Rice researchers will collaborate with Houston health tech startup Motif Neurotech to develop Brain Mesh, a distributed network of minimally invasive implants in the skull. Photo via Motif Neurotech

Houston startup Motif Neurotech and several Rice research groups have been selected by the United Kingdom's Advanced Research + Invention Agency (ARIA) to participate in its inaugural Precision Neurotechnologies program. The program aims to develop advanced brain-interfacing technologies for cognitive and psychiatric conditions.

ARIA will invest $84.2 million over four years in projects that “explore and unlock new methods to interface with the human brain at the circuit level,” according to a news release.

Three of the four Rice labs will collaborate with Houston health tech startup Motif Neurotech to develop Brain Mesh, which is a distributed network of minimally invasive implants that can stimulate neural circuits and stream neural data in real time. The project has been awarded approximately $5.9 million.

Motif Neurotech was spun out of the Rice lab of Jacob Robinson, a professor of electrical and computer engineering and bioengineering and CEO of Motif Neurotech. It will be developed in collaboration with U.K.-based startup MintNeuro, which will help develop custom integrated circuits that will help to miniaturize the implants, according to a separate release.

Robinson will lead the system and network integration and encapsulation efforts for Mesh Points implants. According to Rice, these implants, about the size of a grain of rice, will track and modulate brain states and be embedded in the skull through relatively low-risk surgery.

The Rice lab of Valentin Dragoi, professor of electrical and computer engineering at Rice and the Rosemary and Daniel J. Harrison III Presidential Distinguished Chair in Neuroprosthetics at Houston Methodist, will conduct non-human primate experimental models for Brain Mesh. Kaiyuan Yang, associate professor of electrical and computer engineering who leads the Secure and Intelligent Micro-Systems Lab at Rice, will work on power and data pipeline development to enable the functional miniaturization of the Mesh Points.

“Current neurotechnologies are limited in scale, specificity and compatibility with human use,” Robinson said in a news release. “The Brain Mesh will be a precise, scalable system for brain-state monitoring and modulation across entire neural circuits designed explicitly for human translation. Our team brings together a key set of capabilities and the expertise to not only work through the technical and scientific challenges but also to steward this technology into clinical trials and beyond.”

The fourth Rice lab, led by assistant professor of electrical and computer engineering Jerzy Szablowski, will collaborate with researchers from three universities and two industry partners to develop closed-loop, self-regulating gene therapy for dysfunctional brain circuits. The team is backed by an award of approximately $2.3 million.

“Our goal is to develop a method for returning neural circuits involved in neuropsychiatric illnesses such as epilepsy, schizophrenia, dementia, etc. to normal function and maybe even make them more resilient,” Szablowski said in a news release.

Neurological disorders in the U.K. have a roughly $5.4 billion economic burden, and some estimates run as high as $800 billion annually in terms of economic disruptions in the U.S. These conditions are the leading cause of illness and disability with over one in three people impacted according to the World Health Organization.

Ad Placement 300x100
Ad Placement 300x600

CultureMap Emails are Awesome

Axiom Space-tested cancer drug advances to clinical trials

mission critical

A cancer-fighting drug tested aboard several Axiom Space missions is moving forward to clinical trials.

Rebecsinib, which targets a cancer cloning and immune evasion gene, ADAR1, has received FDA approval to enter clinical trials under active Investigational New Drug (IND) status, according to a news release. The drug was tested aboard Axiom Mission 2 (Ax-2) and Axiom Mission 3 (Ax-3). It was developed by Aspera Biomedicine, led by Dr. Catriona Jamieson, director of the UC San Diego Sanford Stem Cell Institute (SSCI).

The San Diego-based Aspera team and Houston-based Axiom partnered to allow Rebecsinib to be tested in microgravity. Tumors have been shown to grow more rapidly in microgravity and even mimic how aggressive cancers can develop in patients.

“In terms of tumor growth, we see a doubling in growth of these little mini-tumors in just 10 days,” Jamieson explained in the release.

Rebecsinib took part in the patient-derived tumor organoid testing aboard the International Space Station. Similar testing is planned to continue on Axiom Station, the company's commercial space station that's currently under development.

Additionally, the drug will be tested aboard Ax-4 under its active IND status, which was targeted to launch June 25.

“We anticipate that this monumental mission will inform the expanded development of the first ADAR1 inhibitory cancer stem cell targeting drug for a broad array of cancers," Jamieson added.

According to Axiom, the milestone represents the potential for commercial space collaborations.

“We’re proud to work with Aspera Biomedicines and the UC San Diego Sanford Stem Cell Institute, as together we have achieved a historic milestone, and we’re even more excited for what’s to come,” Tejpaul Bhatia, the new CEO of Axiom Space, said in the release. “This is how we crack the code of the space economy – uniting public and private partners to turn microgravity into a launchpad for breakthroughs.”

Chevron enters the lithium market with major Texas land acquisition

to market

Chevron U.S.A., a subsidiary of Houston-based energy company Chevron, has taken its first big step toward establishing a commercial-scale lithium business.

Chevron acquired leaseholds totaling about 125,000 acres in Northeast Texas and southwest Arkansas from TerraVolta Resources and East Texas Natural Resources. The acreage contains a high amount of lithium, which Chevron plans to extract from brines produced from the subsurface.

Lithium-ion batteries are used in an array of technologies, such as smartwatches, e-bikes, pacemakers, and batteries for electric vehicles, according to Chevron. The International Energy Agency estimates lithium demand could grow more than 400 percent by 2040.

“This acquisition represents a strategic investment to support energy manufacturing and expand U.S.-based critical mineral supplies,” Jeff Gustavson, president of Chevron New Energies, said in a news release. “Establishing domestic and resilient lithium supply chains is essential not only to maintaining U.S. energy leadership but also to meeting the growing demand from customers.”

Rania Yacoub, corporate business development manager at Chevron New Energies, said that amid heightening demand, lithium is “one of the world’s most sought-after natural resources.”

“Chevron is looking to help meet that demand and drive U.S. energy competitiveness by sourcing lithium domestically,” Yacoub said.

---

This article originally appeared on EnergyCapital.