Abstract

Taste perception is a vital sensory process that helps organisms distinguish nutrients from harmful substances. It converts chemical stimuli into electrical signals through receptors on taste receptor cells within taste buds. The five primary taste modalities—sweet, salty, sour, bitter, and umami—are mediated by distinct molecular mechanisms. G-proteincoupled receptors, such as T1R and T2R families, are responsible for sweet, umami, and bitter tastes, while ion channels like epithelial sodium channels and proton-sensitive channels govern salty and sour detection. Electrophysiological techniques like patch-clamp recordings, multi-electrode arrays, and voltage-sensitive imaging have provided insights into the electrical properties of taste cells, neurotransmitter release, and neural coding models. Recent advancements in optogenetics, microfluidic devices, and nanoelectrode arrays have refined our understanding of taste transduction at the cellular and network levels. This review highlights key findings in the electrophysiology of taste, focusing on progress in understanding peripheral and central taste processing. It also discusses emerging technologies and future directions that could further advance the field and address ongoing questions about taste perception.