Gene Therapy a Step Closer to Mass Production

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Offline 7assan

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Gene Therapy a Step Closer to Mass Production
« on: July 01, 2010, 09:53:29 AM »
EUREKA project E! 3371 Gene Transfer Agents has made great advances in the development of novel non-viral carriers able to introduce genetic material into the target cells. These new agents, derivatives of cationic amphiphilic 1,4-dihydropyridine (1,4-DHP), avoid the problems of the recipient's immune system reacting against a viral carrier.


http://www.sciencedaily.com/releases/2010/06/100624122058.htm

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Offline 7assan

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Scientists Design New Delivery Device for Gene Therapy
« Reply #1 on: July 07, 2010, 06:57:35 PM »
 Scientists have designed a nanoparticle that appears to effectively deliver genetic material into cells with minimal toxic effects.



In lab experiments, the researchers have found that this device, a vector, is able to deliver DNA deeply enough into a cell to allow genetic material to be activated -- a critical step in gene therapy. This vector is between 2 ½ and 10 times more effective than other experimental materials, according to the research.

Biomedical researchers continue to pursue gene therapy as a treatment option for a variety of diseases known to be caused by a genetic defect. That pursuit includes efforts to ensure the safety of the therapy and find the most effective way to deliver the genes.

In many experiments, deactivated viruses that retain their ability to infect other cells are used as vectors to deliver normal genes intended to replace, or turn off, defective genes. But because some of the viruses can generate an immune response that complicates the treatment, scientists also are pursuing nonviral vector techniques for gene therapy.

In this case, Ohio State University scientists combined two ingredients -- calcium phosphate and a lipid shell -- to create a nanoparticle that protects DNA during its journey to the cell and then dissolves to allow for gene activation in the target cell. Nano refers to the tiny size of the particle in question -- its general structure can be detected only by an atomic force microscope.

Calcium phosphate is a mineral found in bones and teeth. Lipids are fatty molecules that help maintain the structure of cell membranes. Alone, calcium phosphate is toxic and lipids get absorbed by cells. Together, they form a protective and inflexible structure that, thanks to complex chemical reactions, self-destructs once inside a cell.

"Our nanoparticle is a foreign body just like a viral vector is, but it has a self-destructive mechanism so it does not generate a strong response from the immune system," said Chenguang Zhou, a graduate student in pharmaceutics at Ohio State and lead author of the study. "The material we use is also biocompatible. Calcium phosphate is in our bones and the lipids we use are synthetic, but can be biologically degraded. That's why there is low toxicity."

The research is published in a recent issue of the International Journal of Pharmaceutics.

Zhou noted that other researchers have tried to use liposomes -- nanometer-sized bubbles made out of the same material as a cell membrane -- to create nonviral vectors for gene delivery. While the material did a good job of protecting the DNA, it did not do a good job of releasing the gene into a cell.

"The liposome gets internalized into cells. It's sort of like eating food that gets stuck in the stomach or intestines, but never gets to the rest of the body," he said.

Similarly, calcium phosphate alone has been considered as a gene delivery vehicle. But because of its salty properties, it becomes unstable and expands in size, which makes it too big to penetrate some cell and vascular walls, and which can cause the immune system to reject it.

"So what we do is encapsulate a calcium phosphate core inside the liposome," Zhou said. "And when this calcium phosphate gets inside a cell and that environment becomes acidic, it gets dissolved and then the gene can be very effectively released into the cytoplasm and transported to the nucleus. That is the theory."

Zhou and colleagues have developed what they consider an easy method to manufacture this particle. They create a synthetic lipid and place it in a solution that contains calcium and phosphate, which becomes integrated with the lipid. As the acidic properties in the solution change, the calcium phosphate forms a core.
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http://www.sciencedaily.com/releases/2010/07/100706161801.htm

 

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