Sensation – Anatomy, Types, Functions

Sensation – Anatomy, Types, Functions

sensation is a physical feeling. Floating can be a very pleasant sensation. A sensation of burning or tingling may be experienced in the hands. [ + of] Synonyms are feeling, sense, impression, perception More Synonyms of sensation.

sense is a biological system used by an organism for sensation, the process of gathering information about the world and responding to stimuli. Although traditionally around five human senses were known (namely sight, smell, touch, taste, and hearing), it is now recognized that there are many more. Senses used by other non-human organisms are even greater in variety and number. During sensation, sense organs collect various stimuli (such as a sound or smell) for transduction, meaning transformation into a form that can be understood by the brain. Sensation and perception are fundamental to nearly every aspect of an organism’s cognition, behavior and thought.

Overview of Sensation

Sensation refers to our ability to detect or sense the physical qualities of our environment.

Key Points

Sensation refers to our ability to detect and sense the internal and external physical qualities of our environment.

Our senses include both exteroception (stimuli that occur outside of our body) and interoception (stimuli occurring inside of our bodies).

Our primary senses are considered to be sight, hearing, taste, smell, and touch.

All senses require one of four fundamental sensory capacities: chemoreception, photoreception, mechanoreception, or chemoreception.

The peripheral nervous system (PNS) consists of sensory receptors to communicate with other parts of the body.

Key Terms

chemoreception: A physiological response to chemical stimuli.

mechanoreception: A physiological response to mechanical forces like pressure, touch, and vibration.

photoreception: A physiological response to light, as occurs during a vision in animals.

chemoreception: A physiological response to relative or absolute changes in temperature.

Our senses can be broadly grouped into exteroception, for the detection of stimuli that occur outside of our body, and interoception, for stimuli occurring inside of our bodies. However, what constitutes a sense is a matter of great debate, leading to difficulties in precisely defining what it is. Traditionally, human beings are considered to have five main senses: sight, hearing, taste, smell, and touch.

The peripheral nervous system (PNS) consists of sensory receptors that extend from the central nervous system (CNS) to communicate with other parts of the body. These receptors respond to changes and stimuli in the environment. Sense organs (made up of sensory receptors and other cells ) operate the senses of vision, hearing, equilibrium, smell, and taste.

Sight

Sight or vision (ophthalmoception) is the ability of the eye(s) to focus and detect images of visible light on photoreceptors in the retina that generate electrical nerve impulses for varying colors, hues, and brightness. There are two types of photoreceptors: rods and cones. Rods are very sensitive to light but do not distinguish colors. Cones distinguish colors but are less sensitive to dim light. The inability to see is called blindness.

Hearing

Hearing or audition (audio option) is the sense of sound perception. Mechanoreceptors in the inner ear turn vibration motion into electrical nerve pulses. The vibrations are mechanically conducted from the eardrum through a series of tiny bones to hair-like fibers in the inner ear that detect the mechanical motion of the fibers.

Sound can also be detected as vibrations conducted through the body by a tactician. The inability to hear is called deafness or hearing impairment.

Taste6

Taste (gustaoception) refers to the ability to detect substances such as food, certain minerals, poisons, etc. The sense of taste is often confused with the concept of flavor, which is a combination of taste and smell perception. The flavor depends on odor, texture, and temperature as well as on taste.

Humans receive tastes through sensory organs called taste buds, or gustatory calyculi, concentrated on the upper surface of the tongue. Five basic tastes exist: sweet, bitter, sour, salty, and umami. The inability to taste is called ageusia.

Smell

The olfactory system is the sensory system used for the sense of smell (olfaction). This sense is mediated by specialized sensory cells of the nasal cavity.  In humans, olfaction occurs when odorant molecules bind to specific sites on the olfactory receptors in the nasal cavity. These receptors are used to detect the presence of smell. They come together at a structure (the glomerulus) that transmits signals to the olfactory bulb in the brain. The inability to smell is called anosmia.

Touch

Touch or somatosensation (tactioception, tactician, or mechanoreception), is a perception resulting from the activation of neural receptors in the skin, including hair follicles, tongue, throat, and mucosa. A variety of pressure receptors respond to variations in pressure (firm, brushing, sustained, etc.).

The touch sense of itching is caused by insect bites or allergies that involve special itch-specific neurons in the skin and spinal cord. The loss or impairment of the ability to feel anything touched is called tactile anesthesia.

Paresthesia is a sensation of tingling, pricking, or numbness of the skin that may result from nerve damage and may be permanent or temporary.

Types of Sensation

A third sensory modality requires cortical analysis to provide a more complex interpretation of primary sensory information. All three types of sensation should be evaluated in every patient examined.

Exteroceptive sensation (also termed superficial sensation): receptors in the skin and mucous membranes

Tactile or touch sensation (thigmesthesia):

  • Anesthesia: absence of touch appreciation
  • Hypoesthesia: decrease of touch appreciation
  • Hyperesthesia: exaggeration of touch sensation, which is often unpleasant
  • (Terms above are unfortunately used indiscriminately to apply to losses of all types of sensation. They are not specific for loss of tactile sensation.)

Pain sensation (algesia):

  • Analgesia: absence of pain appreciation
  • Hypoalgesia: decrease of pain appreciation
  • Hyperalgesia: exaggeration of pain appreciation, which is often unpleasant

Temperature sensation, both hot and cold (thermesthesia):

  • Thermanalgesia: absence of temperature appreciation
  • Thermhypesthesia: decrease of temperature appreciation
  • Thermhyperesthesia: exaggeration of temperature sensation, which is often unpleasant

Sensory perversions :

  • Paresthesia: abnormal sensations perceived without specific stimulation. They may be tactile, thermal, or painful; episodic or constant.
  • Dysesthesia: painful sensations elicited by a nonpainful cutaneous stimulus such as a light touch or gentle stroking over affected areas of the body. Sometimes referred to as hyperpathia or hyperalgesia. Often perceived as intense burning, dysesthesias may outlast the stimulus by several seconds.

Proprioceptive sensation (also termed deep sensation): receptors located in muscles, tendons, ligaments, and joints

  • Joint position sense (arthresthesia): Absence is described as such
  • Vibratory sense (pallesthesia): Absence is described as such
  • Kinesthesia: perception of muscular motion. Usually not measured in routine clinical evaluation.

Cortical sensory functions: interpretative sensory functions that require analysis of individual sensory modalities by the parietal lobes to provide discrimination. Individual sensory modalities must be intact to measure cortical sensation.

  • Stereognosis: the ability to recognize and identify objects by feeling them. The absence of this ability is termed astereognosis.
  • Graphesthesia: ability to recognize symbols written on the skin. The absence of this ability is termed graphanesthesia.
  • Two-point discrimination: ability to recognize simultaneous stimulation by two blunt points. Measured by the distance between the points required for recognition. Absence is described as such.
  • Touch localization (topognosis): ability to localize stimuli to parts of the body. Topagnosia is the absence of this ability.
  • Double simultaneous stimulation: ability to perceive a sensory stimulus when corresponding areas on the opposite side of the body are stimulated simultaneously. Loss of this ability is termed sensory extinction.

Additional Senses

Many scientists and philosophers argue that humans have additional senses including:

  • Pain or nociception (physiological pain): Signals nerve and other tissue damage.
  • Balance or equilibrioception: Allows the sensing of body movement, direction, and acceleration, and to attain and maintain postural equilibrium and balance.
  • Body awareness or proprioception: Provides the parietal cortex of the brain with information on the relative positions of the parts of the body.
  • Sense of time or conception: This refers to how the passage of time is perceived and experienced but is not associated with a specific sensory system. According to psychologists and neuroscientists, however, human brains have a system governing the perception of time.
  • Temperature sensing or thermoception: The sensation of heat and the absence of heat (cold).
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If interoceptive senses are also considered, the sensation can be expanded to include stretch (as in muscles or organs like the lungs), oxygen and carbon dioxide sensing, pH sensing, and more.

While the exact definition of sensation is still controversial, most scientists agree that all senses rely on four fundamental sensory capacities:

  • Chemical detection (chemoreception).
  • Light detection (photoreception).
  • Force detection (mechanoreception).
  • Temperature detection (chemoreception).

Our nervous system has sensory systems and organs that mediate each sense and these systems rely on chemoreceptors, photoreceptors, mechanoreceptors, or thermoreceptors to detect the state of the internal or external environment.

Other internal sensations and perceptions

An internal sensation and perception also known as interoception[rx] is “any sense that is normally stimulated from within the body”.[rx] These involve numerous sensory receptors in internal organs. Interoception is thought to be atypical in clinical conditions such as alexithymia.[rx] Some examples of specific receptors are:

  • Hunger is governed by a set of brain structures (e.g., the hypothalamus) that are responsible for energy homeostasis.[rx]
  • Pulmonary stretch receptors are found in the lungs and control the respiratory rate.
  • Peripheral chemoreceptors in the brain monitor the carbon dioxide and oxygen levels in the brain to give a perception of suffocation if carbon dioxide levels get too high.[52]
  • The chemoreceptor trigger zone is an area of the medulla in the brain that receives inputs from blood-borne drugs or hormones and communicates with the vomiting center.
  • Chemoreceptors in the circulatory system also measure salt levels and prompt thirst if they get too high; they can also respond to high blood sugar levels in diabetics.
  • Cutaneous receptors in the skin not only respond to touch, pressure, temperature and vibration, but also respond to vasodilation in the skin such as blushing.
  • Stretch receptors in the gastrointestinal tract sense gas distension that may result in colic pain.
  • Stimulation of sensory receptors in the esophagus results in sensations felt in the throat when swallowing, vomiting, or acid reflux.
  • Sensory receptors in pharynx mucosa, similar to touch receptors in the skin, sense foreign objects such as mucous and food that may result in a gag reflex and corresponding gagging sensation.
  • Stimulation of sensory receptors in the urinary bladder and rectum may result in perceptions of fullness.
  • Stimulation of stretch sensors that sense dilation of various blood vessels may result in pain, for example headache caused by vasodilation of brain arteries.
  • Cardioversion refers to the perception of the activity of the heart.[rx][rx][rx][rx]
  • Opsins and direct DNA damage in melanocytes and keratinocytes can sense ultraviolet radiation, which plays a role in pigmentation and sunburn.
  • Baroreceptors relay blood pressure information to the brain and maintain proper homeostatic blood pressure.

The perception of time is also sometimes called a sense, though not tied to a specific receptor.

These are five closeup, black and white photographs of an ear, eye, tongue, nose, and hand.

The five senses: Photographic depiction of the five senses.

Sensation to Perception

The goal of sensation is detection, while the goal of perception is to create useful information about our environment.

Key Points

  • The sensation is a function of the low-level, biochemical, and neurological mechanisms that allow the receptor cells of a sensory organ to detect an environmental stimulus.
  • Perception refers to the mental processes that represent the understanding of the real-world causes of sensory input.
  • Neural signals are transmitted to the brain and processed; the resulting mental recreation of the distal stimulus is the percept. Perception is particularly important to our ability to understand speech. After processing the initial auditory signal, speech sounds are further processed to extract acoustic cues and phonetic information.

Key Terms

Perception: The organization, identification, and interpretation of sensory information in order to construct a mental representation through the process of transduction, during which sensors in the body transform signals from the environment into encoded neural signals.

reverberation: The persistence of sound after a sound is produced (such as an echo).

transduction: The conversion of a stimulus from one form to another.

sensation: The function of the low-level biochemical and neurological events that occur when a stimulus activates the receptor cells of a sensory organ.

Sensation and perception are two distinct stages of processing during human sensing. The sensation is a function of the low level, biochemical, and neurological mechanisms that allow the receptor cells of a sensory organ to detect an environmental stimulus.

Stimuli from the environment (distal stimuli) are transformed into neural signals, which are then interpreted by the brain through a process called transduction. Transduction can be likened to a bridge connecting sensation to perception. This raw pattern of neural activity is called the proximal stimulus. Perception refers to the mental processes that are reflected in statements like “I see a blue wall” that represent the understanding of the real-world causes of sensory input. In other words, the goal of sensation is detection, while the goal of perception is to create useful information about the environment.

The neural signals are transmitted to the brain and processed. The resulting mental recreation of the distal stimulus is the percept. The sound stimulating a person’s auditory receptors is the proximal stimulus, and the brain’s interpretation of this as the ringing of a telephone is the percept.

All perception involves signals in the nervous system that result from physical stimulation of the sense organs. For example, vision involves light striking the retinas of the eyes, the smell is mediated by odor molecules, and hearing involves sound waves.

However, perception is not the passive receipt of these signals but is a process of organization, identification, and interpretation. Although the senses were traditionally viewed as passive receptors, the study of illusions and ambiguous images has demonstrated that the brain’s perceptual systems actively influence sensory systems in an attempt to construct useful representations of our environment.

These are drawings of the Necker cube and Rubin vase illusions. These are two optical illusions that illustrate how perception may differ from reality. In the Necker cube, we see a cube when in fact it is a flat image on our screen. In the Rubin vase, the vase actually resembles two faces looking at each other.

The Necker cube and Rubin vase: These are two optical illusions that illustrate how perception may differ from reality. On the left, we see a cube when in fact it is a flat image on our screen. On the right, the vase actually resembles two faces looking at each other.

Perception is particularly important to our ability to understand speech. The sound of a word can vary widely according to the words around it and the tempo of the speech, as well as the physical characteristics, accent, and mood of the speaker. Listeners manage to perceive words across this wide range of different conditions. Another variation is that reverberation can make a large difference in sounds, such as hearing a word spoken from the far side of a room and the same word spoken up close. The process of perceiving speech begins at the level of the sound within the auditory signal and the process of audition. After processing the initial auditory signal, speech sounds are further processed to extract acoustic cues and phonetic information. This speech information can then be used for higher-level language processes, such as word recognition.

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Sensory Modalities

A sensory modality (also called a stimulus modality) is an aspect of a stimulus or what is perceived after a stimulus.

Key Points

  • The basic sensory modalities include light, sound, taste, temperature, pressure, and smell.
  • A broadly acceptable definition of a sense is A system that consists of a group of sensory cell types, responding to a specific physical phenomenon, and corresponding to a particular group of regions within the brain where the signals are received and interpreted.
  • Multimodal perception is the ability of the mammalian nervous system to combine different inputs of the sensory system. Nociception (physiological pain ) signals nerve damage or damage to tissue. The three types of pain receptors are cutaneous (skin), somatic (joints and bones), and visceral (body organs ).
  • Proprioception, the kinesthetic sense, provides the parietal cortex of the brain with information on the relative positions of the parts of the body.

Key Terms

chemoreception: A physiological response to relative or absolute changes in temperature.

modality: Also known as stimulus modality, it is one feature of a complex stimulus; for example, temperature, pressure, sound, or taste.

utricle: Stimulates hair cells of the inner ear to detect motion and orientation.

saccule: A bed of sensory cells situated in the inner ear that translates head movements into neural impulses that the brain can interpret.

circadian: Any biological process that displays an endogenous, entrainable oscillation of about 24 hours.

ultradian: A recurrent period or cycle repeated throughout a 24-hour circadian day.

mechanoreception: A physiological response to mechanical forces like pressure, touch, and vibration.

bipolar cell: Specialized sensory neuron for the transmission of special senses.

Sensing

Senses are transducers from the physical world to the realm of the mind. Another broadly acceptable definition of a sense is a system that consists of a group of sensory cell types, responding to a specific physical phenomenon, and corresponding to a particular group of regions within the brain where the signals are received and interpreted.

Disputes about the number of senses typically arise around the classification of the various cell types and their mapping to regions of the brain.

Sensory Modalities

A sensory modality (also called a stimulus modality) is an aspect of a stimulus or what is perceived after a stimulus. The term sensory modality is often used interchangeably with sense. The basic sensory modalities include light, sound, taste, temperature, pressure, and smell.

Light Modality

The sensory modality for vision is light. To perceive a light stimulus, the eye must first refract the light so that it directly hits the retina. The transduction of light into neural activity occurs via the photoreceptors in the retina.

When a particle of light hits the photoreceptors of the eye, the photopigment of the photoreceptor undergoes a chemical change leading to a chain of chemical reactions occur. A message is sent to a neuron called the bipolar cell through the use of a nerve impulse. Finally, a message is sent to the ganglion cell and then, finally, the brain.

Sound Modality

The sensory modality for audition is sound. Sound is created through air pressure. A vibrating object compresses the surrounding molecules of air as it moves towards a given point, and expands the molecules as it moves away from the point.

The eardrum is stimulated by vibrations in the air. It collects and sends these vibrations to receptor cells. The ossicles (three tiny bones in the middle ear) pass the vibrations to the fluid-filled cochlea (a spiral, shell-shaped auditory organ of the inner ear ). The vibrations move through the liquid in the cochlea where the receptive organ is able to sense it.

Taste Modality

Taste stimuli are encountered by receptor cells located in taste buds on the tongue and pharynx. Receptor cells disseminate onto different neurons and convey the message of a particular taste in a single medullar nucleus.

Taste perception is created by combining multiple sensory inputs. Different modalities help determine the perception of taste.

Temperature Modality

Temperature modality excites or elicits a symptom through cold or hot temperature. The cutaneous somatosensory system detects changes in temperature.

Thermal stimuli from a homeostatic set point excite temperature-specific sensory nerves in the skin. Specific thermosensory fibers respond to warmth and too cold.

Pressure Modality

Tactile stimulation can be direct, such as through bodily contact, or indirect, such as through the use of a tool or probe. Tactual perception gives information regarding cutaneous stimuli (pressure, vibration, and temperature), kinesthetic stimuli (limb movement), and proprioceptive stimuli (position of the body).

Smell Modality

The sense of smell is called olfaction. Materials constantly shed molecules, which float into the nose or are taken in through breathing. Inside the nasal chambers is the neuroepithelium lining.

It contains the receptors responsible for detecting molecules that are small enough to smell. These receptor neurons then synapse at the olfactory cranial nerve, which sends the information to the olfactory bulbs in the brain for initial processing.

Multimodal Perception

Multimodal perception is the ability of the mammalian nervous system to combine all of the different inputs of the sensory system to result in an enhanced detection or identification of a particular stimulus.

Integration of all sensory modalities occurs when multimodal neurons receive sensory information that overlaps with different modalities. Multimodal perception comes into effect when a unimodal stimulus fails to produce a response.

This is a diagram of how multimodal perception is created by the overlapping and combining of different inputs from the visual, auditory, and somatosensory systems, each labeled in its own box. Inside each box are the organs and their locations that are connected to the sensory system, with all three boxes being connected to a red dot in the center, labeled multisensory.

Multisensory perception: This is a diagram of how multimodal perception is created by the overlapping and combining of different inputs from the sensory systems.

Additional Senses

Balance (or equilibrioception) is the sense that allows an organism to sense body movement, direction, and acceleration, and also attain and maintain postural equilibrium and balance. The organ of equilibrioception is the vestibular labyrinthine system found in both of the inner ears.

In technical terms, this organ is responsible for two senses: angular momentum and acceleration (known together as equilibrioception). The vestibular nerve conducts information from sensory receptors in three ampullae, each of which senses fluid motion in three semicircular canals caused by a three-dimensional rotation of the head.

The vestibular nerve also conducts information from the utricle and the saccule; these contain hair-like sensory receptors that bend under the weight of otoliths (small crystals of calcium carbonate) that provide the inertia needed to detect head rotation, linear acceleration, and the direction of gravitational force.

This is two color drawings. One is a cutaway view of the ear, showing the ear canal and the bony labyrinth. The second is a closeup of the bony labyrinth, with all its parts identified, and the membranous labyrinth outlined within it.

Inner ear: Inner ear anatomy showing utricle, saccule, and vestibular nerve.

Thermoception is the sense of heat or absence of heat (cold) by the skin and internal skin passages. Perceiving changes in temperature is referred to as heat flux (the rate of heat flow) in these areas.

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There are specialized receptors for cold (declining temperature) and heat. The cold receptors infer wind direction, an important part of the animal’s sense of smell. The heat receptors are sensitive to infrared radiation and can occur in specialized organs, for instance in pit vipers.

The thermoreceptors in the skin are quite different from the homeostatic thermoreceptors in the brain (hypothalamus), which provides feedback on internal body temperature.

Proprioception, the kinesthetic sense, provides the parietal cortex of the brain with information on the relative positions of the parts of the body. Neurologists test this sense by telling patients to close their eyes and touch their own nose with the tip of a finger. Assuming proper proprioceptive function, at no time will the person lose awareness of where their hand actually is, even though it is not being detected by any of the other senses. Proprioception and touch are related in subtle ways, and their impairment results in deep and surprising deficits in perception and action.

Nociception (physiological pain) signals nerve or other tissue damage. The three types of pain receptors are cutaneous (skin), somatic (joints and bones), and visceral (body organs).

It was previously believed that pain was simply the overloading of pressure receptors, but research in the first half of the 20th century showed that pain is a distinct phenomenon that intertwines with all of the other senses, including touch.

Conception refers to how the passage of time is perceived and experienced. Although the sense of time is not associated with a specific sensory system, psychological and neuroscientific research indicates that human brains do have a system governing the perception of time.

It is composed of a highly distributed system involving the cerebral cortex, cerebellum, and basal ganglia. One particular component, the suprachiasmatic nucleus, is responsible for the circadian (daily) rhythm, while other cell clusters appear capable of shorter-range (ultradian) timekeeping.

Cellular

Receptors

Sensory receptors become activated by stimuli in the environment by receiving signals. The transmission of any message in the neurons of our body requires it to be in the form of an action potential; the sensation must undergo conversion into electrical signals. The structures which convert mechanical signals into electrical signals are receptors.

Receptors get classified based on the type of stimulus activating them. The following are common types of receptors

Mechanoreceptors

  • Activated by changes in pressure
  • Common mechanoreceptors include
  • Pacinian corpuscles in the subcutaneous tissue
  • Meissner corpuscles in non-hairy skin
  • Baroreceptors in the carotid sinus
  • Hair cells on the organ of Corti and in the semicircular canals

Photoreceptors

  • Activated by light
  • Rods and cones (located in the retina)

    • Rods are sensitive to low-intensity light and function better in a dark environment
    • Cones have a better threshold for light, therefore function well in daylight. They also participate in color vision.

Chemoreceptors

  • Activated by chemicals
  • They serve for olfaction and taste

Thermoreceptors

  • Located in the skin and include cold and warm receptors. These are present in the skin.

Nociceptors

  • These become activated by extreme pressure, temperature, or noxious chemicals. These are also in the skin.

There are different types of receptors present into the skin or muscles for all modalities of senses.[rx]

1) Touch

Human skin divides into hairy and nonhairy or glabrous skin. This classification is associated with different touch receptors inside the skin. There are four types of touch receptors. Those which are slowly adapting called Merkel cells (slowly adapting type 1) and Ruffini corpuscles (slowly adapting type2). Those with Pacinian afferents called Pacinian corpuscles and rapidly adaptive ones called Meissner corpuscles.[rx]

  • Merkel’s disc

Structurally simplest among all are Merkel cells which are present in the basal layer of the epidermis. These are located in non-hairy skin. Present in a high amount at the fingertips, they are sensitive selectively to the particular component of stress or strain, and because of that they are more selective in detecting corners, edges and curvatures; this is useful for reading Braille, etc.

  • Ruffini nerve endings

These types of receptors are less densely placed and therefore have less sensitivity. These receptors are located in hairy skin. They are more sensitive to stretch, so become stimulated during stretching of the skin. An example is stretching during motion and for the direction of force detection, along with muscle spindle for hand shape and finger position perception, etc.

  • Pacinian corpuscle

Distributed throughout the palm and finger, the Pacinian corpuscle is the most sensitive receptor type. These are large, onion-like layered structures enclosing a single nerve ending. Pacinian corpuscles function as a mechanical filter to protect from very large, low-frequency stress during manual labor.

  • Meissner corpuscle      

They are most sensitive to dynamic changes in the skin, and they are relatively insensitive for static changes of the skin.

One distinguishing characteristic of each receptor is the degree of adaptation.

  • “Very rapidly adapting” such as Pacinian corpuscle
  •  “Rapidly adapting” such as Meissner corpuscle and hair follicles
  • “Slowly adapting” includes Ruffini corpuscle, Merkel receptors, and tactile discs

 2) Thermal receptors

These are slowly adapting receptors that can detect changes in skin temperature. These may be cold or warm. These receptors have some baseline firing rates. Cold receptors are sensitive between 10 and 32 degrees C. Firing at a baseline rate during 30 to 35 degrees C, the firing rate increases in cold while it decreases when the temperature increases. In the same way, warm receptors have baseline firing around 38 degrees C and increase with an increase in temperature.[4]

3) Vibration

Vibration sensations are useful in the performance of balancing tasks, along with proprioception. Vibrational sense perception is by Pacinian corpuscles and Meissner corpuscles because both of these receptors are sensitive to low-frequency vibrations.[rx]

4) Pain

Noxious stimulation is converted into an electric signal by unencapsulated nerve endings that terminate in the dermis and epidermis. Noxious stimuli such as intense hot or cold, or long-standing pressure cause activation of free nerve endings; this requires threshold stimulation to activate the endings, but once activated, signals are transmitted continuously.[rx]

5) Proprioception

The Golgi tendon organ senses the position of joints and joint movement near attached muscle tendons attached, and by muscle, spindles present inside the extrafusal muscle fibers. They fire signals when stretched.

References

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