Integrating Stem Cells, Organoids, and Neurons in Hybrid Brain Studies

Author: Columbia University Irving Medical Center
Published: 2024/04/25 - Updated: 2025/09/27
Publication Details: Peer-Reviewed, Experimental Study
Category Topic: Organoids - Academic Publications

Page Content: Synopsis - Introduction - Main - Insights, Updates

Synopsis: This peer-reviewed research from Columbia University represents a groundbreaking advancement in neuroscience through the successful creation of hybrid brains that integrate stem cells, organoids, and neurons from different species. The work demonstrates particular relevance for individuals with neurological conditions, as it addresses fundamental challenges in understanding and treating brain diseases that affect millions of people with disabilities. The research shows promise for improving cell transplantation therapies currently being used for conditions like Parkinson's disease and epilepsy, where researchers are already transplanting stem cells and neurons but lack complete understanding of their effectiveness.

What makes this research especially valuable is its practical approach to solving real-world medical problems - by creating mouse models with functional rat neurons that successfully restored the sense of smell, scientists can now better understand how brain cells integrate and function, potentially accelerating the development of treatments faster than traditional clinical trials. The authoritative nature of this work stems from its peer-reviewed status and publication through Columbia University Irving Medical Center, combined with its novel blastocyst complementation technique that represents a significant methodological advance in the field - Disabled World (DW).

Introduction

If mice ever wonder what it's like to experience the world as a rat, some are now able to live that dream, at least when it comes to the sense of smell.

Main Content

Researchers led by Columbia University's Kristin Baldwin have created mice with hybrid brains - part mouse, part rat - that sense the odors of the world with their rat neurons.

It is the first time that an animal has been able to use the sensory apparatus of another to sense and respond accurately to the world and is one indication of how flexible the brain can be in integrating outside brain cells.

"This research is starting to show us how we can expand the flexibility of a brain so that it can accommodate other kinds of inputs, from human-machine interfaces or transplanted stem cells," says Baldwin, professor of genetics and development at Columbia University Vagelos College of Physicians and Surgeons.

Hybrid Goals

One of the biggest challenges in understanding and treating diseases of the human brain is that it is impossible to fully understand these disorders with current research methods.

"We have beautiful models of cells in dishes and 3D cultures called organoids and they both have their advantages," Baldwin says, "But none of them allow you to determine if the cells are really functioning at the highest level."

Hybrid brains will allow researchers to better understand how brain cells get sick or die and better understand the rules of repairing and replacing parts of the brain.

"Right now, researchers are transplanting stem cells and neurons into people with Parkinson's and epilepsy. But we do not really understand how well that will work," she adds. "With hybrid brain models, we can start to get some answers and at a faster pace than a clinical trial."

Creating Hybrid Brains

Researchers have previously created hybrid brains by injecting neurons or transplanting pea-sized brain organoids from one species into either a developing brain or a fully formed one, either a mouse or rat.

"These experiments have told us that we are somewhat limited in when and how we can add brain cells to an existing brain," Baldwin says. "If the brain has developed to a certain point, the transplanted cells don't necessarily wire together appropriately."

Instead, Baldwin's team introduced rat stem cells into mouse blastocysts, an early stage in development that occurs just hours after fertilization, so that the rat and mouse cells could grow together and integrate on their own.

The technique, called blastocyst complementation, is similar to a technique used to create mice with human immune systems, which have proven to be powerful research tools. But until this study, the technique had not been successful in creating hybrid brains of two different species.

"What we're doing is really cutting edge," Baldwin says.

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Rat Neurons Restore Sense Of Smell In Mice

In the team's first hybrid experiments, they examined where rat neurons appeared in the mouse brain. Rats develop at a slower pace and have bigger brains, but in the mouse, the rat cells followed the mouse's instructions, accelerating their development and making the same kinds of connections as their mouse counterparts.

"You could see rat cells throughout almost the entire mouse brain, which was fairly surprising to us," Baldwin says. "It tells us that there are few barriers to insertion, suggesting that many kinds of mouse neurons can be replaced by a similar rat neuron."

The researchers then looked to see if the rat neurons had been integrated in a functional neural circuit, in this case, part of the olfactory system, which is essential to mice for finding food and avoiding predators. By engineering the mouse embryo to kill or inactivate its own olfactory neurons, the researchers could easily determine if rat neurons had restored the animals' sense of smell.

"We hid a cookie in each mouse cage, and we were very surprised to see that they could find it with the rat neurons," Baldwin says.

Some mice did better at finding the cookie than others, however. The researchers found that mice that retained their own, silenced olfactory neurons, were less successful at finding hidden cookies than mice whose olfactory neurons were engineered to disappear during development.

"This suggests that adding replacement neurons isn't plug and play," Baldwin says. "If you want a functional replacement, you may need to empty out dysfunctional neurons that are just sitting there, which could be the case in some neurodegenerative diseases and also in some neurodevelopmental disorders like autism and schizophrenia."

With the hybrid brain system created by Baldwin's team, researchers can now use the mice to carefully dissect what happened in the different models, which may eventually help improve the success of human cell transplantation.

Primate Hybrids?

One downside of the new hybrid brain system is that the rat cells were randomly distributed in each different animal, a hurdle in extending these studies to other sensory and neural systems in the brain. Baldwin's lab is currently trying to find ways to drive the inserted cells to develop into just one cell type, which may allow for more precise experimentation.

If inserted cells can be constrained in their development within hybrid brains, it could also open the door to creating hybrid brains with primate neurons.

"This would help us get even closer to understanding human disease," Baldwin says.

Columbia University Irving Medical Center (CUIMC)

Columbia University Irving Medical Center is a clinical, research, and educational campus located in New York City. Founded in 1928, CUIMC was one of the first academic medical centers established in the United States of America. CUIMC is home to four professional colleges and schools that provide global leadership in scientific research, health and medical education, and patient care including the Vagelos College of Physicians and Surgeons, the Mailman School of Public Health, the College of Dental Medicine, the School of Nursing.

Insights, Analysis, and Developments

Attribution/Source(s): This peer reviewed publication was selected for publishing by the editors of Disabled World (DW) due to its relevance to the disability community. Originally authored by Columbia University Irving Medical Center and published on 2024/04/25, this content may have been edited for style, clarity, or brevity.