jueves, 25 de julio de 2013

Silky brain implants may help stop spread of epilepsy

Silky brain implants may help stop spread of epilepsy


Silky brain implants may help stop spread of epilepsy

NIH-funded study suggests role for adenosine in molecular processes involved in epilepsy
Silk has walked straight off the runway and into the lab. According to a new study published in the Journal of Clinical Investigation, silk implants placed in the brain of laboratory animals and designed to release a specific chemical, adenosine, may help stop the progression of epilepsy. The research was supported by the National Institute of Neurological Disorders and Stroke (NINDS) and the National Institute of Biomedical Imaging and Bioengineering (NIBIB), which are part of the National Institutes of Health.
The epilepsies are a group of neurological disorders associated with recurring seizures that tend to become more frequent and severe over time. Adenosine decreases neuronal excitability and helps stop seizures. Earlier studies have suggested abnormally low levels of adenosine may be linked to epilepsy.
Image of a silk implant used in the study
Example of Silk Implant Used in the Study. Silk implants designed to release adenosine were placed into rat brains to stop the spread of epilepsy. Image courtesy of Dr. Boison, from Legacy Research Institute and OHSU.
Rebecca L. Williams-Karnesky, Ph.D. and her colleagues from Legacy Research Institute, Portland, Ore., Oregon Health and Sciences University (OHSU), Portland, and Tufts University, Boston, looked at long-term effects of an adenosine-releasing silk-implant therapy in rats and examined the role of adenosine in causing epigenetic changes that may be associated with the development of epilepsy.
The investigators argue that adenosine’s beneficial effects are due to epigenetic modifications (chemical reactions that change the way genes are turned on or off without altering the DNA code, the letters that make up our genetic background). Specifically, these changes happen when a molecule known as a methyl group blocks a portion of DNA, affecting which genes are accessible and can be turned on. If methyl groups have been taken away (demethylated), genes are more likely to turn on.
The results reported in the paper provided evidence that changing adenosine levels affects DNA methylation in the brain. Specifically, greater amounts of adenosine were associated with lower levels of DNA methylation. The investigators also demonstrate that rats induced to develop epilepsy have higher levels of methylated DNA. Of particular note, epileptic rat brains that had received the adenosine-releasing silk implants exhibited DNA methylation levels close to brains of normal rats and this significantly lessened the worsening of the epilepsy over time.
“We know that there are mutations that are associated with epilepsy. However, there are few people such as Dr. Detlev Boison who are doing this type of work, focusing not just on genetic mutations but how the genes are regulated,” said Vicky Whittemore, Ph.D., program director at NINDS.
One mechanism involved in a specific type of epilepsy is an increase in mossy fiber sprouting — the formation of new excitatory circuits in the part of the brain where seizures commonly originate. At the end of the experiment, animals that had been treated with the adenosine-releasing silk implant showed less sprouting than animals that were not given the drug. “Based on our findings that 10 days of adenosine delivery prevented the sprouting of mossy fibers for at least three months in rats, we predict that the benefits of our adenosine therapy may extend even longer. However, this assumption needs to be validated in long-term experiments that go beyond three months,” said Dr. Boison, senior author of the paper from Legacy Research Institute and OHSU.
The rats did not receive the implants until they had experienced a number of seizures. The researchers noted that many studies investigating anti-epileptic drugs often test the treatments too early. “If the therapy interferes with the trigger for epilepsy development then the trigger is weakened and subsequent epilepsy is less severe. However, this is not necessarily indicative of a stop in the progression of the disease,” said Dr. Boison. They found that the adenosine-releasing silk did not completely abolish seizures in their animal model but reduced them four-fold.
“To avoid interference with the epilepsy-triggering mechanisms, we waited until all animals developed an early stage of epilepsy. In this model, the disease is life-long: seizures become more frequent and worsen with time. Therefore, we challenged ourselves to attempt treatment at a stage where epilepsy had already been established,” Dr. Boison continued.
The findings show that the implants are safe to use in rats and suggest that they may one day be used in the clinic. “Adenosine-releasing silk is a biodegradable implant. The release of adenosine occurs for 10 days and then the silk will completely dissolve. This is an ideal set-up for a transient preventative treatment,” said Dr. Boison. “Clinical applications could be the prevention of epilepsy following head trauma or the prevention of seizures that often — in about 50 percent of patients — follow conventional epilepsy surgery. In this case, adenosine-releasing silk might be placed into the resection cavity in order to prevent future seizures.”
However, before the silk implants are ready for their close-up, future studies will need to determine their optimal use and safety in humans. According to Dr. Boison, “We need to look into the efficacy of different doses of adenosine, the duration of adenosine release, and various time points of intervention.”
Future studies also need to demonstrate how long the effects of the adenosine-releasing silk implant will last.
“This work is important because 25-30 percent of people with epilepsy do not have effective therapies. This research may help us to prevent epilepsy in people who suffer some event that places them at risk for the disorder, such as individuals who have experienced head trauma,” said Dr. Whittemore.
This study was supported by grants from NINDS (NS061844, NS070359), NIBIB (EB002520), and the U.S. Department of Defense (W81XWH-12-1-0283).
For more information about epilepsy, please visit: http://www.ninds.nih.gov/disorders/epilepsy/epilepsy.htm
NINDS is the nation’s leading funder of research on the brain and nervous system. The NINDS mission is to reduce the burden of neurological disease – a burden borne by every age group, by every segment of society, by people all over the world.
About the National Institutes of Health (NIH): NIH, the nation's medical research agency, includes 27 Institutes and Centers and is a component of the U.S. Department of Health and Human Services. NIH is the primary federal agency conducting and supporting basic, clinical, and translational medical research, and is investigating the causes, treatments, and cures for both common and rare diseases. For more information about NIH and its programs, visit www.nih.gov.
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Reference

Rebecca L. Williams-Karnesky et al. “Epigenetic changes induced by adenosine augmentation therapy prevent epileptogenesis.” Journal of Clinical Investigation, July 25, 2013.

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