I Hate Dialysis Message Board
Welcome, Guest. Please login or register.
November 26, 2024, 09:25:45 PM

Login with username, password and session length
Search:     Advanced search
532606 Posts in 33561 Topics by 12678 Members
Latest Member: astrobridge
* Home Help Search Login Register
+  I Hate Dialysis Message Board
|-+  Dialysis Discussion
| |-+  Dialysis: News Articles
| | |-+  UCSF unveils model for implantable artificial kidney to replace dialysis
0 Members and 1 Guest are viewing this topic. « previous next »
Pages: [1] Go Down Print
Author Topic: UCSF unveils model for implantable artificial kidney to replace dialysis  (Read 1928 times)
okarol
Administrator
Member for Life
*****
Offline Offline

Gender: Female
Posts: 100933


Photo is Jenna - after Disneyland - 1988

WWW
« on: September 02, 2010, 03:30:06 PM »

UCSF unveils model for implantable artificial kidney to replace dialysis

September 2, 2010
UCSF researchers today unveiled a prototype model of the first implantable artificial kidney, in a development that one day could eliminate the need for dialysis.
 
The device, which would include thousands of microscopic filters as well as a bioreactor to mimic the metabolic and water-balancing roles of a real kidney, is being developed in a collaborative effort by engineers, biologists and physicians nationwide, led by Shuvo Roy, PhD, in the UCSF Department of Bioengineering and Therapeutic Sciences.
The treatment has been proven to work for the sickest patients using a room-sized external model developed by a team member in Michigan. Roy's goal is to apply silicon fabrication technology, along with specially engineered compartments for live kidney cells, to shrink that large-scale technology into a device the size of a coffee cup. The device would then be implanted in the body without the need for immune suppressant medications, allowing the patient to live a more normal life.
"This device is designed to deliver most of the health benefits of a kidney transplant, while addressing the limited number of kidney donors each year," said Roy, an associate professor in the UCSF School of Pharmacy who specializes in developing micro-electromechanical systems (MEMS) technology for biomedical applications. "This could dramatically reduce the burden of renal failure for millions of people worldwide, while also reducing one of the largest costs in U.S. healthcare."
The team has established the feasibility of an implantable model in animal models and plans to be ready for clinical trials in five to seven years.
End-stage renal disease, or chronic kidney failure, affects more than 500,000 people per year in the United States alone, and currently is only fully treated with a kidney transplant. That number has been rising between 5-7 percent per year, Roy said, in part because of the kidney damage associated with diabetes and hypertension.
Yet transplants are difficult to obtain: a mere 17,000 donated kidneys were available for transplant last year, while the number of patients on the transplant waiting list currently exceeds 85,000, according to the Organ Procurement ant Transplant Network.
Ads by Google
Kidney Transplant Medication - Understanding Kidney Transplants Information and Advice for Patients - www.TransplantExperience.com
 
Roughly 350,000 patients are reliant on kidney dialysis, Roy explained, which comes at a tremendous cost. The Medicare system alone spends $25 billion on treatments for kidney failure - more than 6 percent of the total budget - while the disease affects only 1 percent of Medicare recipients, he said. That cost includes almost $75,000 per patient each year for dialysis, according to the U.S. Renal Data System.
Dialysis also takes a human toll. A typical dialysis schedule is three sessions per week, for 3 to 5 hours per session, in which blood is pumped through an external circuit for filtration. This is exhausting for patients and only replaces 13 percent of kidney function, Roy said. As a result, only 35 percent of patients survive for more than 5 years.
With the limited supply of donors, that means thousands of patients die each year waiting for a kidney.
The implantable device aims to eradicate that problem. The two-stage system uses a hemofilter to remove toxins from the blood, while applying recent advances in tissue engineering to grow renal tubule cells to provide other biological functions of a healthy kidney. The process relies on the body's blood pressure to perform filtration without needing pumps or an electrical power supply.
The project exemplifies the many efforts under way at UCSF to build collaborations across scientific disciplines that accelerate the translation of academic research into real solutions for patients, according to Mary Anne Koda-Kimble, PharmD, dean of the UCSF School of Pharmacy.
"This is a perfect example of the work we are doing at UCSF to address some of the most critical medical issues of our time, both in human and financial costs," Koda-Kimble said. "This project shows what can be accomplished by teams of scientists with diverse expertise, collaborating to profoundly and more quickly improve the lives of patients worldwide."
The creation of the Department of Bioengineering and Therapeutic Sciences - a joint department in the UCSF schools of Pharmacy and Medicine - was itself an effort to promote translational research at UCSF by forming collaborations across biomedical specialties. Roy is also a founding faculty member of the UCSF Pediatric Device Consortium, which aims to accelerate the development of innovative devices for children health, and a faculty affiliate of the California Institute for Quantitative Biosciences (QB3) at UCSF.
His team is collaborating with 10 other teams of researchers on the project, including the Cleveland Clinic where Roy initially developed the idea, Case Western Reserve University, University of Michigan, Ohio State University, and Penn State University.
The first phase of the project, which has already been completed, focused on developing the technologies required to reduce the device to a size that could fit into the body and testing the individual components in animal models. In the second and current phase, the team is doing the sophisticated work needed to scale up the device for humans. The team now has the components and a visual model and is pursuing federal and private support to bring the project to clinical use.
Provided by University of California - San Francisco

http://www.physorg.com/news202662991.html
Logged


Admin for IHateDialysis 2008 - 2014, retired.
Jenna is our daughter, bad bladder damaged her kidneys.
Was on in-center hemodialysis 2003-2007.
7 yr transplant lost due to rejection.
She did PD Sept. 2013 - July 2017
Found a swap living donor using social media, friends, family.
New kidney in a paired donation swap July 26, 2017.
Her story ---> https://www.facebook.com/WantedKidneyDonor
Please watch her video: http://youtu.be/D9ZuVJ_s80Y
Living Donors Rock! http://www.livingdonorsonline.org -
News video: http://www.youtube.com/watch?v=J-7KvgQDWpU
carol1987
Full Member
***
Offline Offline

Gender: Female
Posts: 397


« Reply #1 on: September 02, 2010, 08:23:39 PM »

That is amazing!!
Logged

Diagnosed with  PKD July 2002 (no family history)
Fistula placed April 2009
Placed on Transplant list April 2009
Started HD 10/6/10
Transplanted 1/6/11 (Chain Transplant My altruistic donor was  "Becky from Chicago" , and DH Mike donated on my behalf and the chain continued...)
RightSide
Elite Member
*****
Offline Offline

Gender: Male
Posts: 1117


« Reply #2 on: September 03, 2010, 05:02:18 PM »

UCSF unveils model for implantable artificial kidney to replace dialysis

September 2, 2010
UCSF researchers today unveiled a prototype model of the first implantable artificial kidney, in a development that one day could eliminate the need for dialysis....
 
The implantable device aims to eradicate that problem. The two-stage system uses a hemofilter to remove toxins from the blood, while applying recent advances in tissue engineering to grow renal tubule cells to provide other biological functions of a healthy kidney.
Where do these "renal tubule cells" come from?

Won't the patient's own immune system reject these cells, just like it would reject a mismatched kidney transplant?

After all, the patient's blood is circulating through these tubules, so his immune system should "notice" them as foreign.
Logged
greg10
Full Member
***
Offline Offline

Gender: Male
Posts: 469


« Reply #3 on: September 03, 2010, 06:29:46 PM »

Quote
Won't the patient's own immune system reject these cells, just like it would reject a mismatched kidney transplant?
Probably separated by a membrane, allowing only small molecules to pass.
This whole thing sounds like a long shot.  The kidney is arguably the most complex organ from the neck down, certainly more complex than the heart which is more amendable to bioengineering.
Logged

Newbie caretaker, so I may not know what I am talking about :)
Caretaker for my elderly father who has his first and current graft in March, 2010.
Previously in-center hemodialysis in national chain, now doing NxStage home dialysis training.
End of September 2010: after twelve days of training, we were asked to start dialyzing on our own at home, reluctantly, we agreed.
If you are on HD, did you know that Rapid fluid removal (UF = ultrafiltration) during dialysis is associated with cardiovascular morbidity?  http://ihatedialysis.com/forum/index.php?topic=20596
We follow a modified version: UF limit = (weight in kg)  *  10 ml/kg/hr * (130 - age)/100

How do you know you are getting sufficient hemodialysis?  Know your HDP!  Scribner, B. H. and D. G. Oreopoulos (2002). "The Hemodialysis Product (HDP): A Better Index of Dialysis Adequacy than Kt/V." Dialysis & Transplantation 31(1).   http://www.therenalnetwork.org/qi/resources/HDP.pdf
RightSide
Elite Member
*****
Offline Offline

Gender: Male
Posts: 1117


« Reply #4 on: September 04, 2010, 08:35:46 PM »

The kidney is arguably the most complex organ from the neck down, certainly more complex than the heart which is more amendable to bioengineering.
I'll bet that the liver is more complex than the kidney.

After all, we've got dialysis for kidney failure; liver dialysis exists but can't sustain a patient for more than a short period.
Logged
Sax-O-Trix
Full Member
***
Offline Offline

Posts: 391


« Reply #5 on: September 04, 2010, 08:54:54 PM »

As wonderful as this would be, it's so far off in the future...  So the only thing that really caught my attention was the "Only 35% of  dialysis patients survive more than 5 years" statement. :( 
Logged

Preemptive transplant recipient, living donor (brother)- March 2011
Pages: [1] Go Up Print 
« previous next »
 

Powered by MySQL Powered by PHP SMF 2.0.17 | SMF © 2019, Simple Machines | Terms and Policies Valid XHTML 1.0! Valid CSS!