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Dr. Taha Sadig Ahmed, MB, BS ( England ) , MAANEM ( USA)

Motor Functions of the Spinal Cord المهام الحركية للنخاع/ الحبل الشوكي ( Spinal Reflexes) المنعكسات النخاعية. Dr. Taha Sadig Ahmed, MB, BS ( England ) , MAANEM ( USA) Consultant , Clinical Neurophysiology ( Saudi Council of Health Specialities )

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Dr. Taha Sadig Ahmed, MB, BS ( England ) , MAANEM ( USA)

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  1. Motor Functions of the Spinal Cord المهام الحركية للنخاع/ الحبل الشوكي( Spinal Reflexes)المنعكسات النخاعية Dr. Taha Sadig Ahmed, • MB, BS ( England ) , MAANEM ( USA) • Consultant , Clinical Neurophysiology ( Saudi Council of Health Specialities ) • Consultant ,Clinical Neurophysiology ( King Abdulaziz University Hospital , Riyadh • Associate Professor , College of medicine , Riyadh .

  2. مصطلحات طبيّة • Spine / Spinal cord النخاع/ الحبل الشوكي • Neuron/ Nerve fiber ( one nerve cell) عصبون • Nerve : عصب العصب يتكون من عشرات الآلاف أو مئات الآلاف من العصبونات e.g., Sciatic nerve , median nerve , ulnar nerve • Motor Functions of the Spinal Cord المهامالحركية للنخاع الشوكي • Spinal Reflexes المنعكسات النخاعية ( المنعكسات التي مركزها في الحبلالشوكي ) • Afferent ( sensory ) neuron : للجهاز العصبي المركزي) afferent العصبون الحسّي (وهو الوارد • ُُُ Effferent ( Motor ) neuron : العصبون الآمر ( حركي لعضلة أو إفرازي لغدّة ، و هو الخارج من الجهاز العصبي المركزي ُEfferent • Innervation ( Nerve Supply) : تعصيب • Synapse :مشبك • Monosynaptic reflex :منعكس أحادي المشبك • Polysynaptic reflex :منعكس متعدد المشابك

  3. A spinal reflex is an automatic , involuntary neuromuscular action elicited by a defined stimulus. The basic unit of a reflex is the reflex arc . The controlling center of the spinal reflex is located in one or more spinal cord segments What is a spinal reflex ? Receptor is Muscle Spindle

  4. The Spinal Reflex Arc Consists of : • Sense organ (receptor). • Afferent ( sensory ) neuron. • Centre ( in spinal cord ) with one synapse in case of monosynaptic reflexes , and more than one synapse in case of polysynaptic reflexes ). • Efferent ( motor ) neuron . • Effector (muscle or gland ).

  5. Afferent fiber DRG Efferent fiber

  6. The Afferent Neurons (1) • The afferent (sensory ) neuron is a pseudobipolar cell , having its cell-body in the dorsal root ganglion ( DRG) . • Its afferent fiber enters the spinal cord via the posterior spinal root , and : (1) In case of monosynaptic reflexes  synapses directly on the anterior horn cell (2) in case of polysynaptic reflexes  synapses on a posterior horn cell , which can be (a) at the same spinal segment where the afferent fiber entered the spinal cord , or (b) at an adjacent , higher or lower spinal segment ( after the afferent fiber ascends or descends for a few higher or lower spinal levels ).

  7. The Afferent Neurons (2) • In case of polysynaptic reflexes one or more interneurn will connect the posterior horn cell to the anterior horn cell . • Afferent neurons can undergo: • Divergence to spread the effect of a single stimulus to more motoneurons in the same spinal segment , or to adjacent segments, • Convergence ( e.g. on a motoneuron ) to facilitate spatial summation.

  8. The Interneurons (in case of Polysynaptic reflexes) • Interneurons are small excitable cells in the grey matter of spinal cord , connecting posterior ( dorsal ) horn cells to the anterior horn cells . • They can be single or multiple . • Together , they may constitute local spinal circuits • Some of them could be excitatory and others could be inhibitory .

  9. The Efferent Neurons • These are motor neurons ( motoneurons ) . • That are situated in the anterior horn of the spinal cord ( i.e., they are anterior horn cells, AHCs): • They are 2 types: (1) Large alpha motorneurons : Innervates the large extrafusal muscle fibers . ( Extrafusal fibers are the regular contractile units of the muscle , which constitute the muscle bulk , and which are responsible for the actual shortening of the muscle ). (2) Small gamma motor neurons : Innervate the intrafusal fibers . ( Intrafusal fibers are the tiny fibers that are present inside the muscle spindle , which is the muscle receptor ) .

  10. Muscle Receptor Alpha motor neuron to Extrafusal Fibers Gamma motor neuron to Intrafusal Fibers (inside the muscle spindle )

  11. Input to Alpha Motor Neurons • 3 sources ثلاثة مصادر 1. DRG neurons • sensory neurons (proprioception) 2. Upper motor neurons • primarily from M1 (Cortical Motor Area)) 3. Spinal interneurons • Can be excitatory or inhibitory

  12. There are 3 Inputs to Alpha Motor Neurons DRG (1) Afferent (sensory) neuron (2) Upper motor neurons (3) Spinal interneuron

  13. Important Definitions • Reflex ( Response) Time = Time that elapses between application of the stimulus and appearance of the response . • Minimal Synaptic delay ( time taken in one synapse) ~ 0.5 ms. • Central Delay : Time taken in spinal cord synapses • Central Dealy = Total Reflex time –Time spent in conduction of impulses along the afferent and efferent nerves. • Number of synapses = Central Delay /0.5 ms

  14. Important Definitions تعريفات هامة • Reflex Timeزمن الأستجابة :Time that elapses between application of the stimulus and appearance of the response . • الزمن الذي إنقضي بين إعطاء التحفيز و ظهور الأستجابة • و طبعا هو مجموع التأخير في العصبونين ( الوارد و الخارج ) + التأخير داخل المشابك Central Delay • يعني الوقت الذي استغرقته الرحلة في العصبونات زائدا الوقت الذي استغرققه التأخير داخل المشابك (التي هي بين العصبونات) • Central Delayالتأخير داخل مجموع المشابك: Time taken in spinal cord synapses • i.e., Reflex Time = Central Delay + Time spent in conduction of impulses along the afferent and efferent nerves. • Minimal Synaptic delay : التأخير داخل المشبك الواحد ( time taken in one synapse) ~ 0.5 ms. • Central Dealy = Total Reflex time –Time spent in conduction of impulses along the afferent and efferent nerves. • لأنه لو طرحنا الوقت الذي استغرقته الرحلة في العصبونات من كل وقت التأخير المركزي نتوصل إلي التأخير داخل المشابك التي هي بين العصبونات • Number of synapsesعدد المشلبك = Central Delay /0.5 ms

  15. Classification of Reflexes According to the Number of Synapses Present in the Reflex Arc (1) Monosynaptic Reflexes المنعكسات أحادية المشبك: • have one synapse only : The sensory ( afferent ) axon synapse directly on the anterior horn cell. • Therefore , the reflex arc does not contain interneurons . • Examples : The Stretch ( Tendon ) reflexes ( also called Tendon Jerks ). • Polysynaptic reflxes المنعكسات متعددة المشابك : • Have more than one synapse , therefore contain interneuron(s) . • Examples : Abdominal Reflexes , withdarwal reflex , Plantar response .

  16. Stretch Reflexes are Monosynaptic

  17. Monosynaptic Stretch Reflex • Postural adjustments تظبيط وضعية الجسم • Muscle tone • knee-jerk reflex • Muscle spindles • length detectors • Low threshold • Activity in afferent from muscle spindle leads to: • 1) stimulation of extrafusal fibers in muscl • 2) Reciprocal Inhibition of antagonist muscle

  18. Classification of Reflexes According to the Location of the Receptor (1) (1) Superficial Reflexes : The receptor is in the skin ( cutaneous receptor) e.g., abdominal reflexes , plantar reflex , anal reflex . (2) Deep reflexes :The receptor is located in muscle or tendon e.g., a) Stretch Reflexes (Tendon jerks ) : such as the biceps jerk , triceps jerk , knee-jerk ( patellar reflex ) , ankle jerk. The receptor for all these is called muscle spindle , and is located within the muscle itself . b) Inverse Stretch Reflex ( Golgi Tendon Organ reflex ) : The receptor is called Golgi Tendon Organ , and is present in the muscle tendon .

  19. Classification of Reflexes According to the Location of the Receptor (2) (3) Visceral Reflexes منعكسات حشوية : Reflexes involving the autonomic reflex arc , receptors are located in the viscera e.g., micturition reflex المنعكس البولي , Defecation reflex المنعكس البرازي , erection reflex المنعكس الأنتصابي.

  20. The Muscle Spindle (1)المغزل العضلي • Each spindle consists of 3-12 tiny ( small) muscle fibers , called Intrafusal Fibres. • They lie parallel to the large Extrafusal Fibres ( which constitute the muscle bulk ) and are attached to them or to the tendon. • Each intrafusal fibre consists of: • Central non-contractile area (receptor), • Peripheral contractile parts.

  21. The Muscle Spindle (2)Types of Intrafusal Fibers • There are two types of intrafusal fibers: • Nuclear bag fibers : contain many nuclei in a dilated central area ( “ bag ” ) . Typically there are 2 nuclear bag fibers per spindle . • Nuclear chain fibers : thinner and shorter than nuclear bag fibers , and have one line of nuclei spread in a chain along the receptor area . There are 4 or more nuclear chain fibers per spindle ( 4 – 9 usually )

  22. The Muscle Spindle (3) Nuclear bag fiber Nuclear chain fiber

  23. The muscle spindle(5)Sensory Innervation of the Muscle Spindle (2) B/ Secondary ( Flower-spray ) Afferents : • Innervate ONLY thenuclear chain receptor • Discharge at an increased rate throughout the period during which the muscle is being stretched, directly proportion to the degree of stretch (measure only muscle length). • This response is known as theStatic Response • لأنها تسجل فقط التغير المطلق في الطول و لكنها لا تسجل سرعة التغير في طول العضل • Nuclear bag fibres are supplied by primary endings only  responsible for the dynamic response ( e.g. in case of knee-jerk ) • Nuclear chain fibres are supplied by both primary and secondary endings  responsible mainly for the static response ( and to a much lesser extent , dynamic response ) .

  24. Motor innervations of the muscle spindle (1) • Efferent fibres to spindle gamma motor neurons supply the peripheral contractile parts of the intrafusal muscle fibres and are of two functional types: • Dynamic gamma efferent end mainly on the nuclear bag fibres • Static gamma efferent end mainly on nuclear chain fibres

  25. Mechanism of Action of the Stretch reflex • Stretching the muscle bulk ( extrafusal fibers ) also stretches the receptor ( muscle spindle ) , because the muscle spindle intrafusal fibers lie in parallel with the extrafusal fibers of the muscle bulk .  stretch receptor in intrfusal fibre  stimulation of sensory endings . • Afferent impulses  go to spinal cord  stimulate: • Alpha Motoneurons , which send impulses to Extrafusal Muscle Fibres  contraction of the muscle bulk . • Gamma Efferent Motoneurons , which send motor impulses to the Intrafusal Fibers inside the muscle spindle  leading to shortening of the peripheral contractile parts of the intrafusal fibres  increase the sensitivity of the receptor to muscle stretch .

  26. Dynamic Component of Stretch Reflex • Dynamic stretch reflex • Sudden rapid stretch of a muscle  stimulates the receptor  which sends synchronous strong excitatory impulses from the primary ( annulospiral ) endings to the alpha motor neurons in the anterior horn of the spinal cord . • The stimulated alpha motoneurons send excitatory impulses to the extrafusal fibers causing contraction of the muscle bulk  this results in a jerky movement • As the muscle shortens  the spindle becomes lax  and ceases to discharge  no more stimulation of alpha motoneuron  no more excitatory impulses from alpha motoneuron to the extrafusal fibers  muscle relaxes • This is the basis of tendon jerks( stretch reflexes ) .

  27. Static Component of Stretch Reflex • Static stretch reflex • Maintained stretch of muscle • Impulses from muscle spindle travel through secondary sensory nerve to alpha motor neuron causing muscle contraction • Asynchronous discharge resulting in mild sustained contraction of muscle as long as it is stretched • Basis of muscle tone

  28. Higher control on gamma efferent discharge (1) • Cortical areas. • The primary motor area (motor area 4) is facilitatory to gamma motor neurons. lesions of motor area 4 or pyramids in the medulla oblongata hypotonia. • Lesions of motor cortex, such as strokes (which damage both facilitatory and inhibitory areas), are characterized by hypertonia (spasticity).

  29. Higher control on Gamma Efferent Discharge  and hence on the Stretch Reflex and Muscle Tone (2) • Basal ganglia (BG) ( Extrapyramidal Areas ) • Generally ( in most instances ) Inhibitory to Gamma Efferents ( and consequently to the muscle tone and stretch reflex ) . • Indirect effect ( there is no direct BG to spinal cord tract ) . They exert their effect by stimulating a small area in the reticular formation of the brain stem (medullary reticular formation). The latter sends inhibitory impulses to gamma motor neurons via the lateral reticulospinal tracts. • Loss of BG inhibitory influence ( e.g. in Parkinson’s disease ) result in  hypertonia  muscle rigidity.

  30. Higher control on Gamma Efferent Discharge  and hence on the Stretch Reflex and Muscle Tone (3) • Brain stem. • Facilitatory • Pontine reticular formation • Vestibular nuclei • Inhibitory: • Medullary reticular area carrying impulses from inhibitory cortical areas, basal ganglia and red nucleus.

  31. Higher control on Gamma Efferent Discharge  and hence on the Stretch Reflex and Muscle Tone (4) • The cerebellum. • Cerebellar cortex exerts an inhibitory influence on the stretch reflex. • Deep cerebellar nuclei (DCN) are excitatory via lateral vestibular nuclei. • Cerebellar lesions in humans characterized by hypotonia, due to deep cerebellar nuclei lesion,

  32. Enhances (تزيد من نشاطها ) A/ Supraspinal influences : 1. Cortical : Primary motor area Corical/limbic : fear/apprehension , and anxiety , pain 2. Brainstem : Vestibular nuclei Pontine centers 3. Cerebellum B/ Largely spinal mechanisms : related to noxious (painful) stimuli . Inhibits A/Supraspinal : Cortical ( voluntary , conscious , mostly) . 2. Extrapyramidal (Basal ganglia , Red Nucleus ) . 3. Brainstem : Medulla . Reticular formation . 4, Cerebellum B/ Largely spinal mechanisms : 1. Excessive muscle stretch ( stimulation of Golgi tendon organ ). 2. Muscle contraction Summary of Factors Controlling /Regulating/Influencing the Stretch Reflex

  33. The Golgi tendon reflex(inverse stretch reflex) • Inverse stretch reflex: excessive tension on the muscle (passive stretch of tendon or active muscle contraction) >> muscle relaxes opposite response to stretch reflex. • The receptors are Golgi tendon organs in muscle tendons stimulated >> muscle contract and pulled on the tendon (tension) • stimulate golgi organ>> A fibers > spinal cord > excitation of inhibitory interneuron>> inhibit alpha motor neuron > muscle relaxation • Protect muscle from rupture

  34. The Golgi tendon reflex (inverse stretch reflex)

  35. Withdrawal reflex (1)(flexor reflex/respnse) • Stimulation of pain receptors in a limb ( e.g., hand or foot )>> impulses to spinal cord via A or C fibres >> interneurons >> anterior horn cells >> stimulate hand flexor muscles >>move the hand away from the injurious stimulus. • a polysynaptic reflexe. • stimulation of flexors muscle accompanied by inhibition of extensors. • Inhibitory inter neurons synapse with extensor motor neurons known as reciprocal innervations (reciprocal inhibition).

  36. Withdrawal reflex (2) • Flexion and withdrawal of the stimulated limb >> extension of the opposite limb >> occurs with strong stimulus (crossed extensor reflex) • Reciprocal innervations occurs in extensor reflex >> flexors are inhibited while extensors are excited >> pushes the entire body away from the injurious agent and supports the body weight. • Withdrawal reflex is characterized by after discharge, which prolongs the response and further enhances the protective role of the reflex.

  37. Properties of reflexes • Adequate stimulus • Each reflex has a precise stimulus called the adequate stimulus. For example, a painful stimulus to the sole of the foot produces the flexor withdrawal reflex, while deep pressure applied to the same area produces the positive supportive reaction.

  38. Properties of Reflexes 2. Irradiation and recruitment ( spatial ): • The extent of the response in a reflex depends on the intensity of the stimulus. The more intense the stimulus is, the greater is the spread of activity in the spinal cord, involving and recruiting more and more other motor neurons . • when the sole of the foot is stimulated by a weak painful stimulus, only the big toe is flexed. A stronger stimulus will cause reflex flexion of the big toe , other toes , plus the ankle. The strongest stimulus will cause withdrawal of the whole leg by causing reflex flexion of the big toe, ankle, knee and hip . • Impulses may also cross to the other side of the spinal cord to cause extension of the other leg.

  39. Properties of reflexes 3. Summation • A/ In spatial summation: two or more stimuli, through different sensory routes, which by themselves are insufficient to elicit a reflex contraction, may elicit a contraction when given together. Summation of subliminal fringes • The tension obtained in a certain reflex by weak (but threshold) stimulation of two adjacent afferents simultaneously is more than the sum of tension developed when each is stimulated separately. • Stimulation of each afferent separately causes discharge of some neurons but only facilitates some nearby neurons (excites them but not enough to discharge). • Those facilitated neurons are said to lie in the subliminal fringe zone of those discharging.

  40. Spatial Facilitation ( Spatial Summation ) Input A Input B

  41. (1) If neuron B fires, neuron X is excited to threshold and fires AP (4) Neuron Y is in Subliminal Fringe Zone. If BOTH B and C fire at the same time  Y threshold of is reached  it fires AP (3) If B alone OR C alone fire , they only increase excitability of neurons in the area within the square (called Subliminal Fringe zone ) , but membranes of neurons in Subliminal Fringe zone t do not reach the firing level to fire . (2) If neuron c fires, neuron z is excited to threshold and fires AP

  42. Summation ( continued ) • Simultaneous stimulation of the two afferents causes overlapping of the subliminal fringe zones and raises the excitability of the neurons (within the subliminal zones) to discharge. • B/ In temporal summation: • two or more stimuli given at different times, which by themselves are insufficient to elicit a reflex contraction, may elicit a contraction if given within a short time of each other (15 ms). Temporal Summation

  43. Properties of reflexes 4. Recruitment and after-discharge • If a repetitive stimulus is maintained, the strength of the reflex contraction slowly increases to a final level. The slow build-up is due to gradual activation of more motor neurons (recruitment , temporal ). • The reflex response may continue some time after cessation of the stimulus, due to after-discharge, the main type being reverberating circuit after-discharge.

  44. 5. Reverberating circuits impulse from one neuron feed back to re-stimulate itself for long time, this  (1) prolongs the response so that it outlives the stimulus for a considerable time . (2) augments ( reinforces ) the response . It eventually stops or wanes out due to fatigue or due to inhibitory impulses from other parts of CNS with inhibitory interneurons .

  45. Reverberating circus

  46. Properties of reflexes 6. Reciprocal innervation or reciprocal inhibition • Reflex contraction of an agonist muscle is accompanied by inhibition of the antagonist. • When the biceps is involved in a stretch reflex, the triceps must relax or no movement will occur. • This is a reciprocal inhibition >> impulses enter the spinal cord will stimulate • the motor neurons supplying the stimulated muscle • an inhibitory interneuron >> inhibiting motor neurons supplying the antagonist muscle.

  47. 7. The Renshaw cell • Is located in anterior horn in close association with motor neurons. • it is an inhibitory cell excited by collaterals from an alpha motor neuron to project back and inhibit the same motor neuron (negative feedback fashion).

  48. Properties of reflexes 8. Response time • Response time is an indicator of the number of synapses in the reflex arc. Very short response times indicate a smaller number of synapses in reflex path. • The knee-jerk, which has the shortest response time, is a monosynaptic reflex.

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