XML Feed for RxPG News   Add RxPG News Headlines to My Yahoo!   Javascript Syndication for RxPG News

Research Health World General
 
  Home
 
 Latest Research
 Cancer
  Breast
  Skin
  Blood
  Prostate
  Liver
  Colon
  Thyroid
  Endometrial
  Brain
   Glioblastoma Multiforme
   Medulloblastoma
  Therapy
  Risk Factors
  Esophageal
  Bladder
  Lung
  Rectal Cancer
  Pancreatic Cancer
  Bone Cancer
  Cervical Cancer
  Testicular Cancer
  Gastric Cancer
  Ovarian Cancer
  Nerve Tissue
  Renal Cell Carcinoma
 Psychiatry
 Genetics
 Surgery
 Aging
 Ophthalmology
 Gynaecology
 Neurosciences
 Pharmacology
 Cardiology
 Obstetrics
 Infectious Diseases
 Respiratory Medicine
 Pathology
 Endocrinology
 Immunology
 Nephrology
 Gastroenterology
 Biotechnology
 Radiology
 Dermatology
 Microbiology
 Haematology
 Dental
 ENT
 Environment
 Embryology
 Orthopedics
 Metabolism
 Anaethesia
 Paediatrics
 Public Health
 Urology
 Musculoskeletal
 Clinical Trials
 Physiology
 Biochemistry
 Cytology
 Traumatology
 Rheumatology
 
 Medical News
 Health
 Opinion
 Healthcare
 Professionals
 Launch
 Awards & Prizes
 
 Careers
 Medical
 Nursing
 Dental
 
 Special Topics
 Euthanasia
 Ethics
 Evolution
 Odd Medical News
 Feature
 
 World News
 Tsunami
 Epidemics
 Climate
 Business
 
 India
Search

Last Updated: Nov 18, 2006 - 12:32:53 PM

Brain Channel
subscribe to Brain newsletter

Latest Research : Cancer : Brain

   DISCUSS   |   EMAIL   |   PRINT
Vaccine to target resistance-related antigen in Brain tumours
Jun 14, 2005 - 6:24:00 AM, Reviewed by: Dr.

"Based on our results, it appears that we can improve chemotherapy sensitivity by targeting TRP-2 and possibly other drug-resistant related tumor antigens. This may be a significant step in the fight against brain tumors and other malignant cancers because even as we have been able to develop very powerful and targeted chemicals, tumors have often been able to outmaneuver them,"

 
In the August issue of the journal Oncogene, researchers at Cedars-Sinai Medical Center's Maxine Dunitz Neurosurgical Institute describe a molecular mechanism that appears to make malignant brain tumors more vulnerable to chemotherapy after they have been treated with the dendritic cell vaccine.

This finding builds on several studies recently published by the research team. In 2003, they reported that a protein fragment previously found in melanomas also was detected in highly aggressive brain tumors called glioblastoma multiforme (GBM). The immune system recognizes the peptide, Tyrosinase-Related Protein (TRP)-2, as a foreign invader, making it a significant target for immunotherapy.

"Our findings suggest that TRP-2 could be a powerful molecule linking chemotherapy and immunotherapy," said Keith L. Black, M.D, one of the paper's authors, director of the Maxine Dunitz Neurosurgical Institute and director of the medical center's Division of Neurosurgery and Comprehensive Brain Tumor Program.

"Based on our results, it appears that we can improve chemotherapy sensitivity by targeting TRP-2 and possibly other drug-resistant related tumor antigens. This may be a significant step in the fight against brain tumors and other malignant cancers because even as we have been able to develop very powerful and targeted chemicals, tumors have often been able to outmaneuver them," said Black.

In 2004, the researchers documented that the combination of immunotherapy and chemotherapy significantly slowed tumor progression and extended survival of patients suffering from these deadly tumors. The two therapies together were able to accomplish results that neither could achieve by itself. The average length of survival was extended to about 26 months, compared to 18 months for patients who received vaccine alone and 16 months for those undergoing chemotherapy alone.

In a number of laboratory and clinical trials, dendritic cell immunotherapy had succeeded in eliciting a powerful immune response against brain tumor cells, but significant improvements in length of survival had not been realized. One theory is that the rate at which tumor cells die is too slow to keep pace with the rapid growth and mutation of tumors in the body. Similarly, chemotherapy directed against GBM has had very little effect. Even new agents specifically designed to attack the DNA of tumor cells and prevent their replication fail or became impotent as the tumor cells developed drug resistance.

Taking into account recent articles identifying TRP-2 as a contributing factor in the ability of tumor cells to mutate and resist a variety of therapeutic drugs, the Cedars-Sinai team now offers an explanation for the relative effectiveness of this two-wave, vaccine-chemotherapy assault. The first attack comes from the dendritic cell vaccine that is specially formulated to search and destroy tumor cells that contain TRP-2. It clearly launches "cytotoxic T lymphocytes," tumor cell-killing immune cells that diminish or deplete the number of TRP-2-containing tumor cells. Other GBM cells survive, however, and continue to proliferate. But because they lack TRP-2 and therefore the ability to develop drug resistance, they are vulnerable in the follow-up assault of chemicals targeting their DNA.

John S. Yu, M.D., senior author of the paper and co-director of the Comprehensive Brain Tumor Program, said lab results confirmed a strong immune response to TRP-2 in patients' blood cells after vaccination, and cells removed from tumors after vaccination had significantly lower TRP-2 expression than did those removed earlier. Furthermore, the post-vaccine tumor cells were much more sensitive to anti-tumor drugs.

"It is important to note also that four patients in our study that demonstrated a response to TRP-2, after tumor recurrence, responded to chemotherapy with what oncologists call complete responses, which means the tumors were no longer visible on MRI," he added. "This was a small initial study and it will be very interesting to see if similar results will be repeated in larger numbers." Dendritic cell vaccination, pioneered at Cedars-Sinai in the treatment of GBM, introduces foreign proteins from surgically removed tumors to dendritic cells, which are also called antigen-presenting cells because they identify foreign material for destruction by cell-killing T lymphocytes. The tumor cells are cultured with the dendritic cells in the laboratory to enable the immune cells to recognize cancer cells as targets. When the resulting "specialized" dendritic cells are injected back into the patient, they seek out remaining tumor cells and signal for the T lymphocytes to destroy them.
 

- August issue of the journal Oncogene
 

www.csmc.edu

 
Subscribe to Brain Newsletter
E-mail Address:

 

This study was supported in part by NIH grant K23 NS02232.

One of only five hospitals in California whose nurses have been honored with the prestigious Magnet designation, Cedars-Sinai Medical Center is one of the largest nonprofit academic medical centers in the Western United States. For 17 consecutive years, it has been named Los Angeles' most preferred hospital for all health needs in an independent survey of area residents. Cedars-Sinai is internationally renowned for its diagnostic and treatment capabilities and its broad spectrum of programs and services, as well as breakthroughs in biomedical research and superlative medical education. It ranks among the top 10 non-university hospitals in the nation for its research activities and was recently fully accredited by the Association for the Accreditation of Human Research Protection Programs, Inc. (AAHRPP). Additional information is available at www.cedars-sinai.edu.


Related Brain News

Regulatory Approval for New Cotara(R) Brain Cancer Clinical Trial
Lead exposure linked with brain cancer
Synthetic scorpion venom delivers radioactive iodine to malignant gliomas
Chromosomal Testing Can Determine Brain Tumor Therapy
Motexafin gadolinium extends cognitive function in patients with brain metastases
New vaccine to fight glioblastoma multiforme developed
New mouse model that closely mimics human medulloblastoma
Immune response protects against brain tumor development
Long mobile use could cause brain tumours - New Study
Donepezil helps cognitive function in brain tumor patients after radiation


For any corrections of factual information, to contact the editors or to send any medical news or health news press releases, use feedback form

Top of Page

 

© Copyright 2004 onwards by RxPG Medical Solutions Private Limited
Contact Us