Study suggests new approach to treating kidney failure
They demonstrated for the first time that kidney cells housed in a bioreactor, an implanted device, can live within the body of a pig and replicate numerous critical kidney processes.
CALIFORNIA: Scientists at UC San Francisco are developing a new strategy to treating kidney failure that could one day eliminate the need for dialysis or the use of harsh medicines to suppress the immune system following a transplant.
They demonstrated for the first time that kidney cells housed in a bioreactor, an implanted device, can live within the body of a pig and replicate numerous critical kidney processes. The gadget, like a pacemaker, can operate silently in the background and does not activate the recipient's immune system.
The findings, published in Nature Communications on August 29, 2023, are an important step forward for The Kidney Project, which is jointly headed by UCSF’s Shuvo Roy, PhD (technical director) and Vanderbilt University Medical Center’s William H. Fissell, MD (medical director).
Eventually, scientists plan to fill the bioreactor with different kidney cells that perform vital functions like balancing the body’s fluids and releasing hormones to regulate blood pressure – then pair it with a device that filters waste from the blood.
The aim is to produce a human-scale device to improve on dialysis, which keeps people alive after their kidneys fail but is a poor substitute for having a real working organ. More than 500,000 people in the U.S. require dialysis several times a week. Many seek kidney transplants, but there are not enough donors, and only about 20,000 people receive them each year. An implantable kidney would be a boon.
“We are focused on safely replicating the key functions of a kidney,” said Roy, a bioengineering professor in the UCSF School of Pharmacy. “The bioartificial kidney will make treatment for kidney disease more effective and also much more tolerable and comfortable.”
Roy and his colleagues engineered the bioreactor to connect directly to blood vessels and veins, allowing the passage of nutrients and oxygen, much like a transplanted kidney would. Silicon membranes keep the kidney cells inside the bioreactor safe from attack by the recipient’s immune cells.
The team used a type of kidney cell called a proximal tubule cell, which regulates water, as a test case. Co-author H. David Humes, MD, from the University of Michigan, had previously used these cells to help dialysis patients in the intensive care unit with life-saving results.
The team tracked the kidney cells and the recipient animals for seven days after transplantation and both did well. The next step will be month-long trials, as required for by the U.S. Food and Drug Administration (FDA), first in animals and eventually in humans.
“We needed to prove that a functional bioreactor will not require immunosuppressant drugs, and we did,” Roy said. “We had no complications and can now iterate up, reaching for the whole panel of kidney functions at the human scale.”