While debate exists among neurologists as to the specific number of senses due to differing definitions of what constitutes a
sense,
Gautama Buddha and
Aristotle classified five 'traditional' human senses which have become universally accepted:
touch,
taste,
smell,
vision, and
hearing. Other senses that have been well-accepted in most mammals, including humans, include
pain,
balance,
kinaesthesia, and
temperature. Furthermore, some nonhuman animals have been shown to possess alternate senses, including
magnetoreception and
electroreception.
Receptors The initialization of sensation stems from the response of a specific receptor to a physical stimulus. The receptors which react to the stimulus and initiate the process of sensation are commonly characterized in four distinct categories:
chemoreceptors,
photoreceptors,
mechanoreceptors, and
thermoreceptors. All receptors receive distinct physical stimuli and transduce the signal into an electrical
action potential. This action potential then travels along
afferent neurons to specific brain regions where it is processed and interpreted.
Chemoreceptors Chemoreceptors, or chemosensors, detect certain chemical stimuli and transduce that signal into an electrical action potential. The two primary types of chemoreceptors are: • Distance chemoreceptors are integral to receiving stimuli in
gases in the
olfactory system through both olfactory receptor neurons and neurons in the
vomeronasal organ. • Direct chemoreceptors that detect stimuli in
liquids include the
taste buds in the
gustatory system as well as receptors in the
aortic bodies which detect changes in
oxygen concentration.
Photoreceptors Photoreceptors are neuron cells and are specialized units that play the main role in initiating vision function. Photoreceptors are light-sensitive cells that capture different wavelengths of light. Different types of photoreceptors are able to respond to the varying light wavelengths in relation to color, and transduce them into electrical signals. Photoreceptors are capable of
phototransduction, a process which converts light (
electromagnetic radiation) into, among other types of
energy, a
membrane potential. There are five compartments that are present in these cells. Each compartment corresponds to differences in function and structure. The first compartment is the outer segment (OS), where it is responsible for capturing light and transducing it. The second compartment is the inner segment (IS), which includes the necessary organelles that function in cellular metabolism and biosynthesis. Mainly, these organelles include mitochondria, Golgi apparatus, and endoplasmic reticulum, among others. The third compartment is the connecting cilium (CC). As its name suggests, CC works to connect the OS and the IS regions together for the purpose of essential protein trafficking. The fourth compartment contains the nucleus and is a continuation of the IS region, known as the nuclear region. Finally, the fifth compartment is the synaptic region, where it acts as a final terminal for the signal, consisting of synaptic vesicles. In this region, glutamate neurotransmitter is transmitted from the cell to secondary neuron cells. The three primary types of photoreceptors are:
cones are photoreceptors which respond significantly to
color. In humans, the three different types of cones correspond with a primary response to short wavelength (blue), medium wavelength (green), and long wavelength (yellow/red).
Rods are photoreceptors which are very sensitive to the intensity of light, allowing for vision in dim lighting. The concentrations and ratio of rods to cones is strongly correlated with whether an animal is
diurnal or
nocturnal. In humans, rods outnumber cones by approximately 20:1, while in nocturnal animals, such as the
tawny owl, the ratio is closer to 1000:1. These photosensitive ganglia play a role in conscious vision for some animals, and are believed to do the same in humans.
Mechanoreceptors Mechanoreceptors are sensory receptors which respond to mechanical forces, such as
pressure or
distortion. While mechanoreceptors are present in
hair cells and play an integral role in the
vestibular and
auditory systems, the majority of mechanoreceptors are
cutaneous and are grouped into four categories: •
Slowly adapting type 1 receptors have small receptive fields and respond to static stimulation. These receptors are primarily used in the sensations of
form and
roughness. •
Slowly adapting type 2 receptors have large receptive fields and respond to stretch. Similarly to type 1, they produce sustained responses to a continued stimuli. •
Rapidly adapting receptors have small receptive fields and underlie the perception of slip. •
Pacinian receptors have large receptive fields and are the predominant receptors for high-frequency vibration.
Thermoreceptors Thermoreceptors are sensory receptors which respond to varying
temperatures. While the mechanisms through which these receptors operate is unclear, recent discoveries have shown that
mammals have at least two distinct types of thermoreceptors: • The end-bulb of Krause or
bulboid corpuscle detects temperatures above body temperature. •
Ruffini's end organ detects temperatures below body temperature. TRPV1 is a heat-activated channel that acts as a small heat detecting thermometer in the membrane which begins the polarization of the neural fiber when exposed to changes in temperature. Ultimately, this allows us to detect ambient temperature in the warm/hot range. Similarly, the molecular cousin to TRPV1, TRPM8, is a cold-activated ion channel that responds to cold. Both cold and hot receptors are segregated by distinct subpopulations of sensory nerve fibers, which shows us that the information coming into the spinal cord is originally separate. Each sensory receptor has its own "labeled line" to convey a simple sensation experienced by the recipient. Ultimately, TRP channels act as thermosensors, channels that help us to detect changes in ambient temperatures.
Nociceptors Nociceptors respond to potentially damaging stimuli by sending signals to the spinal cord and brain. This process, called
nociception, usually causes the perception of
pain. They are found in internal organs, as well as on the surface of the body. Nociceptors detect different kinds of damaging stimuli or actual damage. Those that only respond when tissues are damaged are known as "sleeping" or "silent" nociceptors. • Thermal nociceptors are activated by noxious heat or cold at various temperatures. • Mechanical nociceptors respond to excess pressure or mechanical deformation. • Chemical nociceptors respond to a wide variety of chemicals, some of which are signs of tissue damage. They are involved in the detection of some spices in food. == Sensory cortex ==