fight their cancer, rather than more traditional chemotherapy drugs,” says Catherine M. Bollard, M.D., director of the Center for Cancer & Immunology Research at Children’s National and co-senior author of the study. “It’s more targeted and less toxic to the patient. These T-cells home in on any cancer cells that might be in the body, allowing healthy cells to continue to grow,” Dr. Bollard adds.

That means patients treated in the Phase I, first-in-human trial didn’t lose their hair and weren’t hospitalized for the treatment. After a quick clinical visit for their treatment, they returned to normal activities, like school, with good energy levels.

“With our specially trained T-cell therapy, many patients who previously had rapidly progressing disease experienced prolonged disease stabilization,” says Holly J. Meany, M.D., a Children’s National oncologist and the study’s co-senior author. “Patients treated at the highest dose level showed the best clinical outcomes, with a six-month, progression-free survival of 73% after tumor-associated antigen cytotoxic T-cell (TAA-T) infusion, compared with 38% with their immediate prior therapy.”

The multi-institutional team published their findings from the study online July 29, 2019, in the Journal of Clinical Oncology.

“Our research team and our parents are delighted that some patients treated in our study continue to do well following T-cell therapy without additional treatment. In some cases, two years after treatment, patients do not appear to have active disease and are maintaining an excellent quality of life,” says Amy B. Hont, M.D., the study’s lead author. “One of these was a patient whose parents were told his only other option was palliative care. Our innovation gives these families new hope,” Dr. Hont adds.

The 2020 STAT Madness #Core64 bracket opened March 2, and the champion will be announced April 6.

In addition to Drs. Hont, Meany and Bollard, Children’s National co-authors include C. Russell Cruz, M.D., Ph.D., Robert Ulrey, MS, Barbara O’Brien, BS, Maja Stanojevic, M.D., Anushree Datar, MS, Shuroug Albihani, MS, Devin Saunders, BA, Ryo Hanajiri, M.D., Ph.D., Karuna Panchapakesan, MS, Payal Banerjee, MS, Maria Fernanda Fortiz, BS, Fahmida Hoq, MBBS, MS, Haili Lang, M.D., Yunfei Wang, DrPH, Patrick J. Hanley, Ph.D., and Jeffrey S. Dome, M.D., Ph.D.; and Sam Darko, MS, National Institute of Allergy and Infectious Diseases.

Financial support for the research described in this post was provided by the Children’s National Hospital Heroes Gala, Alex’s Army Foundation, the Children’s National Board of Visitors and Hyundai Hope on Wheels Young Investigator Grant to Support Pediatric Cancer Research, the Children’s National Research Institute Bioinformatics Unit, the Clinical and Translational Science Institute and the National Institutes of Health under award No. UL1-TR001876.