 |
|
Marrow-derived stem cells deliver new cytokine to kill brain tumor cells, offer protection
March 01, 2006Attaching a recently discovered cytokine to neural stem cells derived from bone marrow, researchers at Cedars-Sinai Medical Center's Maxine Dunitz Neurosurgical Institute have developed a tool to track and kill malignant brain tumor cells and provide long-term protection against their return.
Results of an animal study are published in the March 1, 2006 issue of Cancer Research, and the researchers are now applying to regulatory agencies to translate their work into human clinical trials.
Gliomas are highly invasive tumors with poorly defined borders that intermingle with healthy brain tissue, making complete surgical removal nearly impossible. Furthermore, cells separate from the main tumor and migrate to form satellites that escape treatment and often lead to recurrence.
Researchers at the Maxine Dunitz Neurosurgical Institute documented several years ago that some neural stem cells - "immature" cells that can differentiate into central nervous system cells - have the ability to target and track glioma cells in the brain, even as they migrate. The researchers identified the mechanism that enables certain neural stem cells to develop this tracking ability and genetically engineered neural stem cells to transport several cytokines - proteins that regulate immune responses - to track down and destroy glioma cells.
In 2002, the scientists reported that they had produced central nervous system cells from stem cells derived from bone marrow. Because these stem cells originate in the bone marrow instead of the brain or fetal or embryonic tissue, there is an unlimited supply of cells that are free of ethical and tissue-rejection issues.
This study provides the first documentation that the marrow-derived stem cells possess the same tumor-tracking capability of other neural stem cells. It also includes the first report on the use of the cytokine interleukin-23 (IL-23) as a potential gene-delivered therapy against glioma.
"The paper recapitulates our previous data demonstrating that the neural stem cells - in this case from bone marrow - were able to track to the tumor very efficiently and, like a heat-seeking missile, deliver a killer depot," said John S. Yu, M.D., neurosurgeon, co-director of the Comprehensive Brain Tumor Program at the Maxine Dunitz Neurosurgical Institute, and the article's senior author. "We obtained the stem cells from bone marrow, mirroring what we want to do clinically, which is to take bone marrow cells from a patient, make them into neural stem cells, put in the gene of interest and treat the patient."
In this case, the gene of interest produces IL-23, which appears to be very well suited for attacking gliomas. Earlier studies used IL-4, IL-12, and tumor necrosis factor related apoptosis inducing ligand (TRAIL).
"Each cytokine has unique functions. What we want to do is marry the function with the therapeutic response we want to achieve. Interleukin-23 promotes the function of dendritic cells and memory T-cells, important components in an immune response to tumor cells. The earlier cytokines produced good results, but IL-23 is even more potent," Yu said.
"Most anti-tumor gene strategies attempt to deliver genes directly to tumor cells, but gliomas are especially challenging because of their highly invasive and migratory characteristics," said Keith L. Black, M.D., director of the Maxine Dunitz Neurosurgical Institute, director of Cedars-Sinai's Division of Neurosurgery, and co-director of the Comprehensive Brain Tumor Program. "By combining the tumor-tracking properties of bone marrow-derived neural stem cells with interleukin-23, we are able to initiate a very powerful anti-tumor response that tracks to migrating glioma islands and offers long-term protection - all of which would make this a very attractive therapeutic option."
In the animal study, bone marrow-derived neural stem-like cells (BM-NSC) genetically engineered to produce IL-23 were injected into intracranial gliomas and other areas of the brain. Treated animals survived significantly longer than those in control groups. In fact, of those receiving BM-NSC-IL-23, 60 percent survived beyond day 120 tumor-free. Only 20 percent of those treated with IL-23 that was not attached to neural stem cells survived, and no animals survived if they received neural stem cells without IL-23.
Even after additional glioma cells were injected, BM-NSC-IL-23-treated animals remained tumor free, evidence of the long-term immunity provided by IL-23's generation of memory T-cells.
Cedars-Sinai Medical Center
Researchers at the Maxine Dunitz Neurosurgical Institute documented several years ago that some neural stem cells - "immature" cells that can differentiate into central nervous system cells - have the ability to target and track glioma cells in the brain, even as they migrate. The researchers identified the mechanism that enables certain neural stem cells to develop this tracking ability and genetically engineered neural stem cells to transport several cytokines - proteins that regulate immune responses - to track down and destroy glioma cells.
In 2002, the scientists reported that they had produced central nervous system cells from stem cells derived from bone marrow. Because these stem cells originate in the bone marrow instead of the brain or fetal or embryonic tissue, there is an unlimited supply of cells that are free of ethical and tissue-rejection issues.
This study provides the first documentation that the marrow-derived stem cells possess the same tumor-tracking capability of other neural stem cells. It also includes the first report on the use of the cytokine interleukin-23 (IL-23) as a potential gene-delivered therapy against glioma.
"The paper recapitulates our previous data demonstrating that the neural stem cells - in this case from bone marrow - were able to track to the tumor very efficiently and, like a heat-seeking missile, deliver a killer depot," said John S. Yu, M.D., neurosurgeon, co-director of the Comprehensive Brain Tumor Program at the Maxine Dunitz Neurosurgical Institute, and the article's senior author. "We obtained the stem cells from bone marrow, mirroring what we want to do clinically, which is to take bone marrow cells from a patient, make them into neural stem cells, put in the gene of interest and treat the patient."
In this case, the gene of interest produces IL-23, which appears to be very well suited for attacking gliomas. Earlier studies used IL-4, IL-12, and tumor necrosis factor related apoptosis inducing ligand (TRAIL).
"Each cytokine has unique functions. What we want to do is marry the function with the therapeutic response we want to achieve. Interleukin-23 promotes the function of dendritic cells and memory T-cells, important components in an immune response to tumor cells. The earlier cytokines produced good results, but IL-23 is even more potent," Yu said.
"Most anti-tumor gene strategies attempt to deliver genes directly to tumor cells, but gliomas are especially challenging because of their highly invasive and migratory characteristics," said Keith L. Black, M.D., director of the Maxine Dunitz Neurosurgical Institute, director of Cedars-Sinai's Division of Neurosurgery, and co-director of the Comprehensive Brain Tumor Program. "By combining the tumor-tracking properties of bone marrow-derived neural stem cells with interleukin-23, we are able to initiate a very powerful anti-tumor response that tracks to migrating glioma islands and offers long-term protection - all of which would make this a very attractive therapeutic option."
In the animal study, bone marrow-derived neural stem-like cells (BM-NSC) genetically engineered to produce IL-23 were injected into intracranial gliomas and other areas of the brain. Treated animals survived significantly longer than those in control groups. In fact, of those receiving BM-NSC-IL-23, 60 percent survived beyond day 120 tumor-free. Only 20 percent of those treated with IL-23 that was not attached to neural stem cells survived, and no animals survived if they received neural stem cells without IL-23.
Even after additional glioma cells were injected, BM-NSC-IL-23-treated animals remained tumor free, evidence of the long-term immunity provided by IL-23's generation of memory T-cells.
Cedars-Sinai Medical Center
Brain Tumor Cells Current Events and Brain Tumor Cells News RSSWhy don't brain tumors respond to medication?
Malignant brain tumors often fail to respond to promising new medication. Researchers in Heidelberg have discovered a mechanism and a tumor marker for the development of this resistance.
NIH researchers identify key factor that stimulates brain cancer cells to spread
Researchers funded by the National Institutes of Health have found that the activity of a protein in brain cells helps stimulate the spread of an aggressive brain cancer called glioblastoma multiforme (GBM).
Antibody targeting of glioblastoma shows promise in preclinical tests, say Lombardi researchers
Cancer researchers at Georgetown University's Lombardi Comprehensive Cancer Center have successfully tested a small, engineered antibody they say shuts down growth of human glioblastoma tumors in cell and animal studies. Glioblastoma is the deadliest of brain cancers; there is no effective treatment.
St. Jude scientists discover a new mechanism controlling neuronal migration
The molecular machinery that helps brain cells migrate to their correct place in the developing brain has been identified by scientists at St. Jude Children's Research Hospital.
Stealthy gene network makes brain tumors flourish
The brain tumor afflicting Sen. Edward Kennedy - a glioblastoma - is the most aggressive and wily form of brain cancer.
Remote-control closed system invented for inserting radio-active atoms inside fullerenes
Virginia Tech chemistry Professor Harry C. Dorn, Emory and Henry College chemistry Professor James Duchamp, and Panos Fatouros, professor and chair of the Division of Radiation Physics and Biology at the Virginia Commonwealth University School of Medicine have co-invented a hands-off process for filling fullerenes with radio-active material.
Lithium may help radiation target cancer, spare healthy tissue
Vanderbilt-Ingram Cancer Center investigators have uncovered a mechanism that helps explain how lithium, a drug widely used to treat bipolar mood disorder, also protects the brain from damage that occurs during radiation treatments.
Reversing effects of altered enzyme may fight brain tumor growth
An international team of scientists from the Moores Cancer Center at the University of California, San Diego, the University of North Carolina and several institutions in China have explained how a gene alteration can lead to the development of a type of brain cancer, and they have identified a compound that could staunch the cancer's growth.
UC Davis researchers find molecule that targets brain tumors
UC Davis Cancer Center researchers report today the discovery of a molecule that targets glioblastoma, a highly deadly form of cancer. The finding, which is published in the January 2009 issue of the European Journal of Nuclear Medicine and Molecular Imaging, provides hope for effectively treating an incurable cancer.
Research suggests new treatment suitable for all patients
New research at Wake Forest University Baptist Medical Center suggests that a three-drug cocktail may one day improve outcomes in patients with glioblastoma multiforme (GBM), a type of brain tumor with a dismal prognosis.
More Brain Tumor Cells Current Events and Brain Tumor Cells News Articles
 |
Molecular Makers of Brain Tumor Cells by Bela Bodey (Author), Stuart E. Siegel (Author), Hans E. Kaiser (Author) I. MOLECULAR BIOLOGY OF TUMORS. 1. Brain Tumors 1. Introduction 2. Medulloblastoma 3. Glial Tumors 2. Immunophenotypic Characterization of Infiltrating Poly- and Mononuclear Cells in Childhood Brain Tumors 1. Introduction 2. The Significance of Immunohistochemistry 3. Original Immunohistochemical Observations 4. Intermediate filaments (IFs) 5. Expression of Homeobox B3, B4, and C6 Gene Products 6. Cell proliferation 7. Epidermal growth factor (EGF) and its receptor (EGFR) 8. p53, the guardian of the integrity of the genome 9. Apoptosis in Brain Tumors 10. Survivin 11. Tumor-related Neoangiogenesis in Childhood Brain Tumors 12. Presence of... |
 |
Mobile Starring: Keith Allen, Julie Graham, Michael Kitchen, Samantha Bond, Jamie Draven Directed By: Stuart Orme Conspiracy, betrayal, and revenge in the global telecom industry Someone is blowing up mobile-phone towers across England. Messages scrawled in blood-red paint at the scenes proclaim that mobile phones are the instruments of the devil. What’s more, a gunman -- or gunmen -- is shooting cell phone users in mid-conversation. Baffled police investigators scramble to avert public panic. In four interlocking parts, this tense drama peels back the layers of a terrorist conspiracy, gradually revealing the evil at its core. We follow three characters -- a disgraced telecom executive (Michael Kitchen, Foyle’s War), a bitter ex-soldier (Jamie Draven, Billy Elliot), and a disgruntled engineer (Neil Fitzmaurice, Going Off Big Time) -- all united by circumstance or collusion. In a style... |
 |
Bioelectric Shield Polishing Kit by BioelectriCo Bioelectric Shield Polishing Kit - Cleaning Your Shield - This is the perfect cloth for cleaning your new health investment of a Bioelectric Shield. One side of the cloth has a special moisturizer in the fibers, and the other side is dry and ready for the final polish! Handcrafted in Montana, these EMF shields are carefully designed using standards that insure quality, durability and lasting use. Each shield measures 1 1/8 inch in diameter and weighs 1/2 oz. When you wear a Shield, you can be more balanced, and bring your balance and well-being to the world around you. CHARGING YOUR SHIELD: Once a month, hang your Shield in natural light either in a window, or preferably outside. Just loop the cord or chain over a lawn chair or the front gate, etc. This allows it to hang freely and absorb... |
 |
Intracranial Germ Cell Tumors by Yutaka Sawamura (Editor), Hiroki Shirato (Editor), Nicolas de Tribolet (Editor) Intracranial germ cell tumors are a group of uncommon neoplasms of the central nervous system. The clinical features and natural history of these lesions are quite unique and variable. While intracranial germ cell tumors have been a fascination to neurooncologists for decades, the relatively small number of patients seen in any single institution has hampered the important clinical investigation that is so needed. This text is complete with detailed information concerning the epidemiology, pathology, oncological biology, clinical findings, radiology, and treatment options including surgical strategy, radiotherapy, and chemotherapy for this heterogeneous group of neoplasms. The ongoing clinical trials concerning the optimization of therapy are efficiently summarized. An ... |
|
State of stem: prop. 71 funding spurs range of activity on cell frontier.(Stem Cell Research--Under the Microscope): An article from: Los Angeles Business Journal by Laurence Darmiento (Author) This digital document is an article from Los Angeles Business Journal, published by CBJ, L.P. on January 31, 2005. The length of the article is 2436 words. The page length shown above is based on a typical 300-word page. 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. Citation Details Title: State of stem: prop. 71 funding spurs range of activity on cell frontier.(Stem Cell Research--Under the Microscope) Author: Laurence Darmiento Publication: Los Angeles Business Journal (Magazine/Journal) Date: January 31, 2005 Publisher: CBJ, L.P. Volume: 27 Issue: 5 Page: 1(4) Distributed by Thomson... | |
|
Stem cells and cancer.(Announcements / Fellowships, Grants, & Awards): An article from: Environmental Health Perspectives by National Institute of Environmental Health Sciences (Publisher) This digital document is an article from Environmental Health Perspectives, published by National Institute of Environmental Health Sciences on July 1, 2005. The length of the article is 1913 words. The page length shown above is based on a typical 300-word page. 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. Citation Details Title: Stem cells and cancer.(Announcements / Fellowships, Grants, & Awards) Publication: Environmental Health Perspectives (Magazine/Journal) Date: July 1, 2005 Publisher: National Institute of Environmental Health Sciences Volume: 113 Issue: 7 Page: A476(2) Distributed by Thomson... | |
|
To call or not to call? The ongoing cell phone safety debate.(Your Health): An article from: E by Erika Alexia Tsoukanelis (Author) This digital document is an article from E, published by Earth Action Network, Inc. on November 1, 2008. The length of the article is 863 words. The page length shown above is based on a typical 300-word page. The article is delivered in HTML format and is available immediately after purchase. You can view it with any web browser. Citation Details Title: To call or not to call? The ongoing cell phone safety debate.(Your Health) Author: Erika Alexia Tsoukanelis Publication: E (Magazine/Journal) Date: November 1, 2008 Publisher: Earth Action Network, Inc. Volume: 19 Issue: 6 Page: 40(2) Distributed by Gale, a part of Cengage... | |
 |
Cancer Stem Cells: Methods and Protocols (Methods in Molecular Biology) by John S. Yu (Editor) Through the revolutionary concept of cancer stem cells, cancer research has been reinvigorated to study the role of these unique cells in cancer propagation and as targets of innovative therapies. In Cancer Stem Cells: Methods and Protocols, preeminent researchers have compiled cancer stem cell research techniques and protocols to promote healthy competition, discourse, and collaboration in this vital field. The volume covers extensive topics such as identification and isolation of cancer stem cells, animal models of cancer stem cells, methylation profiling, the contribution of the niche in the regulation of cancer stem cells, immunologic targeting, and the use of normal stem cells as a treatment, among other subjects. Written in the highly successful Methods in Molecular Biology™... |
|
Proton MR Spectroscopy of the Brain (Neuroimaging Clinics of North America) (Volume 8 Number 4 November 1998) by W.B. Saunders Company (Publisher) | |
|
Breaking down barriers to treat a patient with a germinoma: a case study.: An article from: Journal of Neuroscience Nursing by Susan Bell (Author) This digital document is an article from Journal of Neuroscience Nursing, published by American Association of Neuroscience Nurses on August 1, 2004. The length of the article is 2759 words. The page length shown above is based on a typical 300-word page. 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. Citation Details Title: Breaking down barriers to treat a patient with a germinoma: a case study. Author: Susan Bell Publication: Journal of Neuroscience Nursing (Refereed) Date: August 1, 2004 Publisher: American Association of Neuroscience Nurses Volume: 36 Issue: 4 Page: 195(5) Distributed by Thomson... |
| © 2009 BrightSurf.com |