Posted on 05/12/2008 10:46:04 AM PDT by Havok
PRICK FINGER. Test blood. Inject insulin. For millions of people around the world, this painful and tedious cycle is all that stands between relative health and the ravages of diabetes, a disease known to cause blindness, kidney failure, and death. Joseph P. Kennedy hopes that a specially coated metal tube, no larger than a cigarette, will someday put an end to all that.
PRICK FINGER. Test blood. Inject insulin. For millions of people around the world, this painful and tedious cycle is all that stands between relative health and the ravages of diabetes, a disease known to cause blindness, kidney failure, and death. Joseph P. Kennedy hopes that a specially coated metal tube, no larger than a cigarette, will someday put an end to all that.
Courtesy of Joseph Kennedy
Kennedy, a professor of chemistry and polymer science at the University of Akron, in Ohio, calls the device a bioartificial pancreas. He spoke about its construction during a presentation in the Division of Polymer Chemistry at the American Chemical Society national meeting in New Orleans last month.
The World Health Organization estimates that more than 180 million people worldwide have diabetes, and that number is expected to double by 2030. An artificial pancreas, Kennedy says, “would have immense socioeconomic significance.”
A number of research groups around the world are currently working to develop artificial pancreas technologies. Most strategies involve transplanting healthy isletsthe pancreatic cells that detect glucose and release insulininto the diabetic patient. The cells are encapsulated either individually within a hydrogel or as a large collection of cells within some type of polymer membrane.
Kennedy’s group takes the latter approach. Their prototype begins with a scaffold made from a 7-cm-long tube of the biocompatible nickel-titanium alloy nitinol that’s been perforated with laser-cut hexagonal holes. Polyurethane nanofibers are then electrospun over the tube, through techniques designed by Kennedy’s colleague Miko Cakmak, who is a polymer engineering professor at Akron. The resulting entanglement of nanofibers, or so-called nanomats, reinforces the openings in the scaffold’s mesh.
THE TUBE is then coated with a semipermeable polymer membrane made up of poly(dimethylacrylamide) and polydimethylsiloxane domains cross-linked by polymethylhydrosiloxane. The entire assembly is dried, washed to remove small molecules, cleaned in an autoclave, and finally filled with a suspension of pig islets.
Ken S. Rosenthal, a professor of microbiology and immunology at Northeastern Ohio Universities College of Medicine, and one of Kennedy’s collaborators on the project, says that the polymer membrane is really what sets this artificial pancreas apart. Encapsulating a large collection of islets has been difficult, he says, because the material to make that capsule has never been designed for that purpose.
“This device differs because its polymer membrane has been designed to have the optimal properties for encapsulating islets,” Rosenthal tells C&EN. “It allows for free movement of insulin and glucose but restricts access of immune molecules that might attack the encapsulated islets.” Likewise, any viruses that might be piggybacking on the islets are trapped behind the membrane.
“Because of that, we can use pig cells, and the only thing that communicates between them and the patient are the small molecules and small proteins,” Rosenthal notes.
The polymer can also sequester oxygen from the environment, thanks to its silicone-based components. This oxygen nourishes the encapsulated islets cells. “These membranes are biocompatible, flexible, transparent, autoclavable, and they’re easily synthesized and relatively inexpensive,” Rosenthal says.
“Kennedy is the only researcher that I know of who designed the bioartificial pancreas for longevity and oxygen permeability,” says Len Pinchuk, president and chief executive officer of Miami-based Innovia, a company that develops biomaterials and medical devices. “Most other researchers in this field come from a biological background and don’t have the tools to create these new biomaterials.”
The artificial pancreas can be inserted anywhere in the body that encounters blood flow, Kennedy says, even just beneath the skin. “The blood brings the oxygen and nutrients needed by the islets and removes metabolic wastes, such as carbon dioxide.”
The device, Kennedy notes, acts as both a glucose sensor and an insulin delivery device. “It delivers exactly the needed amount of insulin,” he says. “Insulin concentration in the body must be precisely controlled. Too high or too low concentrations result in very serious side effects.”
People with type 1 diabetesaround 2 million in the U.S. alonemake up the primary market for the device, although Kennedy thinks it could also be useful for the some 4 million patients with type 2 diabetes who inject insulin to control their blood sugar levels.
“The goal is to correct high glucose levels in real time instead of once a day or twice a day,” Rosenthal says. So far, tests with rats and dogs, spearheaded by Kennedy’s collaborator Sharon F. Grundfest-Broniatowski, a surgeon at the Cleveland Clinic Foundation, have shown preliminary success. Next, the team hopes to do more advanced animal experiments and then move on to human trials.
“If experimental results in vivo show a satisfying survival rate and perfect functions of the macroencapsulated islets, Kennedy’s artificial pancreas will have great potential in clinical applications,” according to Lina Lu, a doctor in the department of immunology and surgery at the Cleveland Clinic Foundation
THE TUBE is then coated with a semipermeable polymer membrane made up of poly(dimethylacrylamide) and polydimethylsiloxane domains cross-linked by polymethylhydrosiloxane.
I just tried this in my garage, and what do you know, it WORKS!
Seriously, if this can be made to work in the real world, what a blessing. I've known so many people who are diabetic. The disease can be such a challenge to control, even for those who are conscientious about their diet and exercise.
The interesting thing is that the average insulin pump has a connection for a continious glucose monitor which would allow the unit to function as an artificial pancreas.
The problem is the sensor is still under patent and is extraordinarilly over priced and insurers won’t pay for it. The sensor should go off patent in the next few years dramatically improving diabetes treatment.
All seriousness aside, shouldn’t he be working an artificial Liver?
I think, too, that if they can replace the pig-derived beta cells with adult-stem cell-derived beta cells. JDRF recently partnered with Plureon Corporation to work that out.
It's looking possible....
Its not Teddy. lol
Also, the sensors are finicky for some (including my son), which leads to many, many sleepless nights as the damned sensor keeps misreading so the pump is always alarming. They used to say it took 3 weeks to get used to the sensors ... now it's up to "as many as 3 months."
More like an artificial insulin producer.
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Pancreas/diabetes ping!
I use the Omnipod which doesnt have the sensor but has its own problems. It is wireless and tubeless though!
It has one whole side that is sticky and the pod itself is a smooth egg shape and size. Sometimes too smooth. One night it popped out of my hand only to stick to the middle of my chest. That would’nt be so bad but I have a hairy chest.
Hurt like hell coming off.
I’m a type 2 diabetic. There are men and women working every day for a cure. Never give up hope we will see it in our life times. We stand on the brink of a brave new world.
Try shaving it!
LOL
What's your opinion -- more or less convenient than a pump? Do you have to take it off for sports, or bathing?
Also ... how is it controlled? Are the pump controls part of the meter?
The compay itself is FANTASTIC to deal with.
You wear it for three days at a time. You bathe with it on. You can swim to 8 feet deep.
For sports the only things you have to worry about is just suspending the dose (I am sure you understand that) and making sure your sweat doesnt make it fall off. I Have never had it come off from that but they just warn you about it.
It is controlled with a remote about the size of a cell phone that also doubles as your tester.
If you have a ton of questions feel free to privately ping me. I can answer anything you want to know. I should become a salesman for the company because I love it!
I’ve never actually seen anyone using the sensor. I know the port is there and I spoke with a rep last year who told me that affordable sensors would be coming.
I hope people have better luck with them though.
Well as a type #1 going on 38 years it would be wonderful to be normal someday. I really don’t remember what it was like to not have to do everything that I have to do to live? I still have all fingers,toes and eyesight except for being severly near sighted. I’ve always tried to remind myself that there are dieases children get that they don’t survive, so I am lucky. :)
Oh and the insulin is put into the pod before you put it on. the pump and everything is built right into the pod. Holds 200 units.
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