In a paper published in the May 17, 2024, online issue of Cell, investigators from the Duke Human Vaccine Institute reported that a sequence of three immunizations in the HVTN-133 trial was sufficient for the development of heterologous or broadly neutralizing antibodies that protected against several strains of HIV.

The success of a vaccine, a gene editing design for an untreated disease, or achieving cell engraftment after several attempts, comes from years of accumulated basic science studies, thousands of experiments, and clinical trials. Innumerable steps precede hits in gene and cell therapies before a first-time revelation, and most of them are failures at the time. At the 27th Annual Meeting of the American Society of Gene & Cell Therapy (ASGCT) in Baltimore last week, several groups of scientists presented achievements that years ago looked impossible.

Immunotherapy-based cancer vaccines could permanently kill tumors by stimulating immune cells in multiple ways. At the 27th Annual Meeting of the American Society of Gene & Cell Therapy (ASGCT), researchers presented their advances in this field with different techniques in the scientific symposium “Novel nucleic acid and cell-based vaccines for cancer,” organized by the infectious diseases and vaccines committee.

From glaucoma to Stargardt disease, age-related macular degeneration (AMD) to retinitis pigmentosa, or a corneal transplant to Bietti’s crystalline dystrophy, the 27th Annual Meeting of the American Society of Gene & Cell Therapy (ASGCT) is working to bring some light to patients with age and congenital diseases that affect vision. From May 7-11, 2024, thousands of scientists are gathering in Baltimore to show their advances against the challenges of delivering genes and cells to the correct place, avoiding immunogenicity and improving diseases.

From glaucoma to Stargardt disease, age-related macular degeneration (AMD) to retinitis pigmentosa, or a corneal transplant to Bietti’s crystalline dystrophy, the 27th Annual Meeting of the American Society of Gene & Cell Therapy (ASGCT) is working to bring some light to patients with age and congenital diseases that affect vision. From May 7-11, 2024, thousands of scientists are gathering in Baltimore to show their advances against the challenges of delivering genes and cells to the correct place, avoiding immunogenicity and improving diseases.

“Prenatal therapies are the next disruptive technologies in health care, which will advance and shape the future of patient care in the 21st century,” said Graça Almeida-Porada, a professor at the Fetal Research and Therapy Center of the Wake Forest Institute for Regenerative Medicine in Winston-Salem, North Carolina. At the American Society of Gene & Cell Therapy (ASGCT) annual meeting in Baltimore on May 5, 2024, Almeida-Porada introduced the first presentation of the scientific symposium “Prospects for Prenatal Gene and Cell Therapy.”

Despite what University of Pennsylvania (Penn) immunotherapy pioneer Carl June referred to as a “cold slap last November” – a launched investigation by the U.S. FDA into a possible link between CAR T-cell immunotherapies and secondary cancers – new unpublished studies by Penn and Stanford University highlight the rarity of such cases.

Japanese researchers have transplanted human induced pluripotent stem cells (iPSCs) in a primate model of myocardial infarction and were able to restore heart muscle and function in monkeys. Developed by Tokyo-based Heartseed Inc., the grafted iPSCs consist of clusters of purified heart muscle cells (cardiomyocyte spheroids) that are injected into the myocardial layer of the heart. Published in Circulation on April 26, 2024, the study showed that the cardiomyocyte spheroids survived long term and showed improved contractile function with low occurrence of post-transplant arrhythmias.

Researchers have identified enzymes in gut microorganisms that could cleave A and B antigens from red blood, transmuting them to O negative cells.

Japanese researchers have transplanted human induced pluripotent stem cells (iPSCs) in a primate model of myocardial infarction and were able to restore heart muscle and function in monkeys. Developed by Tokyo-based Heartseed Inc., the grafted iPSCs consist of clusters of purified heart muscle cells (cardiomyocyte spheroids) that are injected into the myocardial layer of the heart. Published in Circulation on April 26, 2024, the study showed that the cardiomyocyte spheroids survived long term and showed improved contractile function with low occurrence of post-transplant arrhythmias.