Baku, March 10, AZERTAC

UC Santa Cruz neuroscientists aiming to better understand how specific brain connectivity contributes to perception, thoughts, and behavior are leveraging artificial intelligence to enhance their study of brain function, according to Medical Xpress.

By integrating AI, they are streamlining the process of aligning thin slices of mouse brain tissue with a reference atlas, helping to identify key details such as the brain region of origin more efficiently.

The cutting-edge technology was developed by Alec Soronow while he was a student at UC Santa Cruz. He began the project as an undergraduate in the lab of Euiseok Kim, a professor of molecular, cell, and developmental biology, and he continued to work with Kim until the digital tool was built and ready for use.

Soronow named the desktop application Bell Jar, after the semi-autobiographical novel by Sylvia Plath about a young woman's mental breakdown and recovery, which Soronow was reading while working on the initial version of the software. He and Kim have shared Bell Jar with their peers through an article published in the open-access journal eNeuro.

In academia, undergraduates occasionally see research projects through from inception to a notable publication that contributes to the broader scientific community. But it is nonetheless inspiring when that does happen, Kim said.

Bell Jar offers a valuable tool for neuroscientists, making neuroanatomy analysis more accessible and efficient. For years, researchers have struggled with the limitations of existing tools designed to analyze neural connectivity—many of them developed in MATLAB or other specialized software environments that eventually became outdated or inaccessible due to software updates.

Moreover, previous methods faced challenges in effectively integrating machine learning (ML), restricting their flexibility and accuracy. Bell Jar differentiates itself by leveraging ML techniques to improve accuracy and efficiency.

Bell Jar was born of necessity. In the Kim Neuroscience Lab's ongoing research into brain connectivity, analyzing an entire mouse brain manually was at times tedious. To prepare brain samples for analysis, researchers perform a process known as histology. This involves slicing the brain into incredibly thin sections, much like a deli slicer cuts thin slices of meat.

However, human error is inevitable: sections may be slightly too thick, too thin, or damaged in some way. When analyzing these slices, researchers must then compare them to a reference atlas, often making subjective decisions about how to align and interpret the data.

Training new students to perform these analyses can also be difficult, as it requires a deep understanding of neuroanatomy. But with Bell Jar, many of these burdens are lightened.

"It enables far more efficient analysis of large experimental datasets that would otherwise have to be looked over extensively by hand," Soronow said. "Also, reducing the time to results lets a lab more quickly assess if the experiments being conducted are working and if adjustments are needed—enabling higher throughput science."

To drive this point home, Soronow said, "For a standard experiment in our lab, it saves us about three weeks of manual alignment and counting time per brain."

Soronow won a Dean's Award from the Baskin School of Engineering in 2022 for the Bell Jar project and graduated that year with a B.S. in biomolecular engineering and bioinformatics, then earned an M.S. in molecular, cell, and developmental biology in 2024.

He has since started his own company, PlusTen Intelligence, which is trying to bring the power of neurons to industrial applications by combining AI and engineered neuron-like cells to be powerful sensors for specific molecular targets that fit into a handheld device.

"I'm able to use the unique skill set cultivated in the Kim lab," Soronow said, "combining wet lab, genetic engineering, innovative software design, and hardware design."

Kim said the creation of Bell Jar aligns perfectly with the broader research objectives of his lab. By improving efficiency and accuracy, researchers can focus on the bigger picture: understanding brain connectivity and neural function.

"This tool allows us to conduct research more quickly and effectively," Kim said. "That is the main point here."