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By the end of this section, you will be able to:
- List the cortical components of motor processing
- Describe the pathway of descending motor commands from the cortex to the skeletal muscles
- Compare different descending pathways, both by structure and function
- List the structures and steps involved in a reflex arc
- Describe several reflex arcs and their functional roles
The defining characteristic of the somatic nervous system is that it controls skeletal muscles. Somatic senses inform the nervous system about the external environment, but the response to that is through voluntary muscle movement. The term “voluntary” suggests that there is a conscious decision to make a movement. However, some aspects of the somatic system use voluntary muscles without conscious control. One example is the ability of our breathing to switch to unconscious control while we are focused on another task. However, the muscles that are responsible for the basic process of breathing are also utilized for speech, which is entirely voluntary.
Cortical Responses
The information on sensory stimuli registered through receptor cells is relayed to the CNS along ascending pathways. In the cerebral cortex, the initial processing of sensory perception can lead to the incorporation of sensory perceptions into memory, but more importantly, it leads to a response. The completion of cortical processing through the primary, associative, and integrative sensory areas initiates a similar progression of motor processing, usually in different cortical areas.
Prefrontal Cortex
Whereas the sensory cortical areas are located in the occipital, temporal, and parietal lobes, motor functions are largely controlled by the frontal lobe. The most anterior regions of the frontal lobe—the prefrontal areas—are important for executive functions, which are cognitive functions that lead to goal-directed behaviors. These higher cognitive processes include working memory that can help organize and represent information that is not in the immediate environment. The prefrontal lobe is responsible for aspects of attention, such as inhibiting distracting thoughts and actions so that a person can focus on a goal and direct behavior toward achieving that goal. The functions of the prefrontal cortex are integral to the personality of an individual, because it is largely responsible for what a person intends to do and how they accomplish those plans.
Secondary Motor Cortices
In generating motor responses, the executive functions of the prefrontal cortex will need to initiate actual movements. One way to define the prefrontal area is any region of the frontal lobe that does not elicit movement when electrically stimulated. These are primarily in the anterior part of the frontal lobe. The regions of the frontal lobe that remain are the regions of the cortex that produce movement. The prefrontal areas project into the secondary motor cortices, which include the premotor cortex and the supplemental motor area. The premotor area aids in controlling movements of the core muscles to maintain posture during movement, whereas the supplemental motor area is hypothesized to be responsible for planning and coordinating movement. The supplemental motor area also manages sequential movements that are based on prior experience (that is, learned movements). Neurons in these areas are most active leading up to the initiation of movement. For example, these areas might prepare the body for the movements necessary to drive a car in anticipation of a traffic light changing.
Adjacent to these two regions are two specialized motor planning centers. The frontal eye fields are responsible for moving the eyes in response to visual stimuli. There are direct connections between the frontal eye fields and the superior colliculus. Also, anterior to the premotor cortex and primary motor cortex is Broca’s area. This area is responsible for controlling movements of the structures of speech production.
Primary Motor Cortex
The primary motor cortex is located in the precentral gyrus of the frontal lobe. The primary motor cortex receives input from several areas that aid in planning movement, and its principle output stimulates spinal cord neurons to stimulate skeletal muscle contraction. The primary motor cortex is arranged in a similar fashion to the primary somatosensory cortex, in that it has a topographical map of the body, creating a motor homunculus. The neurons responsible for musculature in the feet and lower legs are in the medial wall of the precentral gyrus, with the thighs, trunk, and shoulder at the crest of the longitudinal fissure. The hand and face are in the lateral face of the gyrus. Also, the relative space allotted for the different regions is exaggerated in muscles that have greater enervation. The greatest amount of cortical space is given to muscles that perform fine, agile movements, such as the muscles of the fingers and the lower face. The “power muscles” that perform coarser movements, such as the buttock and back muscles, occupy much less space on the motor cortex.
Descending Pathways
The motor output from the cortex descends into the brainstem and to the spinal cord to control the musculature through motor neurons. Neurons located in the primary motor cortex, named Betz cells, are large cortical neurons that synapse with lower motor neurons in the spinal cord or the brainstem. The two descending pathways traveled by the axons of Betz cells are the corticospinal tract and the corticobulbar tract. Both tracts are named for their origin in the cortex and their targets—either the spinal cord or the brainstem (the term “bulbar” refers to the brainstem as the bulb, or enlargement, at the top of the spinal cord).
These two descending pathways are responsible for the conscious or voluntary movements of skeletal muscles. Any motor command from the primary motor cortex is sent down the axons of the Betz cells to activate upper motor neurons in either the cranial motor nuclei or in the ventral horn of the spinal cord. The axons of the corticobulbar tract are ipsilateral, meaning they project from the cortex to the cranial motor nucleus on the same side of the nervous system. The corticobulbar tract controls the movement of muscles in the face, head and neck. Conversely, the axons of the corticospinal tract are largely contralateral, meaning that they cross the midline of the brainstem or spinal cord and synapse on the opposite side of the body. The corticospinal tract controls movement of muscles of limbs and trunk. Therefore, the right motor cortex of the cerebrum controls muscles on the left arm, for example, and vice versa.
The corticospinal tract descends from the cortex through the deep white matter of the cerebrum. It then passes between the caudate nucleus and putamen of the basal nuclei as a bundle called the internal capsule. The tract then passes through the midbrain as the cerebral peduncles, after which it burrows through the pons. Upon entering the medulla, the tracts make up the large white matter tract referred to as the pyramids (Figure \(\PageIndex{1}\)). The defining landmark of the medullary-spinal border is the pyramidal decussation, which is where most of the fibers in the corticospinal tract cross over to the opposite side of the brain. At this point, the tract separates into two parts, which have control over different domains of the musculature.
Appendicular Control
The lateral corticospinal tract is composed of the fibers that cross the midline at the pyramidal decussation (see Figure \(\PageIndex{1}\)). The axons cross over from the anterior position of the pyramids in the medulla to the lateral column of the spinal cord. These axons are responsible for controlling appendicular muscles.
This influence over the appendicular muscles means that the lateral corticospinal tract is responsible for moving the muscles of the arms and legs. The lower cervical spinal cord and the lumbar spinal cord both have wider ventral horns, representing the greater number of muscles controlled by these motor neurons. The cervical enlargement is particularly large because there is greater control over the fine musculature of the upper limbs, particularly of the fingers. The lumbar enlargement is not as significant in appearance because there is less fine motor control of the lower limbs.
Axial Control
The anterior corticospinal tract is responsible for controlling the muscles of the body trunk (see Figure \(\PageIndex{1}\)). These axons do not decussate in the medulla. Instead, they remain in an anterior position as they descend the brainstem and enter the spinal cord. These axons then travel to the spinal cord level at which they synapse with a lower motor neuron. Upon reaching the appropriate level, the axons decussate, entering the ventral horn on the opposite side of the spinal cord from which they entered. In the ventral horn, these axons synapse with their corresponding lower motor neurons. The lower motor neurons are located in the medial regions of the ventral horn, because they control the axial muscles of the trunk.
Because movements of the body trunk involve both sides of the body, the anterior corticospinal tract is not entirely contralateral. Some collateral branches of the tract will project into the ipsilateral ventral horn to control synergistic muscles on that side of the body, or to inhibit antagonistic muscles through interneurons within the ventral horn. Through the influence of both sides of the body, the anterior corticospinal tract can coordinate postural muscles in broad movements of the body. These coordinating axons in the anterior corticospinal tract are often considered bilateral, as they are both ipsilateral and contralateral.
Extrapyramidal System
Other descending connections between the brain and the spinal cord are called the extrapyramidal system. The name comes from the fact that this system is outside the corticospinal pathway, which includes the pyramids in the medulla. A few pathways originating from the brainstem contribute to this system.
The tectospinal tract projects from the midbrain to the spinal cord and is important for postural movements that are driven by the superior colliculus (Figure \(\PageIndex{2}\)). The name of the tract comes from an alternate name for the superior colliculus, which is the tectum. The reticulospinal tract connects the reticular system, a diffuse region of gray matter in the brainstem, with the spinal cord. This tract influences trunk and proximal limb muscles related to posture and locomotion. The reticulospinal tract also contributes to muscle tone and influences autonomic functions. The vestibulospinal tract connects the brainstem nuclei of the vestibular system with the spinal cord. This allows posture, movement, and balance to be modulated on the basis of equilibrium information provided by the vestibular system. The pathways of the extrapyramidal system are influenced by subcortical structures. For example, connections between the secondary motor cortices and the extrapyramidal system modulate spine and cranium movements. The basal nuclei, which are important for regulating movement initiated by the CNS, influence the extrapyramidal system as well as its thalamic feedback to the motor cortex.
Figure \(\PageIndex{2}\) summarizes both ascending and descending pathways.
Ventral Horn Output
The somatic nervous system provides output strictly to skeletal muscles. The lower motor neurons, which are responsible for the contraction of these muscles, are found in the ventral horn of the spinal cord. These large, multipolar neurons have a corona of dendrites surrounding the cell body and an axon that extends out of the ventral horn. This axon travels through the ventral nerve root to join the emerging spinal nerve. The axon is relatively long because it needs to reach muscles in the periphery of the body. The diameters of cell bodies may be on the order of hundreds of micrometers to support the long axon; some axons are a meter in length, such as the lumbar motor neurons that innervate muscles in the first digits of the feet.
The axons will also branch to innervate multiple muscle fibers. Together, the motor neuron and all the muscle fibers that it controls make up a motor unit. Motor units vary in size. Some may contain up to 1000 muscle fibers, such as in the quadriceps, or they may only have 10 fibers, such as in an extraocular muscle. The number of muscle fibers that are part of a motor unit corresponds to the precision of control of that muscle. Also, muscles that have finer motor control have more motor units connecting to them, and this requires a larger topographical field in the primary motor cortex.
Somatic Reflexes
This chapter began by introducing reflexes as an example of the basic elements of the somatic nervous system. Simple somatic reflexes do not include the higher centers discussed for conscious or voluntary aspects of movement. Reflexes can be spinal or cranial, depending on the nerves and central components that are involved.
The example described at the beginning of the chapter involved heat and pain sensations from a hot stove causing withdrawal of the arm through a connection in the spinal cord that leads to contraction of the biceps brachii (Figure \(\PageIndex{3}\)). The description of this withdrawal reflex was simplified, for the sake of the introduction, to emphasize the parts of the somatic nervous system. But to consider reflexes fully, more attention needs to be given to this example.
As you withdraw your hand from the stove, you do not want to slow that reflex down. Consequently, as the biceps brachii contracts, the antagonistic triceps brachii needs to relax. In the hot-stove withdrawal reflex, this occurs through an interneuron in the spinal cord. The interneuron’s cell body is located in the dorsal horn of the spinal cord. The interneuron receives a synapse from the axon of the sensory neuron that detects that the hand is being burned. In response to this stimulation from the sensory neuron, the interneuron then inhibits the motor neuron that controls the triceps brachii. Without the antagonistic contraction, withdrawal from the hot stove is faster and keeps further tissue damage from occurring.
Another type of reflex is a stretch reflex shown in Figure \(\PageIndex{4}\). In this reflex, when a skeletal muscle is stretched, a muscle spindle receptor is activated. The axon from this receptor structure will cause direct contraction of the muscle. A collateral of the muscle spindle fiber will also inhibit the motor neuron of the antagonist muscles. A common example of this reflex is the knee jerk that is elicited by a rubber hammer struck against the patellar ligament in a physical exam. The muscle is quickly stretched, resulting in activation of the muscle spindle that sends a signal into the spinal cord through the dorsal root. The fiber synapses directly on the ventral horn motor neuron that activates the muscle, causing contraction. The reflexes are physiologically useful for stability. If a muscle is stretched, it reflexively contracts to return the muscle to compensate for the change in length. In the context of the neurological exam, reflexes indicate that the lower motor neuron is functioning properly.
A specialized reflex to protect the surface of the eye is the corneal reflex, or the eye blink reflex. When the cornea is stimulated by a tactile stimulus, or even by bright light in a related reflex, blinking is initiated. The sensory component travels through the trigeminal nerve, which carries somatosensory information from the face, or through the optic nerve, if the stimulus is bright light. The motor response travels through the facial nerve and innervates the orbicularis oculi on the same side. This reflex is commonly tested during a physical exam using an air puff or a gentle touch of a cotton-tipped applicator.
Concept Review
The motor components of the somatic nervous system begin with the frontal lobe of the brain, where the prefrontal cortex is responsible for higher functions such as working memory. The integrative and associate functions of the prefrontal lobe feed into the secondary motor areas, which help plan movements. The premotor cortex and supplemental motor area then feed into the primary motor cortex that initiates movements. Large Betz cells project through the corticobulbar and corticospinal tracts to synapse on lower motor neurons in the brainstem and ventral horn of the spinal cord, respectively. These connections are responsible for generating movements of skeletal muscles.
The extrapyramidal system includes projections from the brainstem and higher centers that influence movement, mostly to maintain balance and posture, as well as to maintain muscle tone. The superior colliculus and red nucleus in the midbrain, the vestibular nuclei in the medulla, and the reticular formation throughout the brainstem each have tracts projecting to the spinal cord in this system. Descending input from the secondary motor cortices, basal nuclei, and cerebellum connect to the origins of these tracts in the brainstem.
All of these motor pathways project to the spinal cord to synapse with motor neurons in the ventral horn of the spinal cord. These lower motor neurons are the cells that connect to skeletal muscle and cause contractions. These neurons project through the spinal nerves to connect to the muscles at neuromuscular junctions. One motor neuron connects to multiple muscle fibers within a target muscle. The number of fibers that are innervated by a single motor neuron varies on the basis of the precision necessary for that muscle and the amount of force necessary for that motor unit. The quadriceps, for example, have many fibers controlled by single motor neurons for powerful contractions that do not need to be precise. The extraocular muscles have only a small number of fibers controlled by each motor neuron because moving the eyes does not require much force, but needs to be very precise.
Reflexes are the simplest circuits within the somatic nervous system. A withdrawal reflex from a painful stimulus only requires the sensory fiber that enters the spinal cord and the motor neuron that projects to a muscle. Antagonist and postural muscles can be coordinated with the withdrawal, making the connections more complex. The simple, single neuronal connection is the basis of somatic reflexes. The corneal reflex is contraction of the orbicularis oculi muscle to blink the eyelid when something touches the surface of the eye. Stretch reflexes maintain a constant length of muscles by causing a contraction of a muscle to compensate for a stretch that can be sensed by a specialized receptor called a muscle spindle.
Review Questions
Q. Which region of the frontal lobe is responsible for initiating movement by directly connecting to cranial and spinal motor neurons?
A. prefrontal cortex
B. supplemental motor area
C. premotor cortex
D. primary motor cortex
- Answer
-
D
(Video) 2401 Chapter 13
Q. Which extrapyramidal tract incorporates equilibrium sensations with motor commands to aid in posture and movement?
A. tectospinal tract
B. vestibulospinal tract
C. reticulospinal tract
D. corticospinal tract
- Answer
-
B
Q. Which region of gray matter in the spinal cord contains motor neurons that innervate skeletal muscles?
A. ventral horn
B. dorsal horn
C. lateral horn
D. lateral column
- Answer
-
A
(Video) Biol 2010 Lect 13.5 Types of Reflexes
Glossary
- anterior corticospinal tract
- division of the corticospinal pathway that travels through the ventral (anterior) column of the spinal cord and controls axial musculature through the medial motor neurons in the ventral (anterior) horn
- Betz cells
- output cells of the primary motor cortex that cause musculature to move through synapses on cranial and spinal motor neurons
- Broca’s area
- region of the frontal lobe associated with the motor commands necessary for speech production
- cerebral peduncles
- segments of the descending motor pathway that make up the white matter of the ventral midbrain
- cervical enlargement
- region of the ventral (anterior) horn of the spinal cord that has a larger population of motor neurons for the greater number of and finer control of muscles of the upper limb
- corneal reflex
- protective response to stimulation of the cornea causing contraction of the orbicularis oculi muscle resulting in blinking of the eye
- corticobulbar tract
- connection between the cortex and the brainstem responsible for generating movement
- corticospinal tract
- connection between the cortex and the spinal cord responsible for generating movement
- executive functions
- cognitive processes of the prefrontal cortex that lead to directing goal-directed behavior, which is a precursor to executing motor commands
- extrapyramidal system
- pathways between the brain and spinal cord that are separate from the corticospinal tract and are responsible for modulating the movements generated through that primary pathway
- frontal eye fields
- area of the prefrontal cortex responsible for moving the eyes to attend to visual stimuli
- internal capsule
- segment of the descending motor pathway that passes between the caudate nucleus and the putamen
- lateral corticospinal tract
- division of the corticospinal pathway that travels through the lateral column of the spinal cord and controls appendicular musculature through the lateral motor neurons in the ventral (anterior) horn
- lumbar enlargement
- region of the ventral (anterior) horn of the spinal cord that has a larger population of motor neurons for the greater number of muscles of the lower limb
- premotor cortex
- cortical area anterior to the primary motor cortex that is responsible for planning movements
- pyramidal decussation
- location at which corticospinal tract fibers cross the midline and segregate into the anterior and lateral divisions of the pathway
- pyramids
- segment of the descending motor pathway that travels in the anterior position of the medulla
- reticulospinal tract
- extrapyramidal connections between the brainstem and spinal cord that modulate movement, contribute to posture, and regulate muscle tone
- stretch reflex
- response to activation of the muscle spindle stretch receptor that causes contraction of the muscle to maintain a constant length
- supplemental motor area
- cortical area anterior to the primary motor cortex that is responsible for planning movements
- tectospinal tract
- extrapyramidal connections between the superior colliculus and spinal cord
- vestibulospinal tract
- extrapyramidal connections between the vestibular nuclei in the brainstem and spinal cord that modulate movement and contribute to balance on the basis of the sense of equilibrium
- withdrawal reflex
- automatic withdrawal of an extremity (e.g. a hand) from a painful stimulus
- working memory
- function of the prefrontal cortex to maintain a representation of information that is not in the immediate environment
Contributors and Attributions
OpenStax Anatomy & Physiology (CC BY 4.0). Access for free athttps://openstax.org/books/anatomy-and-physiology
FAQs
What is a somatic motor response? ›
A somatic reflex is an involuntary movement in response to a stimulus. To produce the action, the somatic reflex arc is activated when a signal from the stimulus is sent to the muscle cells, passing through afferent neurons to the CNS, and finally, to the efferent neurons.
What is the minimum number of neurons in a reflex arc? ›Reflexes require a minimum of two neurons, a sensory neuron (input) and a motor neuron (output) (see Figure 1). The sensory neuron detects stimuli and sends a signal towards the CNS.
What is the minimum number of motor neurons that are involved in a somatic reflex? ›The minimum number of neurons required for a reflex arc is two. one must be a sensory neuron that brings impulses to the CNS, and the other a motor neuron that transmits a response to the effector. One of the first somatic reflexes to develop is the suckling reflex.
How many motor neurons does a somatic reflex have? ›Somatic reflex arcs have 1 motor neuron and autonomic reflex arcs have 2 motor neurons. 2. The effectors of somatic reflex arcs are skeletal muscles and the effectors of the autonomic nervous systems are cardiac muscle, smooth muscle, and glands.
What is an example of somatic motor? ›One common example is the knee reflex: hitting the patellar tendon just below the knee cap with a reflex hammer leads to an automatic contraction of the quadriceps – which results in the lower leg kicking out.
What is a somatic response in therapy? ›The somatic therapy approach involves a person sensing their physical form, engaging their senses, feeling their feet on the earth, and ultimately, calming down their nervous system.
What is a typical reflex arc? ›The reflex arc is a special type of neural circuit that begins with a sensory neuron at a receptor (e.g., a pain receptor in the fingertip) and ends with a motor neuron at an effector (e.g., a skeletal muscle).
What happens when you have no reflex actions? ›When reflex responses are absent this could be a clue that the spinal cord, nerve root, peripheral nerve, or muscle has been damaged. When reflex response is abnormal, it may be due to the disruption of the sensory (feeling) or motor (movement) nerves or both.
What is the level of reflex arc? ›What are the 5 components of a reflex arc? The components of a reflex arc include a receptor that receives a stimulus, a sensory neuron, a control centre or interneuron, a motor neuron and a muscle.
What is the minimum level of stimulation required to activate a neuron? ›Answer and Explanation: The minimum stimulus required to trigger an action potential is known as the threshold stimulus. In order for an action potential to be produced, a stimulus (or combination of stimuli) must depolarize to the membrane from -70 mV to the threshold potential of -55 mV.
What is a typical somatic motor neuron? ›
Somatic motor neurons. Somatic motor neurons originate in the central nervous system, project their axons to skeletal muscles (such as the muscles of the limbs, abdominal, and intercostal muscles), which are involved in locomotion.
How many somatic motor neurons stimulate one? ›This somatic motor neuron will branch and innervate several skeletal muscle cells; additionally, each skeletal muscle cell is innervated by only one somatic motor neuron. A single somatic motor neuron and all the skeletal muscle cells that it innervates are known as a motor unit.
What are the 5 parts of a somatic reflex? ›Most reflex arcs have five main components: receptors, sensory neurons, interneurons, motor neurons and muscles.
What are the three somatic reflexes? ›In our discussion we will examine four major reflexes that are integrated within the spinal cord: the stretch reflex, the Golgi tendon reflex, the withdrawal reflex and the crossed extensor reflex.
What is the total number of neurons involved in a reflex response? ›Most reflex arcs involve only three neurons. The stimulus, such as a needle stick, stimulates the pain receptors of the skin, which initiate an impulse in a sensory neuron. This travels to the spinal cord where it passes, by means of a synapse, to a connecting neuron called the relay neuron situated in the spinal cord.
What are 3 examples of somatic? ›Somatic cells make up the connective tissue, skin, blood, bones and internal organs. Examples are muscle cells, blood cells, skin cells and nerve cells.
What do somatic responses consist of? ›The somatic nervous system consists of both afferent (sensory) and efferent (motor) nerves [1]. It is also responsible for the reflex arc, which involves the use of interneurons to perform reflexive actions. Besides these, there are thousands of other association nerves in the body.
Which of the following is an example of a somatic sense? ›Somatic senses include spatial orientation, called proprioception, and the ability to sense mechanical stimuli such as touch, vibration, pressure, heat and cold. Somatosensory pathways involve neurons, nerve fibers, muscles, and various organs including the skin.
What is an example of a somatic treatment? ›Treatment techniques include deep breathing, relaxation exercises, and meditation, each used to help relieve symptoms. Some of the adjunctive physical techniques that may be used with somatic therapy include dance, exercise, yoga, vocal work, and “bodywork” akin to massage or physical therapy.
What grade should reflexes be? ›By convention the deep tendon reflexes are graded as follows: 0 = no response; always abnormal. 1+ = a slight but definitely present response; may or may not be normal. 2+ = a brisk response; normal.
What are the 4 types of reflexes? ›
There are different types of reflexes, including a stretch reflex, Golgi tendon reflex, crossed extensor reflex, and a withdrawal reflex.
What are the 7 stages of a reflex action? ›- stimulus → receptor →
- sensory neurone → relay neurone →
- motor neurone → effector →
- response.
If your doctor taps on a tendon and there isn't a reflexive movement in the muscle, it's a sign of a health issue. Usually, absent reflexes are caused by an issue with the nerves in the tendon and muscle. You may have other muscle symptoms along with areflexia, like weakness, twitching, or atrophy.
Why are my reflexes so poor? ›The most common cause of low reflex response is peripheral neuropathy. Diabetes, anemia, and vitamin deficiency are possible causes of absent reflexes. However, the conditions don'tcause brisk reflexes. If your doctor suspects a neurological disorder, they will order more tests.
Can you regain your reflexes? ›The good news is that it's completely possible to improve reaction times. Strengthening that connection between your body and brain can make a noticeable difference in your ability to react to the world around you.
What is reflex arc 10 standard? ›It is a shortest pathway for an impulse to travel from the receptor organ via central nervous system to the effector. Components of the reflex arc: It includes one sensory neuron which transmits the sensory impulses from the receptors to the central nervous system.
Which part of brain controls reflex action? ›Spinal Cord is the center that controls reflex action. Reflex actions are actions that are carried out quickly in response to a stimulus and thus do not involve any thinking, and thus are under the control of spinal cord.
What 2 types of action can a nerve cell control? ›The conditions inside our body must be carefully controlled if the body is to function effectively. The conditions are controlled in two ways with chemical and nervous responses.
What is the lowest level of stimulation that a person can detect? ›Absolute Threshold
the lowest level of stimulation that a person can consciously detect 50 percent of the time the stimulation is present.
An absolute threshold is the smallest level of stimulus that can be detected, usually defined as at least half the time. The term is often used in neuroscience and experimental research and can be applied to any stimulus that can be detected by the human senses including sound, touch, taste, sight, and smell.
What is the minimum amount of stimulation that a person can detect? ›
An absolute threshold is the smallest amount of stimulation needed for a person to detect that stimulus 50% of the time. This can be applied to all our senses: The minimum intensity of light we can see. The lowest volume of a sound we can hear.
What is the importance of somatic reflexes? ›In doing so, these reflexes utilize some of the same lower motor neurons (alpha motor neurons) used to control skeletal muscle during conscious movement. Because reflexes are quick, it makes sense that somatic reflexes are often meant to protect us from injury.
What is EMG recruitment ratio? ›The recruitment ratio is calculated from the firing frequency of the fastest firing MUAP divided by the number of different MUAPs on the screen. This ratio should be close to 5. In the example just discussed, MUAP C is activated when the firing frequency of the fastest firing MUAP (ie, MUAP A) is 15 Hz.
What are the 31 pairs of somatic nervous system? ›The spinal nerves help to control the function and movement for the rest of the body. The 31 pairs of spinal nerves include 8 cervical, 12 thoracic, 5 lumbar, 5 sacral, and 1 coccygeal. Their names match the adjacent spinal vertebra from which they exit.
What is rate coding of motor units? ›The force exerted by a muscle during a voluntary contraction depends on the number of motor units that are activated and the rates at which these motor units discharge action potentials. These two properties are known as recruitment and rate coding, respectively.
What are 2 examples of somatic reflexes? ›A touch on the roof of the mouth by the sucking tongue causes swallowing to occur (allowing baby to obtain nourishment). A stroke along the side of the sole of the foot causes the foot to grasp, moving the toes toward the heel. Sharp, sudden pain causes the affected arm or leg to be withdrawn.
What are the 3 types of reflexes? ›Sucking reflex (sucks when area around mouth is touched) Startle reflex (pulling arms and legs in after hearing loud noise) Step reflex (stepping motions when sole of foot touches hard surface)
What is a somatic reflex quizlet? ›• If the reflex involves the contraction of skeletal muscle as the effector it is called a somatic reflex. • If the reflex involves the contraction of smooth muscle, cardiac muscle or glands, it is called an autonomic (visceral) reflex.
What are 3 common reflexes that can be tested? ›- Biceps (innervated by C5 and C6)
- Radial brachialis (by C6)
- Triceps (by C7)
- Distal finger flexors (by C8)
- Quadriceps knee jerk (by L4)
- Ankle jerk (by S1)
- Jaw jerk (by the 5th cranial nerve)
There are two types: autonomic reflex arc (affecting inner organs) and somatic reflex arc (affecting muscles). Autonomic reflexes sometimes involve the spinal cord and some somatic reflexes are mediated more by the brain than the spinal cord.
What is the minimum number of neurons required for a reflex circuit? ›
As discussed earlier, a reflex involves at least 2 or 3 neurons. The typical components of a reflex are shown in Figure 13.12. The reflex shown in this figure is called a 3-neuron reflex because it requires three types of neurons: a sensory, an interneuron, and a motor neuron.
What is the average number of neurons? ›Remarkably, at an average of 86 billion neurons and 85 billion nonneuronal cells (25), the human brain has just as many neurons as would be expected of a generic primate brain of its size and the same overall 1:1 nonneuronal/neuronal ratio as other primates (26).
What are 90% of neurons in a nervous? ›Association neurons make up as many as 90% of the neurons of the nervous system. a. Multipolar neurons - these are the most commonly observed type of neuron possessing many dendrites and a single axon. Most association neurons are multipolar.
What are the examples of somatic movements? ›...
They include:
- rolfing.
- Body-Mind Centering.
- Alexander technique.
- Feldenkrais method.
- Laban movement analysis.
Somatic Interventions such as tracking sensations, deepening awareness, boundary awareness, and self-regulation compliment and, in my opinion, increase the efficacy of EMDR Therapy. Collectively these therapeutic modalities offer a profound healing tool for anyone facing the pain of PTSD.
What is an example of a motor response? ›Motor Response - Obeys commands
You must get the patient to follow a simple command such as stick your tongue out or lift up your right arm.
The brain and spinal cord are responsible for processing and integrating the various sources of information to allow us to develop a response. Therefore the main function of the somatic nervous system is to connect the CNS with organs and striated muscle to perform our daily functions.
What is normal somatic movement? ›A somatic movement, generally speaking, is one which is performed consciously with the intention of focusing on the internal experience of the movement rather than the external appearance or result of the movement. The term somatic has become a bit of a buzzword in the health and wellness industry.
What are the different types of somatic? ›There are 220 types of somatic cells present in our body. Many cells are differentiated to perform various specific functions. Some of the specialized somatic cells are: Skin Cells: The unique quality of these cells is regeneration.
What are somatic responses to PTSD? ›Often the scars of past trauma extend beyond emotional pain and physical injury—they can manifest in distinct somatic symptoms as well. Patients may experience a range of general symptoms like fatigue, nausea, diarrhea, constipation, joint or muscle pain, headaches, and palpitations, which may or may not be temporary.
What is somatic response to trauma? ›
Somatic experiencing contends that negative symptoms of trauma—such as anxiety, hypervigilance, aggression, and shame—result from denying the body the opportunity to fully process the traumatic event.
How does EMDR release trauma? ›When you undergo EMDR, you access memories of a trauma event in very specific ways. Combined with eye movements and guided instructions, accessing those memories helps you reprocess what you remember from the negative event. That reprocessing helps “repair” the mental injury from that memory.
What is a score of 5 in a motor response test? ›Motor response
Score 5: localises to central pain. The patient does not respond to a verbal stimulus but purposely moves an arm to remove the cause of a central painful stimulus; Score 4: withdraws from pain.
- Dialing the phone.
- Turning doorknobs, keys, and locks.
- Putting a plug into a socket.
- Buttoning and unbuttoning clothes.
- Opening and closing zippers.
- Fastening snaps and buckles.
- Tying shoelaces.
- Brushing teeth and flossing.
During the movement of any body part, our muscles relay information back to the brain, and the brain is constantly sending “revised” instructions back to the muscles. The cerebellum is important in contributing to the motor system because it compares cerebral motor commands with proprioceptive feedback.
Why is somatic important? ›As somatic experiencing focuses on bodily sensations and regulating the emotional system, it can teach people better thinking patterns and help to rewire the brain to create a productive balance. This form of therapy gives people a greater awareness of their internal experiences, including sensation and emotion.
What part of the brain controls somatic functions? ›The somatic nervous system (SNS), or voluntary nervous system is the part of the peripheral nervous system associated with the voluntary control of body movements via skeletal muscles. 1. (Brain) Precentral gyrus: the origin of nerve signals initiating movement. 2.