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Rapid restoration of immunity in immune-suppressed cancer patients using T-cell vaccines
October 21, 2005Novel approach reduces the time to achieve protective levels of immunity in myeloma patients by nearly one year
(Philadelphia, PA)-Patients with multiple myeloma suffer from a malignant proliferation of plasma cells in their bone marrow. The standard treatment for this form of cancer is high-dose chemotherapy and transplantation of one's own blood-producing adult stem cells; however, this aggressive treatment wipes out the mature immune-system cells of patients - leaving them vulnerable to infection.
A complementary treatment currently approved is to vaccinate myeloma patients against pneumococcus, a common bacterial infection, a year after their transplantation. But why wait a year, wondered researchers at the University of Pennsylvania School of Medicine? Their own investigation revealed that protective levels of immunity against pneumococcus could be obtained in patients who were given the prophylactic bacterial vaccine in addition to a new autologous T-cell-based vaccine only two weeks after transplantation. Indeed, protection developed in the patients within a month after the transplantation. Their clinical trial is described in this week's online edition of Nature Medicine.
"We found that we can rapidly rebuild the patients' immunity after chemotherapy and stem-cell transplant," said Carl June, MD, Director of Translational Research at Penn's Abramson Cancer Center. "For future studies, we will apply the principles learned from this study to hone the development of a cancer vaccine aimed directly at tumors and other cancers," added June, who is also Professor of Pathology and Laboratory Medicine in Penn's School of Medicine.
Early Measures Prove Highly Effective
Patients in the study were all given two pneumococcal vaccines one month and three months after their stem-cell transplants; whereas normally they would have to wait up to a year. The patients were then divided into four groups: one group received an initial pneumococcal vaccine before transplantation and chemotherapy, then a T-cell vaccine immediately after; a second group received the pneumococcal vaccine before transplantation and chemotherapy, but received the T-cell vaccine three months after their transplant and chemotherapy. The last pair of groups did not get the initial pneumococcal vaccine before the standard transplant and chemotherapy, but did receive the T-cell vaccine immediately after or three months after the standard treatment.
The researchers found that the patients in the group that received the early pneumococcal vaccine plus the early T-cell vaccine infusion had an immune response that was protective and higher than often achieved in normal patients who do not have cancer.
Custom-Designed T-Cell Therapies Will Enhance Immunity
At the recently opened Clinical Cell and Vaccine Production Facility at Penn, "we have been using new cell-based custom therapeutics derived from a patient's own T cells in this and other studies, with the long term goal of improving outcome and extending life," explains co-author Bruce Levine, PhD, who directs the Facility. T-cells are taken from a patient and expanded about a thousand fold. The engineered T-cells are then given back to the patient a few weeks later via an infusion. The newly grown T cells continue to grow in the patient, which is different than a red blood cell transfusion. The effect of this therapy is to quickly repopulate a patient's immune system with mature cells that can support immunity against infections, and potentially against tumors.
"This study showed how to take a vaccine that is a failure in people after chemotherapy and to modify it so that it works in cancer patients after chemotherapy," says June. "The surprising thing is that the vaccine works better than normal in many of the patients. This is the first step in developing a new form of personalized therapy for the treatment of cancer, where engineered T-cells will be used to boost the immune system, essentially priming it to make cancer vaccines work better."
In addition to June and Levine, study co-authors include Edward Stadtmauer from Penn and Aaron Rapoport and Alan Cross, University of Maryland.
University of Pennsylvania School of Medicine
"We found that we can rapidly rebuild the patients' immunity after chemotherapy and stem-cell transplant," said Carl June, MD, Director of Translational Research at Penn's Abramson Cancer Center. "For future studies, we will apply the principles learned from this study to hone the development of a cancer vaccine aimed directly at tumors and other cancers," added June, who is also Professor of Pathology and Laboratory Medicine in Penn's School of Medicine.
Early Measures Prove Highly Effective
Patients in the study were all given two pneumococcal vaccines one month and three months after their stem-cell transplants; whereas normally they would have to wait up to a year. The patients were then divided into four groups: one group received an initial pneumococcal vaccine before transplantation and chemotherapy, then a T-cell vaccine immediately after; a second group received the pneumococcal vaccine before transplantation and chemotherapy, but received the T-cell vaccine three months after their transplant and chemotherapy. The last pair of groups did not get the initial pneumococcal vaccine before the standard transplant and chemotherapy, but did receive the T-cell vaccine immediately after or three months after the standard treatment.
The researchers found that the patients in the group that received the early pneumococcal vaccine plus the early T-cell vaccine infusion had an immune response that was protective and higher than often achieved in normal patients who do not have cancer.
Custom-Designed T-Cell Therapies Will Enhance Immunity
At the recently opened Clinical Cell and Vaccine Production Facility at Penn, "we have been using new cell-based custom therapeutics derived from a patient's own T cells in this and other studies, with the long term goal of improving outcome and extending life," explains co-author Bruce Levine, PhD, who directs the Facility. T-cells are taken from a patient and expanded about a thousand fold. The engineered T-cells are then given back to the patient a few weeks later via an infusion. The newly grown T cells continue to grow in the patient, which is different than a red blood cell transfusion. The effect of this therapy is to quickly repopulate a patient's immune system with mature cells that can support immunity against infections, and potentially against tumors.
"This study showed how to take a vaccine that is a failure in people after chemotherapy and to modify it so that it works in cancer patients after chemotherapy," says June. "The surprising thing is that the vaccine works better than normal in many of the patients. This is the first step in developing a new form of personalized therapy for the treatment of cancer, where engineered T-cells will be used to boost the immune system, essentially priming it to make cancer vaccines work better."
In addition to June and Levine, study co-authors include Edward Stadtmauer from Penn and Aaron Rapoport and Alan Cross, University of Maryland.
University of Pennsylvania School of Medicine
Results of landmark study of HIV vaccine published in the Lancet
Results from the Step study, a test-of-concept efficacy study of a Merck & Co., Inc. HIV vaccine candidate, were published online today in two papers in The Lancet. These analyses of the Step study are being conducted, presented and published to inform the continued search for an effective HIV vaccine.
NIAID describes challenges, prospects for an HIV vaccine
Events of the past year in HIV vaccine research have led some to question whether an effective HIV vaccine will ever be developed. In the August 28 edition of the New England Journal of Medicine, officials from the National Institute of Allergy and Infectious Diseases (NIAID), part of the National Institutes of Health, examine the extraordinarily challenging properties of the virus that have made a vaccine elusive and outline the scientific questions that, if answered, could lead to an effective HIV vaccine.
AIDS vaccine research offers new insights on survival
New insights into how a subpopulation of helper T-cells provides immunity and promotes survival following infection with an AIDS-like virus offer a new means of predicting an AIDS vaccine's effectiveness, a discovery that could help scientists as they test these vaccines in clinical trials.
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Animal Cell Technology: From Vaccines to Genetic Medicine by Manuel J.T. Carrondo (Editor), Bryan Griffiths (Editor), José L.P. Moreira (Editor) Animal cell technology has undergone a rapid transformation over the last decade from a research tool and highly specialised technology to a central resource for innovation in pharmaceutical research and development. These proceedings of the 14th Meeting of the European Society for Animal Cell Technology (Vilamoura, Portugal, May 1996) bring up to date the historical perspective of animal cell technology for the benefit of society, `From Vaccines to Genetic Medicine', and will charter this vital technology for the years to come. Strong contributions are grouped in the traditional ESACT areas of 'Cell and Physiology Engineering' dealing with cell state, including genetics, and its environment, and 'Animal Cell Process Engineering' covering integration of bioreaction with... |
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Teaching About Immunity Kit by American Educational Products This kit clearly displays the interrelated workings of the Immunity System. Attack an invading anigen with a phagocyte or monbyte. Produce macrophages. T-Cells, B-Cells, Plasma Cells, and antibodies. Clone T and B cells to produce Helper, Killer, Memory and Suppression cells. Demonstrate the operation of AIDS, Cancer, Vaccines, Allergies, Autoimmune reactions and more right on the board. Students can readily participate in the "hands on" activities. The Plastick pieces will not break, chip, tear, peel or wear out! Comes complete with a 30" X 40" Demonstration Board, mounting legs, and Teacher's Guide with detailed lesson plans plus reproducible student worksheets. |
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Cancer Vaccines Zeroing in on the Cancer Cell by Lowell T. Harmison (Author), Kenichiro Hasumi (Author) The book best written about cancer vaccine for both medical professionals and cancer patients. This book is about cancer vaccines for patients, their families and physicians and the opportunity they offer to improve the cancer treatment. The results of the research conducted by scientists worldwide to date are promising enough to justify our hope that this book will open your door to cancer vaccines. This book is about a vision for the future; it is about the possibility of a better quality of life for people with cancer. And it is a book about how vaccines can be used to help treat and, hopefully one day, help cure or even prevent cancer. In short, this book seeks to open the door to cancer vaccines as we zero in on the cancer cell. | |
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AIDS, RECENT ADVANCES IN RESEARCH AND TREATMENT: An entry from Gale's World of Microbiology and Immunology by Gale (Publisher) This digital document is an article from World of Microbiology and Immunology, brought to you by Gale®, a part of Cengage Learning, a world leader in e-research and educational publishing for libraries, schools and businesses. The length of the article is 883 words. The article is delivered in HTML format and is available in your Amazon.com Digital Locker immediately after purchase. You can view it with any web browser. Covers the concepts, theories, discoveries, and pioneers in microbiology and immunology, using a mix of traditional academic and topical articles, this title addresses current ethical, legal, and social issues with special emphasis given to biological warfare and terrorism. |
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