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Cheating Death: Yale Scientists Restore Cell, Organ Function in Pigs After Death

Illustration of organ perfusion and cellular recovery with OrganEx technology. The cell-saving blood analog is delivered to vital organs one hour after death. Credit: Marin Balaic

Yale-developed technology restores cell and organ function in pigs after death, a potential organ transplant breakthrough.

Within just minutes of the final heartbeat, a cascade of biochemical events triggered by a lack of blood flow, nutrients, and oxygen begins to destroy a body’s cells and organs. However, a team of researchers at Yale UniversityEstablished in 1701, Yale University is a private Ivy League research university in New Haven, Connecticut. It is the third-oldest institution of higher education in the United States and is organized into fourteen constituent schools: the original undergraduate college, the Yale Graduate School of Arts and Sciences and twelve professional schools. It is named after British East India Company governor Elihu Yale.” data-gt-translate-attributes=”[{“attribute”:”data-cmtooltip”, “format”:”html”}]”>Yale University has discovered that massive and permanent cellular failure doesn’t have to happen so quickly.

Using a new technology the scientists developed that delivers a specially designed cell-protective fluid to organs and tissues, the team restored blood circulation and other cellular functions in pigs a full hour after their deaths. They report their findings in the August 3 edition of the journal Nature.

Their results may help extend the health of human organs during surgery and expand the availability of donor organs, the authors said.

All cells do not die immediately, there is a more protracted series of events,” said David Andrijevic, associate research scientist in neuroscience at Yale School of Medicine and co-lead author of the study. “It is a process in which you can intervene, stop, and restore some cellular function.”

The research builds upon an earlier Yale-led project that restored circulation and certain cellular functions in the brain of a dead pig with technology dubbed BrainEx. Published in 2019, that study and the new one were led by the lab of Yale’s Nenad Sestan, the Harvey and Kate Cushing Professor of Neuroscience and professor of comparative medicine, genetics, and psychiatry. The new study involved senior author Sestan and colleagues Andrijevic, Zvonimir Vrselja, Taras Lysyy, and Shupei Zhang, all from Yale.

If we were able to restore certain cellular functions in the dead brain, an organ known to be most susceptible to ischemia [inadequate blood supply], we hypothesized that something similar could also be achieved in other vital transplantable organs,” Sestan said.

In the new study, the scientists applied a modified version of BrainEx called OrganEx to the whole pig. The technology consists of a perfusion device similar to heart-lung machines — which do the work of the heart and lungs during surgery — and an experimental fluid containing compounds that can promote cellular health and suppress inflammation throughout the pig’s body. Cardiac arrest was induced in anesthetized pigs, which were treated with OrganEx an hour after death.

Six hours after treatment with OrganEx, the researchers found that certain key cellular functions were active in many areas of the pigs’ bodies — including the heart, liver, and kidneys. Additionally, some organ functions had been restored. For instance, they found evidence of electrical activity in the heart, which retained the ability to contract.

We were also able to restore circulation throughout the body, which amazed us,” Sestan said.

Normally when the heart stops beating, organs begin to swell, collapsing blood vessels and blocking circulation, he said. Yet circulation was restored and organs in the deceased pigs that received OrganEx treatment appeared functional at the level of cells and tissue.

Under the microscope, it was difficult to tell the difference between a healthy organ and one which had been treated with OrganEx technology after death,” Vrselja said.

As in the 2019 experiment, the scientists also discovered that cellular activity in some areas of the brain had been restored. However, no organized electrical activity that would indicate consciousness was detected during any part of the experiment.

The team was especially surprised to observe involuntary and spontaneous muscular movements in the head and neck areas when they evaluated the treated animals, which remained anesthetized through the entire six-hour experiment. These movements indicate the preservation of some motor functions, Sestan said.

Additional studies are necessary to understand the apparently restored motor functions in the animals, the researchers stressed. They also called for rigorous ethical review from other scientists and bioethicists.

The experimental protocols for the latest study were approved by Yale’s Institutional Animal Care and Use Committee and guided by an external advisory and ethics committee.

The OrganEx technology could eventually have several potential applications, the researchers said. For example, it could extend the life of organs in human patients and expand the availability of donor organs for transplant. It might also be able to help treat organs or tissue damaged by ischemia during heart attacks or strokes.

There are numerous potential applications of this exciting new technology,” said Stephen Latham, director of the Yale Interdisciplinary Center for Bioethics. “However, we need to maintain careful oversight of all future studies, particularly any that include perfusion of the brain.”

Reference: “Cellular recovery after prolonged warm ischaemia of the whole body” by David Andrijevic, Zvonimir Vrselja, Taras Lysyy, Shupei Zhang, Mario Skarica, Ana Spajic, David Dellal, Stephanie L. Thorn, Robert B. Duckrow, Shaojie Ma, Phan Q. Duy, Atagun U. Isiktas, Dan Liang, Mingfeng Li, Suel-Kee Kim, Stefano G. Daniele, Khadija Banu, Sudhir Perincheri, Madhav C. Menon, Anita Huttner, Kevin N. Sheth, Kevin T. Gobeske, Gregory T. Tietjen, Hitten P. Zaveri, Stephen R. Latham, Albert J. Sinusas and Nenad Sestan, 3 August 2022, Nature.
DOI: 10.1038/s41586-022-05016-1

The research was funded by the U.S. Department of Health & Human Services, National Institutes of Health, and National Institute of Mental Health.

This work was supported by the NIH BRAIN Initiative grants MH117064, MH117064-01S1, R21DK128662,T32GM136651, F30HD106694, and Schmidt Futures.

Source: SciTechDaily