Our other chemical sense is the sense of smell or olfaction. In contrast to taste cells, which are epithelial derived, olfactory receptor cells are neurons. (See the image above in 12.1). Similar to taste cells, olfactory receptor neurons have a relatively short life span, about 2 months, and must be replaced. The ability to grow in cycles (4 to 8 weeks) places olfactory neurons in a unique class within the nervous system as the only neurons that routinely die and are replaced. Olfactory receptor neurons are located within the olfactory epithelium, a 10 cm2 area located high in the roof of the nasal cavity. Animals with a more highly developed sense of smell have many more olfactory receptors than humans. For example, some dogs have an olfactory epithelium with 100 times as many olfactory receptor neurons covering an area of 170 cm2. Some breeds of dogs can detect the scents of people hours after the person has left the area. The title for all-time best smeller goes to the bear. Black bears have been known to travel 18 miles in a straight line to a food source. African Elephants also have an excellent sense of smell and can detect water up to 12 miles away.
The image above Shows (1) Olfactory bulb; (2) Mitral Cells; (3) Bone; (4) Olfactory Epithelium; (5) Glomerulus; (6) Olfactory neurons
The olfactory epithelia contain millions of olfactory sensory neurons that can detect more than 400,000 different substances, by some estimates, and more than 1.7 trillion, yes 1.7 trillion different smells (Bushdid et al., 2014; Science). As we breathe, chemical odorants are mixed with the air as they pass through the many folds in the nasal passages. In order for us to smell, the odorant must first be dissolved in a thin water-based mucous layer that lines the olfactory epithelium. Dissolved odorants then bind to receptors located within membranes of the receptor cilia of the olfactory neuron (see image above). Olfactory receptors are G protein coupled receptors that activate the enzyme adenylyl cyclase. The activated adenylyl cyclase, in turn, produces cAMP which opens a cation channel, allowing Na+ and Ca2+ to enter the cell. The influx of the positively charged ions depolarizes the membrane triggering an action potential. This in turn can activate voltage gated chloride channels. The concentration gradients and subsequent driving force for chloride is such that it will leave the cell, causing further depolarization.
The olfactory sensory neurons synapse with neurons in the olfactory bulb that extend to the olfactory cortex. Neurons from the olfactory tract pass either to the temporal lobe where the odor is perceived or to areas in the frontal lobe where emotions associated with the odor are generated. These areas are associated with the limbic system and can generate emotional and visceral responses to the smell. Recall that the sense of smell is the only major sense that does not pass through the thalamus. It is considered to be a very primitive sense and is important in emotion and memory. You may have observed an increase in emotional responses to smells during pregnancy. It is thought that the hormones of pregnancy enhance the cortical regions of smell so that the woman becomes more sensitive to certain odors.