黑料吃瓜群网

A type 1 diabetes trial at the Royal Adelaide 黑料吃瓜群网 (RAH) is said to be showing promising results after the first surgery performed in May.

The new method, led by Kidney and Islet Transplantation Director Professor Toby Coates AO, of the Central Adelaide Local Health Network, implants insulin-producing islet cells into an artificial dermis (skin) in the patient鈥檚 arm.

Islet cells are created in the pancreas and produce the hormones that regulate blood sugar, such as insulin. Transplantation of islet cells into the liver can help diabetics to produce their own insulin. But with this method, about 75% of transplanted islet cells, donated from cadavers, are lost in the first 24 hours, according to the Central Adelaide Local Health Network. This is due to the limited supply of oxygenated blood to the liver.

鈥淵ou have to process three pancreases to get one that will work, so transplanting into the liver is a very inefficient procedure,鈥� Coates said.

鈥淪o the quest around the world has been to come up with alternative sites where the cells might be more likely to survive, and that鈥檚 what led us to start working here, looking at implanting into the skin.鈥�

Sourcing islet cells from the pancreas of deceased donors means there is a finite supply. This places a limit on the number of transplants that can be performed and the number of patients who can successfully benefit.

However, by creating an oxygen-rich environment outside of the liver to support the survival and functioning of islet cells, the supply of donated cells can be better used to provide more transplants to more patients.

This approach involves the removal of a piece of the patient鈥檚 skin in the upper arm and replacing it with a piece of novel polymer foam creating an artificial dermis (skin). This newly created artificial skin site becomes highly vascularised (high blood flow) creating a similar environment to that of a person鈥檚 pancreas. Once the artificial skin site has settled after around 20 days, the site is then injected with donor insulin-producing islets cells creating an insulin-producing artificial pancreas for the patient in the skin of their upper arm.

This new method could also support alternative methods of sourcing donor islet cells. Stem cell-derived islets, for instance, may be able to be differentiated in a laboratory culture and then transplanted into the skin. This would further increase the precious supply, reducing or ending the reliance on rare donor islets.

The innovative treatment is said to be less invasive than the liver implantation method, as it can be done under local anaesthetic, is easy to monitor or remove and is significantly less expensive. It also provides the transplanted cells with their own blood supply, which reduces the risk to the patient.

The first step

This proof-of-concept study includes three patients and lasts for three months. It is primarily to check that the procedure is safe for the recipient, and that the site works: that islets can survive and secrete insulin.

鈥淭his is just the beginning 鈥� the first step,鈥� Coates said.

Alec Tibbitts was the first of three patients in a trial of the new treatment, which could lead to him no longer needing his daily insulin injections. 鈥淗aving been a child with diabetes, and being the parent of a child with diabetes, I鈥檝e felt the anxiety from both angles,鈥� Tibbitts said.

鈥淸I wanted to be] part of a small step in what could eventually be a life-changing procedure for many thousands of patients.鈥�

If we can get to the point where type 1 diabetics can produce their own insulin, then that would be historic,鈥� Tibbitts said.

The next step

Although much more research is still to come, this study is the culmination of eight years of work led by Professor Coates and initiated by Professor John Greenwood AM, the former director of the RAH Burns Unit. Now retired, Greenwood is world renowned for his work treating complex burns and developing an artificial skin. The expertise of the two world-leading researchers combined to inspire the novel technique.

If the trial is successful, the next step would be to gather further data from more participants. Clinicians and patients alike are optimistic that this world-class research can be a pathway towards a cure for type 1 diabetes.

This research was funded through the JDRF Pilot and Innovation Awards, with research done at the renal laboratories in the University of Adelaide in collaboration with local South Australian biotech company Beta Cell Technologies Pty Ltd.

Pictured from left to right: Professor Toby Coates AO, Nurse Unit Manager Colleen Cunningham, Surgeon Dr Patrick Coghlan, Dr Dorota Pawlak: Juvenile Diabetes Research Foundation, Professor John Greenwood AM, CALHN CEO Professor Lesley Dwyer, and pioneering patient Alec Tibbitts.