LinkGevity secures place in SPACE-H accelerator programme

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Image: WikiImages/Pixabay

LinkGevity, an AI-driven drug discovery company focused on longevity and age-related disease, has been selected for the SPACE-H Accelerator programme, powered by Starburst in collaboration with NASA’s Human Research Program (NASA HRP), the Translational Research Institute for Space Health (TRISH), and Microsoft Federal (Microsoft).

The programme, in its inaugural year, is dedicated to advancing innovative solutions for human health and performance in space. LinkGevity has been selected as its research has uncovered a first in class anti-necrotic technology with significant potential to minimize the health and performance risks in human spaceflight.

The human spaceflight sector is growing rapidly, with commercial space companies poised to be the primary driver of human spaceflight activity by 2040 and NASA’s focus on space exploration taking on a new dimension, with plans to establish sustainable lunar operations as a foundation for deep space missions. The SPACE-H programme is highly selective for passionate entrepreneurs who are dedicated to building a better future. The 13-week schedule, composed of lectures, workshops, one-on-ones with the SPACE-H team and mentors, and a final Demo Day showcase, provides insights into NASA and other space health sector organisations.

“Being one of the few companies selected from a global pool of applications for the SPACE-H program underscores the profound potential impact of our research. Necrosis has been a critical hurdle in scientific advancement, not just on Earth, but also for space exploration. This recognition highlights the potential of our pioneering Anti-Necrotic technology to address critical challenges in long-duration space missions,” said arina Kern, CEO and co-founder of LinkGevity.

“For the first time, we have the potential to block necrosis, opening up game-changing applications in areas crucial for space travel, such as cryopreservation, organoid preservation, artificial organ growth, and kidney protection during these missions.”

LinkGevity’s inclusion in the SPACE-H programme comes as the company prepares to maximise the potential of its anti-necrotics on Earth and in space. Applications of this medical technology include four major areas:

Organoid preservation and growth: Necrosis has hindered the development of complex organoids used in disease modelling and drug screening. LinkGevity’s anti-necrotic technology could enable unprecedented advancements in these fields.

Cryopreservation: Necrosis causes irreversible damage during the freezing and thawing process. LinkGevity’s technology has the potential to prevent this from happening.

Organ growth and preservation: Necrotic cores at the heart of biological structures have, until now, inhibited the lab-based growth and vascularisation of functional tissues and organs. Necrosis is also the primary cause of irreversible damage during organ preservation. LinkGevity’s breakthrough technology could pave the way for organ generation, regeneration and new preservation techniques that could dramatically extend the viability of preserved organs.

Kidney protection: The organs most susceptible to stress, the kidneys, are likely to be the limiting factor in long-duration space missions. LinkGevity’s technology could offer hope for the first viable treatment for space-related kidney injury, as well as acute kidney Injury, a common medical emergency.

“We are thrilled to become part of SPACE-H program, which will accelerate the development of our technology for both terrestrial and space applications,” said Serena Kern-Libera, COO and co-founder of LinkGevity.

“This prestigious program will ensure that our anti-necrotics are able to have the broadest possible impact, aligning with our vision of transforming healthcare. It will be instrumental in ensuring that LinkGevity’s innovations reach their full potential, both in space and on Earth.”

Necrosis has long been a critical barrier in the treatment of chronic and age-related diseases and has hindered advancement in scientific fields such as bioengineering, cryopreservation, and organ preservation. Despite being intensively studied for decades, until now no one has managed to successfully intervene in the necrotic pathway.

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Jim Cornall is editor of Deeptech Digest and publisher at Ayr Coastal Media. He is an award-winning writer, editor, photographer, broadcaster, designer and author. Contact Jim here.