1. Voluntary Movement From Ch. 38 “Principles of Neural Science”, 4 th Ed. Kandel et al

2. Voluntary movement Voluntary movements are organized in cortex Sensory feed back –Visual information –Proprioceptive information –Sounds and somatosensory information Goal of movement –Vary in response to the same stimulus depending on behavioral task (precision vs. power grip) Improves with learning/ experience Can be generated in response to external stimuli or internally

3. Cortical organization Hierarchical organization of motor control and task features –Populations of neurons encode motor parameters e.g. force, direction, spatial patterns –The summed activity in a population determines kinematic details of movement –Voluntary movement is highly adaptable Novel behavior requires processing in several motor and parietal areas as it is continuously monitored for errors and then modified –Primary motor cortex Fires shortly before and during movement Fires only with certain tasks and patterns of muscle activation –Premotor areas encode global features of movement Set-related neurons –Sensorimotor transformations (external environment integrated into motor programs) –Delayed response

4. Motor cortex Primary motor cortex –Activated directly by peripheral stimulation –Executes movements –Adapt movements to new conditions Premotor areas (Motor planning) –Dorsal premotor area (dPMA) Selection of action; Sensorimotor transformations; Externally triggered movements; external cues that do not contain spatial information –Ventral premotor area (vPMA) Conforming the hand to shape of objects; Mirror neurons; Selection of action; Sensorimotor transformations; Externally triggered movements –Supplementary motor area (SMA) Preparation of motor sequence from memory (internally not in response to external information) –Pre-supplementary motor area (pre-SMA) Motor sequence learning –Cingulate motor area (CMA) Dorsal and ventral portions of caudal and roastral CMA (along the cingulate sulcus) Functions: to be determined

5. Somatotopical organization Sequence in human and monkey M1 similar Face and finger representations are much bigger than others Greater motor control required for face and fingers

6. Motor cortex stimulation Historical perspective 1870 Discovery of electrical excitability of cortex in the dog; first brain maps (Fritsh and Hitzig) 1875 First motor map of the primate brain (Ferrier) 1926 Recording of extracellular spike activity of a nerve fiber (Adrian) 1937 First experimentally derived human motor map (Penfield and Boldrey) 1957 Microelectrode recordings to map primary somatosensory area (Mountcastle et al.) 1958 First recordings from neurons in awake monkeys (Jasper) 1967 Intracortical microstimulation for mapping of cortical motor output (Asanuma) 1985 TMS is used to activate motor cortex noninvasively (Barker et al.)

7. Transcranial stimulation TES – transcranial electrical stimulation (Merton and Morton 1980) –High voltage (1-2kV), short duration pulses (10-50us), low resistance electrodes. –Direct stimulation occurs at the anode –Current passes through skin and scalp (resistance) before reaching cortex. TMS – transcranial magnetic stimulation (Barker 1985) –Discharge of large capacitive currents (5-10kA, 2-300us) through a coil producing high magnetic field (1-2T). –Stimulus site depends on coil design, coil orientation and stimulus intensity Non-invasive techniques to study –Structure-function relationship (e.g. rTMS virtual lesion) –Map brain motor output (typically averaged EMG as output =MEP) –Measure conduction velocity TMS has advantages over TES –No discomfort (no current passes through skin and high current densities can be avoided) –No attenuation of field when passing through tissue –No skin preparation (conduction gel)

8. Transcranial magnetic stimulation Principles of TMS Coil design

9. Motor cortex stimulation Movements can be evoked by direct stimulation of motor cortex Activates corticospinal fibers –Direct from motor cortex to spinal motor neurons or interneurons Evokes a short latency EMG response in contralateral muscles Latency depends on corticospinal distance impulses have to travel Latency difference

10. Cortex-muscle connections Shoulder muscle Wrist muscle Maps can be generated by intracortical microstimulation Sites controlling individual muscles are distributed over a wide area of motor cortex Muscle representations overlap in cortex Stimulation of single sites activates several muscles (diverging innervation) Many motor cortical neurons contribute to multijointed movements

11. Cortical projections Premotor cortex and primary motor cortex has reciprocal connections Parietal projections to premotor areas (sensorimotor transformations) Prefrontal projections to some premotor areas (cognitive-affective control and learning) Premotor areas and primary motor areas have direct projections to spinal motor neurons

12. Other projections Inputs from cerebellum –Do not project directly to spinal cord Inputs from basal ganglia –Do not project directly to spinal cord Cortico-striatal pathways –Motor loops –Motor cortex => striatum => globus pallidus => Thalamus => motor cortex

13. Motor cortex plasticity The functional organization of M1 changes after transection of facial nerve

14. Practiced movements M1 representation becomes more dense with practice PET data

15. Pyramidal tract Bilateral sectioning of the pyramidal tract removes the ability of fine movements Successive cortical stimuli result in progressively larger EPSP in spinal motor neurons Make it possible to make individual movement of digits and isolated movements of proximal joints –Direct corticospinal control is necessary for fine control of digits

16. Ia spinal circuits Type Ia sensory fibers are primary afferent fibers –Proprioceptor –Component of the muscle spindle –Conveys information about the velocity of stretch and change in muscle length Spinal Ia neurons are inhibitory interneurons –Can respond directly to changes in somatosensory input –Cortical centers do not need to respond to minor changes –Sends inhibitory signals to antagonist motor neurons when muscle spindles in the agonist muscle are activated –Spinal Ia neurons also inhibits spinal reflexes Spinal circuits are used as components of complex behaviors Agonist muscle: generates specific movement Antagonist muscle: acts opposite the specific movement

17. Direction of movement Activity in individual neurons in M1 is related to muscle force and not joint displacement Increased activity with load Wrist displacement constant but load is different Flexor muscle: decreases joint angle Extensor muscle: increases joint angle

18. Postspike facilitation Cortical motor neuron –EPSP have fixed latency –One EPSP increases the probability of spinal motor neuron firing. It does not fully depolarize the motor neuron The EMG is the sum of spike trains of a population of motor units within a muscle The EMG is an indicator of firing of spinal motor neuron Spike-triggered averaging –Averaging the EMG profile over thousands of discharges from a single cortical neuron –Cancels out random noise –Peak in EMG profile at 6ms latency = postspike facilitation –Indicator of connectivity between cortical neuron and the motor neuron

19. M1 and force Two types of cortical motor neurons –Phasic-tonic: initial dynamic burst –Tonic: tonic high level Linear relationship between M1 firing rate and force generation In both types of neurons activity increases with torque Isometric wrist torques: torque level is reached and held

20. Direction of movement Direction of movement is encoded by a population of neurons Motor cortical neurons are broadly tuned to directions but have a preferred direction Single neuron response to 8 directions Population vector Predicted from vector Actual movement Major response: 90- 225 deg Many neurons with different preferred direction

21. Direction of movement Single Arm movements without and with external loads (a) Unloaded: preferred direction to the upper left (b) Loaded: opposite, preferred direction to the lower right A cells firing rate increases if a load opposes movement in preferred direction and decreases if load pulls in preferred direction M1 encoding of force required to maintain a direction Activity of a single motor neuron Length of vector = discharge magnitude 8 directions of movement

22. Activity depends on motor task Precision grip: same activity whether force is light or heavy Power grip: No activity, but EMG activity the same

23. Complexity of movement

24. Internal and external information Influence of visual cue and prior training in motor cortex Task: press 3 buttons in a sequence either guided by (a) light or (b) previously learned Before movement After movement 16 trials

25. Motor preparation Dorsal premotor area is active during preparation Fires according to different delay times Fires during the whole period of anticipation Laterality specific response

26. Visuomotor transformations Separate but parallel fronto-parietal projections

27. Ventral premotor cortex Specific hand tasks activate vPMC

28. Mirror neurons Observed movement Observed human movement Self-performed movement Ventral premotor area

29. Summary Hierarchical organization of motor control and task features –Populations of neurons encode motor parameters e.g. force, direction, spatial patterns –The summed activity in a population determines kinematic details of movement –Voluntary movement is highly adaptable Novel behavior requires processing in several motor and parietal areas as it is continuously monitored for errors and then modified –Primary motor cortex Fires shortly before and during movement Fires only with certain tasks and patterns of muscle activation –Premotor areas encode global features of movement Set-related neurons –Sensorimotor transformations (external environment integrated into motor programs) –Delayed response