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New research from the聽College of Osteopathic Medicine聽(NYITCOM) could help explain how the sense of smell is impacted in individuals with autism.聽

Individuals with autism have an 鈥渋nsistence on sameness,鈥� and often avoid unfamiliar elements, including new smells and foods, which can impact their quality of life. While many studies have focused on the behavioral features of autism, additional research is needed to help explain its sensory aspects.

A study led by Assistant Professor of Biomedical Sciences聽Gonzalo Otazu, Ph.D., published in the journal聽, analyzes a mouse model of autism and reports differences in the neurological processes responsible for smell.

The team trained two groups of mice鈥攐ne group with a mutation in a gene linked to autism (CNTNAP2 knockout mice) and one neurotypical group鈥攖o recognize familiar scents. When they successfully identified the target scent, the mice were rewarded with a sip of water. Both groups succeeded in identifying the target. Then the mice were given a more challenging task: identifying target scents while unfamiliar odors were introduced in the background. Otazu, an electrical engineer, likens this task to Internet captchas, which require humans to visually identify letters and numbers set in a busy or obscured background. While the neurotypical mice were able to 鈥渇ilter out鈥� new background odors and identify the target scents, the CNTNAP2 knockout mice struggled to do so. 

To better understand where the processing error was occurring in the brains of the CNTNAP2 knockout mice, the researchers visualized the neural activity at the input of each animal鈥檚 olfactory bulb, the part of the brain that first processes smell. An imaging technique called intrinsic optical imaging was used to visualize neural activity near the surface of the olfactory bulb. Here, 鈥渟cent signals鈥� are transmitted to other parts of the brain for further processing, playing a key role in how the brain computes smell.

However, the input signals were very similar between the CNTNAP2 knockout mice and neurotypical mice. This finding suggests that scent processing in the autism model was impaired at a later step鈥攁fter signals were processed at the olfactory bulb input.

This result was also replicated when the researchers 鈥渞everse-engineered鈥� the brain鈥檚 processes for identifying target scents in unfamiliar backgrounds.

Leveraging machine learning, a form of artificial intelligence that uses algorithms to replicate the brain鈥檚 processes, the team applied the olfactory bulb input signals to a sophisticated algorithm that matched the high-performance brain computing used by neurotypical mice. Once again, despite having very similar olfactory bulb input signals, the algorithm replicated the same outcome: neurotypical mice filtered out novel background scents and identified targets, but this complex processing was impaired in CNTNAP2 knockout mice.

鈥淲e speculate that the olfactory bulbs in the mouse model of autism might be more easily overwhelmed by processing new background odors,鈥� said Otazu. 鈥淭hese findings illustrate why more studies related to the sensory aspect of autism are so important. By documenting the neural processes in the mouse model of autism, our findings may help to explain the brain circuitry of humans with autism and one day lead to advancements that improve these individuals鈥� quality of life.鈥�

The study鈥檚 other researchers include NYITCOM Associate Professor聽Raddy Ramos, Ph.D., Senior Research Associate Yan Li, Ph.D., and many former medical students and students from the College of Arts and Sciences: Syed Asim Ahmed (B.S.鈥�19), Michael Castellano (D.O. 鈥�22), Jared Cohn (D.O. 鈥�22), Daniel Mogel (D.O. 鈥�21), Asiyah Rahman (D.O. 鈥�21), James San Miguel (D.O. 鈥�22), Nikesh Shah (D.O. 鈥�22), Reema Shah (D.O. 鈥�22), Naveen Sharma (D.O. 鈥�22), Tianyu She (D.O. 鈥�21), Mitchell Swerdloff (D.O. 鈥�22), and Jason Wu (D.O. 鈥�21).