According to a recent computer simulation by Zhenxing Wu and his team from Ohio State University, domestic cats' noses possess convoluted nasal structures that operate similarly to parallel coiled gas chromatographs. Gas chromatography is commonly used in laboratories for precise chemical analysis. The study, published in the open-access journal PLOS Computational Biology, explores the anatomical model of a cat's nose using high-resolution micro-CT scans and computational fluid dynamics modeling.

The research reveals that the convoluted channels within a cat's nose enhance odor detection efficiency, resembling the parallel coiled gas chromatograph design. Unlike amphibians, which typically have a single straight tube for odor detection, cats' nasal structures consist of multiple intricate channels that increase efficiency by up to 100 times.

These findings shed light on the evolutionary advantage of mammals' complex nasal structures, particularly in cats, and offer insights into their superior sense of smell. The researchers draw parallels between the convoluted olfactory turbinate channels in mammalian noses and the coiled cochlea, a sensory organ unique to mammals involved in hearing. They suggest that the convoluted nasal structures serve as a "olfactory cochlea," enhancing the sense of smell in a manner analogous to the cochlea's role in hearing. This discovery contributes to our understanding of mammalian adaptation and their remarkable olfactory capabilities, including those of cats, which play a significant role as pets in diverse environments.