Muscle spindle

Muscle spindle
Mammalian muscle spindle showing typical position in a muscle (left), neuronal connections in spinal cord (middle) and expanded schematic (right). The spindle is a stretch receptor with its own motor supply consisting of several intrafusal muscle fibres. The sensory endings of a primary (group Ia) afferent and a secondary (group II) afferent coil around the non-contractile central portions of the intrafusal fibres. Gamma motor neurons activate the intrafusal muscle fibres, changing the resting firing rate and stretch-sensitivity of the afferents. [a]
Details
Part ofMuscle
SystemMusculoskeletal
Identifiers
Latinfusus neuromuscularis
MeSHD009470
THH3.11.06.0.00018
FMA83607
Anatomical terminology

Muscle spindles are stretch receptors within the body of a skeletal muscle that primarily detect changes in the length of the muscle. They convey length information to the central nervous system via afferent nerve fibers. This information can be processed by the brain as proprioception. The responses of muscle spindles to changes in length also play an important role in regulating the contraction of muscles, for example, by activating motor neurons via the stretch reflex to resist muscle stretch.

The muscle spindle has both sensory and motor components.

Structure

Muscle spindles are found within the belly of a skeletal muscle. Muscle spindles are fusiform (spindle-shaped), and the specialized fibers that make up the muscle spindle are called intrafusal muscle fibers. The regular muscle fibers outside of the spindle are called extrafusal muscle fibers. Muscle spindles have a capsule of connective tissue, and run parallel to the extrafusal muscle fibers unlike Golgi tendon organs which are oriented in series.[citation needed]

Composition

Muscle spindles are composed of 5-14 muscle fibers, of which there are three types: dynamic nuclear bag fibers (bag1 fibers), static nuclear bag fibers (bag2 fibers), and nuclear chain fibers.[1][2]

A
Light microscope photograph of a muscle spindle. HE stain.

Primary type Ia sensory fibers (large diameter) spiral around all intrafusal muscle fibres, ending near the middle of each fibre. Secondary type II sensory fibers (medium diameter) end adjacent to the central regions of the static bag and chain fibres.[2] These fibres send information by stretch-sensitive mechanically-gated ion-channels of the axons.[3]

The motor part of the spindle is provided by motor neurons: up to a dozen gamma motor neurons also known as fusimotor neurons.[4] These activate the muscle fibres within the spindle. Gamma motor neurons supply only muscle fibres within the spindle, whereas beta motor neurons supply muscle fibres both within and outside of the spindle. Activation of the neurons causes a contraction and stiffening of the end parts of the muscle spindle muscle fibers.[citation needed]

Fusimotor neurons are classified as static or dynamic according to the type of muscle fibers they innervate and their effects on the responses of the Ia and II sensory neurons innervating the central, non-contractile part of the muscle spindle.

  • The static axons innervate the chain or static bag2 fibers. They increase the firing rate of Ia and II afferents at a given muscle length (see schematic of fusimotor action below).
  • The dynamic axons innervate the bag1 intrafusal muscle fibers. They increase the stretch-sensitivity of the Ia afferents by stiffening the bag1 intrafusal fibers.

Efferent nerve fibers of gamma motor neurons also terminate in muscle spindles; they make synapses at either or both of the ends of the intrafusal muscle fibers and regulate the sensitivity of the sensory afferents, which are located in the non-contractile central (equatorial) region.[5]

Function

Stretch reflex

When a muscle is stretched, primary type Ia sensory fibers of the muscle spindle respond to both changes in muscle length and velocity and transmit this activity to the spinal cord in the form of changes in the rate of action potentials. Likewise, secondary type II sensory fibers respond to muscle length changes (but with a smaller velocity-sensitive component) and transmit this signal to the spinal cord. The Ia afferent signals are transmitted monosynaptically to many alpha motor neurons of the receptor-bearing muscle. The reflexly evoked activity in the alpha motor neurons is then transmitted via their efferent axons to the extrafusal fibers of the muscle, which generate force and thereby resist the stretch. The Ia afferent signal is also transmitted polysynaptically through interneurons (Ia inhibitory interneurons), which inhibit alpha motorneurons of antagonist muscles, causing them to relax.[citation needed]

Sensitivity modification

The function of the gamma motor neurons is not to supplement the force of muscle contraction provided by the extrafusal fibers, but to modify the sensitivity of the muscle spindle sensory afferents to stretch. Upon release of acetylcholine by the active gamma motor neuron, the end portions of the intrafusal muscle fibers contract, thus elongating the non-contractile central portions (see "fusimotor action" schematic below). This opens stretch-sensitive ion channels of the sensory endings, leading to an influx of sodium ions. This raises the resting potential of the endings, thereby increasing the probability of action potential firing, thus increasing the stretch-sensitivity of the muscle spindle afferents.

How does the central nervous system control gamma fusimotor neurons? It has been difficult to record from gamma motor neurons during normal movement because they have very small axons. Several theories have been proposed, based on recordings from spindle afferents.

  • 1) Alpha-gamma coactivation. Here it is posited that gamma motor neurons are activated in parallel with alpha motor neurons to maintain the firing of spindle afferents when the extrafusal muscles shorten.[6]
  • 2) Fusimotor set: Gamma motor neurons are activated according to the novelty or difficulty of a task. Whereas static gamma motor neurons are continuously active during routine movements such as locomotion, dynamic gamma motorneurons tend to be activated more during difficult tasks, increasing Ia stretch-sensitivity.[7]
  • 3) Fusimotor template of intended movement. Static gamma activity is a "temporal template" of the expected shortening and lengthening of the receptor-bearing muscle. Dynamic gamma activity turns on and off abruptly, sensitizing spindle afferents to the onset of muscle lengthening and departures from the intended movement trajectory.[8]
  • 4) Goal-directed preparatory control. Dynamic gamma activity is adjusted proactively during movement preparation in order to facilitate execution of the planned action. For example, if the intended movement direction is associated with stretch of the spindle-bearing muscle, Ia afferent and stretch reflex sensitivity from this muscle is reduced. Gamma fusimotor control therefore allows for the independent preparatory tuning of muscle stiffness according to task goals.[9]

Development

It is also believed that muscle spindles play a critical role in sensorimotor development.

Clinical significance

After stroke or spinal cord injury in humans, spastic hypertonia (spastic paralysis) often develops, whereby the stretch reflex in flexor muscles of the arms and extensor muscles of the legs is overly sensitive. This results in abnormal postures, stiffness and contractures. Hypertonia may be the result of over-sensitivity of alpha motor neurons and interneurons to the Ia and II afferent signals.[10]

Additional images

Notes

  1. ^ Animated version: https://www.ualberta.ca/~aprochaz/research_interactive_receptor_model.html Arthur Prochazka's Lab, University of Alberta

References

  1. ^ Mancall, Elliott L; Brock, David G, eds. (2011). "Chapter 2 - Overview of the Microstructure of the Nervous System". Gray's Clinical Neuroanatomy: The Anatomic Basis for Clinical Neuroscience. Elsevier Saunders. pp. 29–30. ISBN 978-1-4160-4705-6.
  2. ^ a b Pearson, Keir G; Gordon, James E (2013). "35 - Spinal Reflexes". In Kandel, Eric R; Schwartz, James H; Jessell, Thomas M; Siegelbaum, Steven A; Hudspeth, AJ (eds.). Principles of Neural Science (5th ed.). United States: McGraw-Hill. pp. 794–795. ISBN 978-0-07-139011-8.
  3. ^ Purves, Dale; Augustine, George J; Fitzpatrick, David; Hall, William C; Lamantia, Anthony Samuel; Mooney, Richard D; Platt, Michael L; White, Leonard E, eds. (2018). "Chapter 9 - The Somatosensory System: Touch and Proprioception". Neuroscience (6th ed.). Sinauer Associates. pp. 201–202. ISBN 9781605353807.
  4. ^ Macefield, VG; Knellwolf, TP (1 August 2018). "Functional properties of human muscle spindles". Journal of Neurophysiology. 120 (2): 452–467. doi:10.1152/jn.00071.2018. PMID 29668385.
  5. ^ Hulliger M (1984). "The mammalian muscle spindle and its central control". Reviews of Physiology, Biochemistry and Pharmacology, Volume 86. Vol. 101. pp. 1–110. doi:10.1007/bfb0027694. ISBN 978-3-540-13679-8. PMID 6240757. {{cite book}}: |journal= ignored (help)
  6. ^ Vallbo AB, al-Falahe NA (February 1990). "Human muscle spindle response in a motor learning task". J. Physiol. 421: 553–68. doi:10.1113/jphysiol.1990.sp017961. PMC 1190101. PMID 2140862.
  7. ^ Prochazka, A. (1996). "Proprioceptive feedback and movement regulation". In Rowell, L.; Sheperd, J.T. (eds.). Exercise: Regulation and Integration of Multiple Systems. Handbook of physiology. New York: American Physiological Society. pp. 89–127. ISBN 978-0195091748.
  8. ^ Taylor A, Durbaba R, Ellaway PH, Rawlinson S (March 2006). "Static and dynamic gamma-motor output to ankle flexor muscles during locomotion in the decerebrate cat". J. Physiol. 571 (Pt 3): 711–23. doi:10.1113/jphysiol.2005.101634. PMC 1805796. PMID 16423858.
  9. ^ Papaioannou, S.; Dimitriou, M. (2021). "Goal-dependent tuning of muscle spindle receptors during movement preparation". Sci. Adv. 7 (9): eabe0401. doi:10.1126/sciadv.abe0401. PMC 7904268. PMID 33627426.
  10. ^ Heckmann CJ, Gorassini MA, Bennett DJ (February 2005). "Persistent inward currents in motoneuron dendrites: implications for motor output". Muscle Nerve. 31 (2): 135–56. CiteSeerX 10.1.1.126.3583. doi:10.1002/mus.20261. PMID 15736297. S2CID 17828664.