SENSORY AND MOTOR SYSTEMS: REFLEXES D. C. Mikulecky Professor of Physiology Objectives: 1. Associate receptors with the adequate stimulus for those receptors and classify them by the type of energy handled. 2. Identify the various steps in the transduction of a signal into action potentials in sensory nerves. 3. Identify the various ways a signal can be encoded into the all or none responses of the nervous system. 4. Identify the relation ship between sensory units, the size of their receptor field, and sensory acuity. Relate to two point discrimination as an example. 5. Describe the hierarchical and parallel organization of the motor system. 6. Describe somatotopic organization and relate it to the anatomical and functional aspects of both the sensory and the motor systems. 7. Describe the organization of the spinal cord with respect to sensory and motor function. 8. Relate the proprioceptors to the function of the motor system. 9. Describe some simple reflexes.
ADEQUATE STIMULUS A SPECIFIC STIMULUS UNIQUE TO A SENSORY RECEPTOR FOR EXAMPLE, PHOTORECEPTORS IN THE EYE RESPOND ONLY TO ELECTROMAGNETIC RADIATION
TYPES OF ENERGY TRANSDUCED
GRADED VS ALL OR NONE A RECEPTOR’S RESPONSE TO A STIMULUS IS GRADED IF THRESHOLD IS EXCEEDED, THE ACTION POTENTIAL RESULTING IS ALL OR NONE
SENSORY TRANSDUCTION ADEQUATE STIMULUS GENERATOR POTENTIAL ACTION MEMBRANE CONDUCTANCE CHANGE GENERATOR POTENTIAL ACTION POTENTIAL
See pages 686-689 in text
EXAMPLE: THE PACINIAN CORPUSCLE PRESSURE RECEPTOR PRESSURE DISTORTS THE CAPSULE, STRETCHING THE CELL MEMBRANE SODIUM CHANNELS OPEN, DEPOLARIZING THE MEMBRANE IF BEYOND THRESHOLD, ACTION POTENTIAL RESULTS
HOW IS THE INTENSITY OF THE STIMULUS ENCODED? FREQUENCY CODING POPULATION CODING
FREQUENCY CODING LIGHT PRESSURE MORE PRESSURE LOW FREQUENCY HIGHER
POPULATION CODING LIGHT PRESSURE MORE PRESSURE
THE LABELED LINE CODE OF STIMULUS QUALITY NOSE SMELL EYE VISION TONGUE NEOCORTEX LIMBIC CORTEX NOSE SMELL THALAMUS EYE VISION TONGUE TASTE BRAIN STEM EAR AUDITION SKIN SOMATIC SPINAL CORD
LOCALIZATION, DISTRIBUTION, AND ACUITY CODING OF LOCATION DEPENDS ON RECEPTOR LOCATION AREA COVERED BY RECEPTORS IN A SENSORY UNIT IS A RECEPTIVE FIELD ACUITY DEPENDS ON THE DENSITY OF RECEPTORS
GENERAL FEATURES OF THE MOTOR SYSTEM HIERARCHICAL ORGANIZATION VS PARALLEL ORGANIZATION
HIERARCHICAL ORGANIZATION MOTOR CORTEX CEREBELLUM AND BASAL GANGLIA BRAIN STEM SPINAL CORD SKELETAL MUSCLE
PARALLEL ORGANIZATION MOTOR CORTEX BRAIN STEM SPINAL CORD SKELETAL MUSCLE
THE MOTOR UNIT A SINGLE MOTOR NEURON AND ALL THE MUSCLES IT INNERVATES THE FUNCTIONAL UNIT OF THE MOTOR SYSTEM CORRESPONDS TO THE SENSORY UNIT/RECEPTIVE FIELD RELATIONSHIP SIZE OF MOTOR UNIT DETERMINES FINENESS OF MOTOR RESPOSE See chapter 55 in text
THE MOTOR RESPONSE SYSTEM: SPINAL LEVEL THE ORGANIZATION OF MOTOR NERVES IN THE SPINAL COLUMN THE ROLE OF INTERNEURONS THE ROLE OF LOCOMOTOR GENERATORS
THE ORGANIZATION OF MOTOR NERVES IN THE SPINAL COLUMN DORSAL AREA OF VENTRAL HORN: FLEXOR MOVEMENTS VENTRAL AREA OF VENTRAL HORN: EXTENSOR MOVEMENTS DORSOLATERAL AREA OF VENTRAL HORN: INNERVATE EXTREMITIES VENTROMEDIAL REGION: AXIAL MUSCLES TO MAINTAIN POSTURE
LOCATION OF CELL BODIES FOR EXTENSORS AND FLEXORS
THE ROLE OF INTERNEURONS LOCATED IN THE INTER MEDIATE ZONE OF THE SPINAL CORD LATERAL SIDE NEURONS SYNAPSE IPSILATERALLY (TO DISTAL LIMB MUSCLES) MIDLINE NEURONS SYNAPSE BOTH SIDES (MUSCLES FOR POSTURE) ALPHA MOTOR NEURONS:EXCITE SYNERGISTIC AND INHIBIT ANTAGONISTIC
THE ROLE OF LOCOMOTOR GENERATORS RHYTHMIC ACTION OF ALTERANATING FLEXION AND EXTENSION INVOVED IN WALKING MOVEMENTS (CHICKEN WITH ITS HEAD CUT OFF) SPINAL TRANSECTED ANIMALS CAN WALK ON TREADMILL UNDER CONTROL OF LOCOMOTOR COMMAND CENTER IN THE BRAIN STEM
SENSORY FIBERS IN THE MUSCLE THE MUSCLE SPINDLE AS LENGTH DETECTOR GOGLI TENDON ORGANS: TENSION RECEPTORS See chapter 56 in text
THE MUSCLE SPINDLE AS LENGTH DETECTOR(SENSORY FIBERS) TYPE Ia NERVE FIBERS: TRANSMIT INFORMATION ABOUT LENGTH AND VELOCITY TO THE CNS TYPE II NERVE FIBERS:TRANSMIT INFORMATION ABOUT MUSCLE LENGTH TO CNS
TWO TYPES OF INTRAFUSAL FIBERS TYPE IA SENSORY FIBER TYPE II SENSORY FIBER NUCLEAR CHAIN FIBER NUCLEAR BAG FIBER
TWO TYPES OF MOTOR NEURON ALPHA MOTOR NEURON: INNERVATES EXTRAFUSAL FIBER GAMMA MOTOR NEURON: INNERVATES INTRAFUSAL FIBERS
STRETCHING AN INTRAFUSAL FIBER SENDS SIGNALS TO CNS
THE ROLE OF GAMMA MOTOR NEURONS IN REGULATING MUSCLE SPINDLE RESPONSE STIMULATE RECORD RECORD Afferent Activity Muscle Force
THE ROLE OF GAMMA MOTOR NEURONS IN REGULATING MUSCLE SPINDLE RESPONSE STIMULATE RECORD RECORD STIMULATE Afferent Activity Muscle Force
GOGLI TENDON ORGANS: TENSION RECEPTORS IN SERIES WITH EXTRAFUSAL FIBERS TRANSMITS INFORMATION ABOUT FORCE OR TENSION TO CNS FREQUENCCY CODING
SPINAL REFLEXES THE STRETCH REFLEX THE INVERSE MYOTACTIC REFLEX THE FLEXOR WITHDRAWAL REFLEX
THE STRETCH REFLEX (KNEE JERK REFLEX) TAP PATELLAR TENDON BELOW KNEE SENSORY SIGNALS FROM MUSCLE SPINDLE INDICATE FLEXION OF LEG FLEXOR IS INHIBITED EXTENSOR ACTIVATED LEG EXTENDS
KNEE JERK REFLEX EXTENSOR ACTIVATED SENSORY NEURON FROM MUSCLE SPINDLE DETECTS STRETCH SPINAL CORD FLEXOR INHIBITED
INVERSE MYOTACTIC REFLEX ARM EXTENDS BICEPS & SYNERGYSTIC MUSCLE RELAXEDEXTENSOR CONTRACTED WEIGHT RELEASED
THE FLEXOR WITHDRAWAL REFLEX PAINFUL STIMULUS DETECTED IPSILATERAL EXTENSORS INHIBITED IPSILATERAL EXTENSORS EXCITED LIMB IS WITHDRAWN IF INVOLVING ONE FOOT WHILE STANDING, CONTRALATERAL SIDE EXTENSORS ACTIVATED AND FLEXORS INHIBITED TO SUPPORT GREATER WEIGHT
FLEXOR WITHDRAWAL REFLEX SENSORY SIGNAL TO SPINE STEPON TACK VIA INTERNEURONS IPSILATERAL EXTENSORS INHIBITED IPSILATERAL FLEXORS CONTRACT-LEG LIFTS CONTRALATERAL EXTENSORS CONTRACT CONTRALATERAL FLEXORS INHIBITED- MAINTAIN BALANCE AND SUPPORT WEIGHT