Posts tagged brain cancer

A polymer originally designed to help mend broken bones could be successful in delivering chemotherapy drugs directly to the brains of patients suffering from brain tumours, researchers at The University of Nottingham have discovered.

Their study, published in the journal PLOS ONE, shows that the biomaterial can be easily applied to the cavity created following brain cancer surgery and used to release chemotherapy drugs over several weeks.

The targeted nature of the therapy could also reduce the toxic effects of chemotherapy drugs on healthy parts of the body, potentially reducing the debilitating side-effects that many patients experience after cancer treatment.

Patient survival

Dr Ruman Rahman, of the University’s Children’s Brain Tumour Research Centre (CBTRC), who led the study, said: “Our system is an innovative method of drug delivery for the treatment of brain tumours and is intended to be administered immediately after surgery by the operating neurosurgeon.

“Ultimately, this method of drug delivery, in combination with existing therapies, may result in more effective treatment of brain tumours, prolonged patient survival and reduced morbidity.”

Brain tumours are the major cause of cancer-related death in children and adults up to the age of 40. Most relapses occur when surgeons are unable to remove all of the cancerous cells during surgery – something which can be particularly challenging in very young children and babies and by the very nature of a type of adult brain cancer called glioblastoma.

Although alternative systems for delivery of drugs directly to the brain have been developed, they are used infrequently because their success has been limited. This new drug delivery system is the first that can be moulded to the shape of the brain tumour cavity and the first to deliver several different drugs over a clinically meaningful period of time.

The Nottingham polymer formulation is made from two types of micro-particles called PLGA and PEG and has been developed and patented by leading tissue engineer Professor Kevin Shakesheff, based in the University’s School of Pharmacy. A powder at room temperature, it can be mixed to a toothpaste-like consistency with the addition of water.

Unique properties

The unique properties of the polymer lie in its ability to set into a rigid structure only when it reaches body temperature (37 degrees), a feature perfectly tailored for use in medical therapies. It was originally developed as a scaffold on to which new bone cells could be grown to speed up the knitting back together of broken bones.

Dr Ruman Rahman at the CBTRC and Dr Cheryl Rahman from the School of Pharmacy spotted the potential for the polymer to deliver chemotherapy drugs directly to patients’ brain tumours. The work was performed at the CBTRC with neurosurgeon Mr Stuart Smith and neuro-oncologist Professor Richard Grundy. The cavity left by the removal of a tumour would be lined with the polymer while in paste form, which would start to solidify and gradually release the chemotherapy drugs after the incision has been closed. This would directly target any residual cells not initially removed during surgery.

In the lab, the Nottingham scientists were able to successfully demonstrate the slow-release properties of the material by placing paste loaded with three commonly used chemotherapy drugs into a solution of saline and measuring the quantities of the drugs given out by the material over time.

To establish whether the material itself is safe to use on patients in this form of therapy, they used it to create a 3D model onto which they were able to grow brain tumour cells and healthy brain blood vessel cells without any toxicity. They then simulated surgery on a sheep’s brain from an abattoir by moulding the paste around a brain cavity and warming the brain to human body temperature to harden the polymer.

The brain was then scanned using CT and MRI technology to demonstrate that it is still possible to distinguish the polymer from normal brain tissue on a routine brain scan, an aspect crucial for doctors when dealing with follow-up care for brain tumour patients who have undergone surgery.

Robust material

The team also dealt with concerns that the material could disintegrate and release its chemotherapy contents too quickly during the subsequent radiotherapy which many cancer patients undergo following surgery. By placing the biomaterial loaded with chemotherapy drugs into a head cavity of a medical training dummy and subjecting it to the same duration and intensity of radiotherapy used for brain tumour patients they were able to successfully demonstrate the robust integrity of the structure.

Finally they showed that a chemotherapy drug called etoposide could be effective at killing brain cancer cells in a mouse when released from the polymer formulation. The next stage of the research will be to extend the study in mice with brain tumours to test whether animals with the drug-loaded polymers survive longer. The team are also investigating the release of other chemotherapeutic drugs that hold promise, supported by a recent grant award from Sparks.

As the research used a biomaterial and chemotherapy drugs already approved for medical use, many of the usual ethical approval hurdles to allow further investigation have already been cleared.

The first clinical test, anticipated in 3 years’ time, will be to devise a multi-centre phase 0 clinical trial which would involve testing the therapy on a small number of patients for whom other clinical treatments have not been successful and would otherwise only be offered palliative care.

“This is a very exciting development and holds considerable promise for the treatment of malignant brain tumours in the near future” commented Professor Grundy, Co-Director of the CBTRC.

(Source: nottingham.ac.uk)

Gene regulation technology increases survival rates in mice with glioblastoma

(Source: northwestern.edu)

Project delves deeply in genomics of 599 glioblastoma multiforme cases to better target disease

When The Cancer Genome Atlas launched its massively collaborative approach to organ-by-organ genomic analysis of cancers, the brain had both the benefit, and the challenge, of going first.

TCGA ganged up on glioblastoma multiforme (GBM), the most common and lethal of brain tumors, with more than 100 scientists from 14 institutions tracking down the genomic abnormalities that drive GBM.

Five years later, older and wiser, TCGA revisited glioblastoma, producing a broader, deeper picture of the drivers – and potential therapeutic targets – of the disease published in the Oct. 10 issue of Cell.

“The first paper in 2008 characterized glioblastoma in important new ways and illuminated the path for all TCGA organ studies that have followed,” said senior author Lynda Chin, M.D., professor and chair of Genomic Medicine and scientific director of the Institute for Applied Cancer Science at The University of Texas MD Anderson Cancer Center.

“Our new study reflects major improvements in technology applied to many more tumor samples to more completely characterize the landscape of genomic alterations in glioblastoma,” said Chin, who was also co-senior author of the first paper while she was on the faculty of Dana-Farber Cancer Institute in Boston.

“Information generated by this unbiased, data-driven analysis presents new opportunities to discover genomics-based biomarkers, understand disease mechanisms and generate new hypotheses to develop better, targeted therapies,” Chin said.

About 23,000 new cases of GBM are predicted in the United States during 2013 and more than 14,000 people expected to die of the disease. Most patients die within 15 months of diagnosis.

Well of rich, detailed data will nurture better treatment  

New information about genetic mutations, deletions and amplifications; gene expression and epigenetic regulation; structural changes due to chromosomal alterations, proteomic effects and the molecular networks that drive GBM make for a deep, broad dataset that will underpin research and clinical advances for years to come.

“Our main contribution is this tremendous resource for the GBM research community, which is already heavily relying on the earlier TCGA study,” said co-lead author Roeland Verhaak, Ph.D., assistant professor of Bioinformatics and Computational Biology at MD Anderson. “Whatever new treatments people come up with for GBM, I’m very confident that their discovery and development will in some way have benefited from this rich and detailed data set,” he said.

The Cell paper describes analysis of tumor samples and molecular data from 599 patients at 17 study sites. Detailed clinical information including treatment and survival was available for almost all cases

New targetable mutations

In addition to confirming significantly mutated genes discovered earlier, such as the tumor suppressors TP53, PTEN and RB1 and the oncogene PIK3CA, the analysis identified 61 new mutated genes.  The most frequent mutations occurred in from 1.7 to 9 percent of cases.  

Two of these, BRAF and FGFR, might have more immediate clinical relevance, Verhaak noted. MD Anderson neuro-oncologists are checking to see if patients have these mutations. Drugs are available to address those variations now, Verhaak said. The BRAF point mutation in GBM is the same commonly found in melanoma, which is treated by a new class of drugs.

More twists and turns for EGFR

The larger data set and an improved analytical algorithm allowed major refinement of gene amplification and deletion information. For example, common amplification events were found to occur more frequently than previously known, including amplification of the epidermal growth factor receptor (EGFR) on chromosome 7.

EGFR is both amplified and mutated frequently in GBM; yet therapeutic efforts targeting EGFR so far have failed. “We found EGFR is more frequently altered than we already thought,” Verhaak said.

Overall, the EGFR gene was mutated, rearranged, amplified or otherwise altered in 57 percent of tumors. Increased EGFR protein levels in GBM cells correlated with the many mechanisms of EGFR alteration, Verhaak said.

A treatment based on EGFR still has great potential, he noted. But strategies to target EGFR will need to address the likelihood that different alterations of EGFR might be present in the same tumor and affect the impact of targeted drugs.

Breaking GBM into molecular subtypes

Verhaak and other researchers in recent years have begun to classify GBM tumors by gene expression. Four such subgroups — neural, proneural, mesenchymal and classical — were further characterized by DNA methylation pattern, signaling pathway activity and by clinical measures such as survival and treatment response. Methylation of a gene turns it off.

Understanding the subgroups could establish biomarkers to guide treatment and identify new therapeutic targets.

The team found, for example, that the survival advantage of the proneural subtype depends on a specific DNA methylation pattern known as G-CIMP and that DNA methylation of the MGMT gene may serve as a biomarker of treatment response in the classical subtype.

(Source: mdanderson.org)

(Source: beaker.sanfordburnham.org)

Johns Hopkins researchers suggest neural stem cells may regenerate after anti-cancer treatment

Scientists have long believed that healthy brain cells, once damaged by radiation designed to kill brain tumors, cannot regenerate. But new Johns Hopkins research in mice suggests that neural stem cells, the body’s source of new brain cells, are resistant to radiation, and can be roused from a hibernation-like state to reproduce and generate new cells able to migrate, replace injured cells and potentially restore lost function.

“Despite being hit hard by radiation, it turns out that neural stem cells are like the special forces, on standby waiting to be activated,” says Alfredo Quiñones-Hinojosa, M.D., a professor of neurosurgery at the Johns Hopkins University School of Medicine and leader of a study described online today in the journal Stem Cells. “Now we might figure out how to unleash the potential of these stem cells to repair human brain damage.”

The findings, Quiñones-Hinojosa adds, may have implications not only for brain cancer patients, but also for people with progressive neurological diseases such as multiple sclerosis (MS) and Parkinson’s disease (PD), in which cognitive functions worsen as the brain suffers permanent damage over time.

In Quiñones-Hinojosa’s laboratory, the researchers examined the impact of radiation on mouse neural stem cells by testing the rodents’ responses to a subsequent brain injury. To do the experiment, the researchers used a device invented and used only at Johns Hopkins that accurately simulates localized radiation used in human cancer therapy. Other techniques, the researchers say, use too much radiation to precisely mimic the clinical experience of brain cancer patients.

In the weeks after radiation, the researchers injected the mice with lysolecithin, a substance that caused brain damage by inducing a demyelinating brain lesion, much like that present in MS. They found that neural stem cells within the irradiated subventricular zone of the brain generated new cells, which rushed to the damaged site to rescue newly injured cells. A month later, the new cells had incorporated into the demyelinated area where new myelin, the protein insulation that protects nerves, was being produced.

“These mice have brain damage, but that doesn’t mean it’s irreparable,” Quiñones-Hinojosa says. “This research is like detective work. We’re putting a lot of different clues together. This is another tiny piece of the puzzle. The brain has some innate capabilities to regenerate and we hope there is a way to take advantage of them. If we can let loose this potential in humans, we may be able to help them recover from radiation therapy, strokes, brain trauma, you name it.”

His findings may not be all good news, however. Neural stem cells have been linked to brain tumor development, Quiñones-Hinojosa cautions. The radiation resistance his experiments uncovered, he says, could explain why glioblastoma, the deadliest and most aggressive form of brain cancer, is so hard to treat with radiation.

(Source: hopkinsmedicine.org)

About 15 percent of glioblastoma patients could receive personalized treatment with drugs currently used in other cancers

A team of researchers at the Herbert Irving Comprehensive Cancer Center at Columbia University Medical Center has identified 18 new genes responsible for driving glioblastoma multiforme, the most common—and most aggressive—form of brain cancer in adults. The study was published August 5, 2013, in Nature Genetics.

“Cancers rely on driver genes to remain cancers, and driver genes are the best targets for therapy,” said Antonio Iavarone, MD, professor of pathology and neurology at Columbia University Medical Center and a principal author of the study.

“Once you know the driver in a particular tumor and you hit it, the cancer collapses. We think our study has identified the vast majority of drivers in glioblastoma, and therefore a list of the most important targets for glioblastoma drug development and the basis for personalized treatment of brain cancer.”

Personalized treatment could be a reality soon for about 15 percent of glioblastoma patients, said Anna Lasorella, MD, associate professor of pediatrics and of pathology & cell biology at CUMC.

“This study—together with our study from last year, Research May Lead to New Treatment for Type of Brain Cancer—shows that about 15 percent of glioblastomas are driven by genes that could be targeted with currently available FDA-approved drugs,” she said. “There is no reason why these patients couldn’t receive these drugs now in clinical trials.”

New Bioinformatics Technique Distinguishes Driver Genes from Other Mutations

In any single tumor, hundreds of genes may be mutated, but distinguishing the mutations that drive cancer from mutations that have no effect has been a longstanding problem for researchers.

An analysis of all gene mutations in nearly 140 brain tumors has uncovered most of the genes responsible for driving glioblastoma. The analysis found 18 new driver genes (labeled red), never before implicated in glioblastoma and correctly identified the 15 previously known driver genes (labeled blue). The graphs show mutated genes that are commonly found in varying numbers in glioblastoma (left), that frequently contain insertions (middle), and that frequently contain deletions (right). Genes represented by blue dots in the graphs were statistically most likely to be driver genes. Image: Raul Rabadan/Columbia University Medical Center.

The Columbia team used a combination of high throughput DNA sequencing and a new method of statistical analysis to generate a short list of driver candidates. The massive study of nearly 140 brain tumors sequenced the DNA and RNA of every gene in the tumors to identify all the mutations in each tumor. A statistical algorithm designed by co-author Raul Rabadan, PhD, assistant professor of biomedical informatics and systems biology, was then used to identify the mutations most likely to be driver mutations. The algorithm differs from other techniques to distinguish drivers from other mutations in that it considers not only how often the gene is mutated in different tumors, but also the manner in which it is mutated.

“If one copy of the gene in a tumor is mutated at a single point and the second copy is mutated in a different way, there’s a higher probability that the gene is a driver,” Dr. Iavarone said.

The analysis identified 15 driver genes that had been previously identified in other studies—confirming the accuracy of the technique—and 18 new driver genes that had never been implicated in glioblastoma.

Significantly, some of the most important candidates among the 18 new genes, such as LZTR1 and delta catenin, were confirmed to be driver genes in laboratory studies involving cancer stem cells taken from human tumors and examined in culture, as well as after they had been implanted into mice.

A New Model for Personalized Cancer Treatment

Because patients’ tumors are powered by different driver genes, the researchers say that a complicated analysis will be needed for personalized glioblastoma treatment to become a reality. First, all the genes in a patient’s tumor must be sequenced and analyzed to identify its driver gene.

“In some tumors it’s obvious what the driver is; but in others, it’s harder to figure out,” said Dr.Iavarone.

Once the candidate driver is identified, it must be confirmed in laboratory tests with cancer stem cells isolated from the patient’s tumor.

About 15 percent of glioblastoma driver genes can be targeted with currently available drugs, suggesting that personalized treatment for some patients may be possible in the near future. Personalized therapy for glioblastoma patients could be achieved by isolating the most aggressive cells from the patient’s tumor and identifying the driver gene responsible for the tumor’s growth (different tumors will be driven by different genes). Drugs can then be tested on the isolated cells to find the most promising candidate. In this image, the gene mutation driving the malignant tumor has been replaced with the normal gene, transforming malignant cells back into normal brain cells. Image: Anna Lasorella.

“Cancer stem cells are the tumor’s most aggressive cells and the critical cellular targets for cancer therapies,” said Dr. Lasorella. “Drugs that prove successful in hitting driver genes in cancer stem cells and slowing cancer growth in cell culture and animal models would then be tried in the patient.”

Personalized Treatment Already Possible for Some Patients

For 85 percent of the known glioblastoma drivers, no drugs that target them have yet been approved.

But the Columbia team has found that about 15 percent of patients whose tumors are driven by certain gene fusions, FDA-approved drugs that target those drivers are available.

The study found that half of these patients have tumors driven by a fusion between the gene EGFR and one of several other genes. The fusion makes EGFR—a growth factor already implicated in cancer—hyperactive; hyperactive EGFR drives tumor growth in these glioblastomas.

“When this gene fusion is present, tumors become addicted to it—they can’t live without it,” Dr. Iavarone said. “We think patients with this fusion might benefit from EGFR inhibitors that are already on the market. In our study, when we gave the inhibitors to mice with these human glioblastomas, tumor growth was strongly inhibited.”

Other patients have tumors that harbor a fusion of the genes FGFR (fibroblast growth factor receptor) and TACC (transforming acidic coiled-coil), first reported by the Columbia team last year. These patients may benefit from FGFR kinase inhibitors. Preliminary trials of these drugs (for treatment of other forms of cancer) have shown that they have a good safety profile, which should accelerate testing in patients with glioblastoma.

An experimental drug in early development for aggressive brain tumors can cross the blood-brain tumor barrier, kill tumor cells and block the growth of tumor blood vessels, according to a study led by researchers at the Ohio State University Comprehensive Cancer Center – Arthur G. James Cancer Hospital and Richard J. Solove Research Institute (OSUCCC – James).

The laboratory and animal study also shows how the agent, called SapC-DOPS, targets tumor cells and blood vessels. The findings support further development of the drug as a novel treatment for brain tumors.

Glioblastoma multiforme is the most common and aggressive form of brain cancer, with a median survival of about 15 months. A major obstacle to improving treatment for the 3,470 cases of the disease expected in the United States this year is the blood-brain barrier, the name given to the tight fit of cells that make up the blood vessels in the brain. That barrier protects the brain from toxins in the blood but also keeps drugs in the bloodstream from reaching brain tumors.

“Few drugs have the capacity to cross the tumor blood-brain barrier and specifically target tumor cells,” says principal investigator Balveen Kaur, PhD, associate professor of neurological surgery and chief of the Dardinger Laboratory of Neurosciences at the OSUCCC – James. “Our preclinical study indicates that SapC-DOPS does both and inhibits the growth of new tumor blood vessels, suggesting that this agent could one day be an important treatment for glioblastoma and other solid tumors.”

The findings were published in a recent issue of the journal Molecular Therapy.

SapC-DOPS (saposin-C dioleoylphosphatidylserine), is a nanovesicle drug that has shown activity in glioblastoma, pancreatic cancer and other solid tumors in preclinical studies. The nanovesicles fuse with tumor cells, causing them to self-destruct by apoptosis.

Key findings of the study, which used two brain-tumor models, include:

• SapC-DOPS binds with exposed patches of the phospholipid phosphatidylserine (PtdSer) on the surface of tumor cells;
• Blocking PtdSer on cells inhibited tumor targeting;
• SapC-DOPS strongly inhibited brain-tumor blood-vessel growth in cell and animal models, probably because these cells also have high levels of exposed PtdSer.
• Hypoxic cells were sensitized to killing by SapC-DOPS.

“Based on our findings, we speculate that SapC-DOPS could have a synergistic effect when combined with chemotherapy or radiation therapy, both of which are known to increase the levels of exposed PtdSer on cancer cells,” Kaur says.

(Source: cancer.osu.edu)