Functional Antaomy of the Brain and Neural System Flashcards

Question

What are the two branches of spinal nerves?

Answer 1

2 branches of spinal nerves: 1. Ventral root: (Outputs) -contains axons of MOTOR neurons 2. Dorsal root: (Inputs) -contain axons of SENSORY neurons (ex; touch, pain) Dosal Root ganglia: -contain cell bodies of sensory neurons -called Psuedounipolar neurons -these cell bodies in ganglion extends fibers to spinal segments or medulla

Answer 2

Two enlargements: -Cervical enlargement -C3 to T1 (cervical 3 is enlarged compared to T1) -Lumbar enlargement L1 to S2 Gray matter is expanded (during enlargement) to incorporate more sensory input from limbs, and more cell bodies for motor control of limbs

Answer 3

Neuronal Organization: made up of 10 zones of cells in the gray matter called renga Lamina 10 Laminas Lamina I, and II: have cell bodies that process pain inputs coming from dorsal root ganglia Lamina III, IV- process info related to Touch: temperature, crude touch and pain Lamina VII, VIII, IX : process info related to motor outputs Lamina VII: have Renchal cells which are inhibitory neurons in the cell Lamina VIII ; motor neurons that innervate distal musculature (legs) Lamina IX: have alpha motor neurons innervate core musculature, intercostal, ribcage and diaphragm

Answer 4

Reflexes: fast, stereotypical, inborn, protective actions -occur at spinal cord or brainstem levels -May be either monosynaptic or polysynaptic

Answer 5

Reflexes all require: 1. Stimulus at receptor 2. sensory information relay 3. processing at CNS level 4. activation of motor response 5. response of peripheral effector

Answer 6

Patellar stretch by hitting of hammer, causes stretch of quadriceps muscle The activation of muscle spindle fibers will cause a synapse on monosynaptic synapse that innervates and activates that muscle group The stretch activates the muscle spindle and 1A fiber which synapses into lamina 7 (contain renchal neurons which are inhibitory interneurons) when these inhibitory neurons are activated, they inhibit the motor neurons that are heteronomous innervating opposing muscle group (try to inhibit opposing muscle group (hence heel kicks up as reflex when hit knee with hammer)

Answer 7

Principle Sensory Pathways (dependent on sensory modality) 1. Fine Touch Pathway (ex: run fingers through paper) Sensory information comes in through dorsal root, does not synapse. Those fibers enter fasciculus gracilla and Fasciculus cuneatus and ascends into the medulla. -neruons in the Fine Touch pathway do NOT synapse until they reach medulla. As you ascend the spinal column, as more fibers come in through dorsal root, they continue pack in, pushing all fibers medially (hence why leg to neck across fasiculus) -Fasiculus gravilla and Cuneatus- have fibers inne Side Note: Normally, fibers innervating leg- medial upper trunk, arm and neck- lateral 2. Pain pathways -Sensory info comes from C fiber and A delta fiber through the dorsal root -However they will synapse on Laminas I- IV (unlike in fine touch pathway) The second neuron in pathway sends fiber that desiccate, or CROSS to other side at that spinal segment. Once crossed, the fibers ascend through neuralspinal thalamotract or anterior lateral system of tracts. Either neurospinal tract or paleo tract will make tertiary synapse cerebral cortex

Answer 8

Paleospinal thalamotract- synapses at Brainstem reticular formation Neuralspinal thalamotract- ascend directly into thalamus Both paleo and neuralspinal thalamotract make tertiary synapse to cerebral cortex . Neurospinal thalamotract: fast pain signals elicited by mechanical or normal stimuli (ex; if you cut yourself) Paleospinal thalamus- slow, chronic pain signals being transmitted by slow, C- fibers. (ex: throbbing, dull pain) -older version

Answer 9

Clinical presentation of lesions (patient) -T11 injury -Dorsal column lesion -Loss of all proprioception and vibration sensation below lesion (belly button) -pain sensation and motor remain intact Process: Level of T11 corresponds to belly button; the Fine touch comes into dorsal roots, which immediately ascends through dorsal columns;, at that level of lesion and below brain, there is no proprioreception hence that's why the information will not ascend into brain, hence proprioreceptor, vibration below lesion does not exist, so you have lost that sensation. Pain synapses in Lamina I-IV, desiccates and then ascends toward more ventral area; where pain is ascending is spared (hence individual can feel pain and temp below region site, not fine touch) motor regions will descend in ventral region (which are spared)

Answer 10

YES patellar region is intact (with T11 lesion) because patellar reflex occurs at spinal segment which is intact. so with this lesion, you won't have fine touch, but reflex are still intact.

Answer 11

L2 Hemicord lesion -17-year old was stabbed at level T12/L1 in the back -Significant muscle weakness affecting the whole right Lower extremity -Impaired vibration and proprioreception sense of the right leg -Loss of pain and temperature sense of the left leg The motor tracks running down right hand side exit through ventral root (hence lesion through right side of spinal segment, have deficits in motor movement -somatosensation from right hand side is lost from lesion side (due to leafing dorsal columns) pain and temperature is lost on contralateral side b/c pain and temp info below region sit, come in synapse and desiccate -paralysis , lose proprioeeception and vibration on ispilateral side This L2 lesions is a reminder of Brown Sequard syndrome- lesionof spinal cord that results in the weakness or paralysis by one side of the body and loss of sensation on other side of body

Answer 12

There are 12 cranial nerves (all synapse on nuclei in brain) -some of these cranial nerves are sensory, motor, or mixed (sensory and motor)

Answer 13

Cranial nerve Nerve Type Functions 1. Olfactory Sensory Smell 2. Optic Sensory Vision 3. Oculomotor Motor Eye Movement (cross eye) 4. Trochlear Motor Eye Movement 5. Trigeminal- Fine touch, temperature, pain, chewing Ophthalmic Branch Sensory Maxillary Branch. Sensory Mandibular Branch Mixed 6. Abducens Motor Eye Movement 7. Facial Mixed. Sense of Taste, Saliva and Tear Secretion, Movement of facial muscles 8. Vestibulocochlear - Cochlear Sensory Hearing (Auditory Nerve) Vestibular Sensory. Maintaining Equilibrium of the Body 9. Glossopharyngeal Mixed Swallowing and Secretion of Saliva, Taste 10. Vagus Mixed. Parasympathetic Sensation, Control of Smooth Muscles of Lungs, Viscera. Monitors Blood pressure, Levels of O2 and CO2 11. Accessory Motor Swallowing, Movement of Head and Shoulders 12 Hypoglossal Motor Tongue Movement, Speech and swallowing

Answer 14

Trigeminal nerve has 3 branches: 1. Mandibular Division: as it enters and exits trigeminal nerve, it forms mandibular nerve and innervates the mandible 2. Maxillary nerve- underneath the eye 3. Opthalamic nerve- above Maxillary nerve all three nerves through trigeminal ganglion, will synapse on trigeminal nerve nuclei

Answer 15

Medulla- extension of the spinal cord -Closed part of Medulla: dorsal columns begin to synapse on Nucleus gracillis and Nucleus cuneata; also decussation of descending motor fibers or DECUSSATION OF PYRAMIDS (motor fibers from the medullary pyramids cross the midline) -axons coming in through dorsal column will synapse first in Nucleus cuneata and gracillus. Those neurons send fibers that will cross at this level, ascend though medial lemniscus into thalamus (seen better in open portion of medulla) -Open part of Medulla- cerebral canal opens up into fourth ventricle at this point At open part, you see other structures: **inferior Olivary nucleus (involved in motor coordination, source of climbing fibers to cerebellum, and involved in voluntary movement) *Trigeminal Nerve Nucleus and Spinal tract** -**cranial nerve V- Spinal nucleus -**cranial nerve V- Spinal tract -also see vagal, hypoglossal, vestibular and trigemninal nuclei (lots of cranial nerves snyapse in medulla)

Answer 16

Most cranial nerves have first synapse in the MEDULLA (open part)

Answer 17

Pons is connected to middle part of cerebellum called middle peduncle (tract of fibers from Pons into cerebellum) many of same pathways present in medulla are present in pons such as medial lemniscus tract, Medial longitudinal fasciciulus ( contain oculomotor nerve, trochlear nerve and abducens nerve), and 5th cranial nerve nuclei, motor nucleus, sensory nuclei, spinal portions of nuclei) -Locus ceruleus- next to cranial nerve 5 this anatomy used to help find different things in the dark (that are a mile away) - reticular activating system nuclei

Answer 18

Reticular activating system- (in Pons) contains serotonergic Nuclei of Raphe, and Cholinergic reticuluar formation (gigantocellular neurons of reticular formation, ACh), and Locus ceruleus (NE)

Answer 19

Midbrain: Substantial Niagra (Dopaminergic neurons) -slice midbrain, you can see different regions: inferior caliculus(auditory processing) *Superior caliculus (Visual area involved in psychotic movements; fast jumps of your eye, regulate smooth movement, fixation eye movements, Vergence (Move both eyes simultaneously; cross-eyed) most Dorsal part of Midbrain: **Tectum Most Ventral part of Midbrain: **Tegmentum ** Peri acqueductal gray (PAG) - pain process **Cirus cerebri (aka cerebral periduncle) - major pathway of motor neurons to get out of cortex

Answer 20

Forebrain: 1) Frontal Lobe: -MOTOR CORTEX- plans and executes voluntary movements -BASAL GANGLIA- smoothes movements -Broca's area- controls speech -Prefrontal cortex- planning, impulse control 2) Parietal Lobe: - *Somatosensory Cortex- protection area for body senses Association cortex- location of body and objects in space 3) Temporal Lobes: -AUDITORY CORTEX- Auditory information -Wernicke's area- Language area- meaning -Inferior temporal cortex- visual identification of objects 4) Occipital Lobes -PRIMARY Visual Cortex : Projection area for visual information Visual association cortex: Processes components of visual information

Answer 21

Brain hemispheres have different functions -Left and right hemispheres control the OPPOSITE parts of the body (right, and left, respectively) right brain hemisphere controls left side of body -Speech processing centers (Broca's area and Wernicke's) are located on the left hemispheres

Answer 22

High Cognitive functions are controlled ASYMMETRICALLY Left Brain- logic, Analysis, mathematics, language, facts, think in words. right brain - (Affective related in prefrontal cortex , rhythm processing in music, creativity, imagination, intuition, feelings, visualizations, arts there is a bias for different functions in both brain regions

Answer 23

Frontal Lobe located in front of central sulcus and above the Sylvian (lateral) sulcus Frontal lobe- planning, organization, problem solving, memory, attention, decision making, abstract thinking, complex behavior and emotions; fine control of the movement (primary motor cortex- pre central gyrus) inferior frontal gyrus- Supplemental motor area, initiation and sequence of movements -Prefrontal cortex- intellectual and emotional events

Answer 24

Broca's Aphasia- when you have difficulty with speech production ( you know what you want to say, but hard time verbalizing it) ex: you. notice a red thing on a tree (hard time saying apple) broca's - production of language

Answer 25

Insula (island of rhile) : has broad role of interception; sense of physical condition body (ex; how am I doing, how am I feeling) -also involved in Pain and taste sensation -sensorimotor pain, social and emotional processing and decision making Insula located in coronal section of brain

Answer 26

Amygdala: involved in emotional processing (both fear, and positive emotions

Answer 27

Parietal Lobe: Integrate sensory inputs from various parts of the body tactile, pain), including orientation in space (together with cerebellum). Primary somatosensory cortex- postcentral gyrus Temporal Lobe- recognizing and processing sounds, Understanding and producing speech Occipital Lobe- receiving and processing visual information (visual cortex)

Answer 28

Broca's motor speech area: production of speech Wernicke's area- recognition of speech (association of sound and rhymes)

Answer 29

Sagittal Section: Corpus Callosum- connects cerebral hemispheres Cingulate gyrus- emotions, learning, instincts, Septum pellucidum- separates lateral ventricles

Answer 30

Feedback circuit: feedback loop for information to be computed, trying to generate movement, you will go to motor cortex which will send information to basal ganglia about movement (tell body, I want to move). Basal ganglia will send this information to thalamus to talk to primary Motor cortex. if there is any update, sensory info will come back to basal ganglia so it can update it. Basal ganglia interconnected with many other brain regions interconnections throughout brain (not just one single circuit)

Answer 31

Primary motor cortex: constantly send excitatory signals to the lower motor neurons, If not dampened by voluntary control, these signals can cause an uncontrolled movement of the muscles (dyskinesia) that may be observed in the course of Parkinson's disease Prefrontal cortex (PfC) and primary associative cortex (PAC) control the primary Motor cortex though the BASAL GANGLIA, a complex that involves a number of nuclei

Answer 32

The Primary motor cortex affects Parkinson's Disease -Dyskinesia- is the uncontrolled movement of muscles, that can be observed in Parkinson's disease (if primary motor cortex not controlled properly)

Answer 33

PAC, FC, PfC, are involved in the PLANNING process (using a compilation of memory, experience, visual and auditory signals) in a decision to make a move. The Primary motor cortex is involved in the EXECUTION of movement (of spinal cord)

Answer 34

Primary motor cortex - is a cortical area, called cortical motor homunculus The homunculus: Size of body part relates to how many neurons control muscle group or particular area in the body This was later discovered since primary Motor cortex underwent electrical stimulation in trans, (during open surgery), and the patient will move muscles regardless of his or her will hence, there is Somatopoic organization in brain regions (thalamus, spinal cord, precentral gyrus, Nucleus gracillis and cuneata)

Answer 35

Cerebral cortices 1) Fine perception of complex, visual, auditory and tactile signals and their compilation (ex: primary somatosensory cortex, visual cortex) 2. Fine control of the movement (primary motor cortex) 3. Associative and abstract memory, conscious control, intellect and high cognitive functions (frontal and prefrontal cortices) 4. Verbal, speech and language recognition (Wernicke's and Broca's areas)

Answer 36

Cerebellum; 1) Balance and coordination of complex movemnts (also coordination of cognitive thought)

Answer 37

Brain stem: 1) Primordial instincts and emotions (limbic system) 2. Motivation and addiction (basal ganglia; dopamine, VTA) 3. Control of the motor output (basal ganglia) 4. Autonomous control of respiratory, cardiovascular and digestive functions (NE, E) 5. Sorting and transmission of the information to the spinal cord

Answer 38

You have an environment (that you need to take information from) will become a sensation, and we will perceive it in different ways. We then you that information to make a decision, which generates an action The action will then impact the environment around you. The brain has the interconnected system to keep you alive.

Answer 39

Sensory receptors: specialized cells (like auditory cell) or multicellular structures that collect information from the environment -these receptors send impulses to the brain Sensation: a feeling that occurs when brain becomes aware of sensory impulse -you then take the sensation and have perception of it (ex: how I hear violin) Perception: a person's view of the stimulus; the way the brain interprets the information

Answer 40

Sensory Pathway: Stimulus --> Sensory receptor (= transducer) ---> Afferent sensory neurons---> CNS---> Integration and perception

Answer 41

Receptor Types: 1) Chemoreceptors- respond to changes in chemical concentrations (ex; taste) 2) Pain receptors (nociceptors) - respond to tissue damage 3) Thermoreceptors- repsond to changes in temperature 4) mechanoreceptors - respond to changes in mechanical forces (ex; stretch receptors) 5) Photoreceptors (respond to light) 6) Osmoreceptors (respond to changes in solute concentration) (ex: pH, O2 and CO2 levels)

Answer 42

General Somatosensation: describes senses that are associated with skin, muscles, joints and viscera Three groups; -Exteroceptive tissues (exteroceptors): senses associated with body surface such as touch, pressure, temperature and brain -Visceroceptive senses (interoceptors) : senses associated with changes in the viscera such as blood pressure stretching blood vessels and ingestion of the meal Proprioreceptive senses; senses associated with changes in muscles and tendons such as at joints (ex: how you're standing, arm is up)

Answer 43

CNS Distinguishes 4 Stimulus Properties: 1) Modality (nature) of stimulus -type of receptor (ex: taste, auditory) 2) Intensity (how loud?) 3) Duration (how long?) 4) Location -Lateral inhibition and Population coding mechanisms is what the brain uses to help determine location and other properties of sensory stimuli

Answer 44

Somatosensory Receptors: 1) Mechanoreceptors -hair follicle (virbrissa) receptors -FINE TOUCH Meissner's Corpuscles Merkel's disks -Deep Transient Pressure and High Frequency Vibration Pacininan corpuscles -Skin Stretch and Deformation within joints Ruffini's endings -Muscle Stretch Intrafusal fiber: Annulospiral endings, flower-spray endings, Golgi-tendon 1b fiber (patellar fiber) 2) Temperature -Krause and Bulbs (cold) 3) Nociceptors -Free nerve endings -

Answer 45

Nociception: -Free dendritic endings -Activation strong Noxious stimuli- 3 categories of the stimuli: -Mechanical -Thermal (menthol and cold/capsaicin and hot) -Chemical (includes chemicals from injured tissues) -Inflammatory pain May activate 2 different pathways: -Reflexive protective- integrated in spinal cord -Ascending to cortex (pain or pruritis -> itch)

Answer 46

Receptor Transduction: composes of stimulus that will bind to different kinds of receptos: -Simple neural receptor; containing free nerve endings, unmyelinated axon and cell body -Complex Neural receptor- contains layers of connective tissue, myelinated axon, cell body -Special Senses receptor: containing synapse, sensory neuron and cell body Receptor is part of neuron--> Action potential triggered if potential is above threshold Specialized receptor cell--> the amount of Neurotransmitters released determines stimulus strength

Answer 47

Mechanism of Mechanotranduction: Pacian Corpuscle Detects vibration There is an A beta fiber that contains concentric layers of myelin and protection that wrap around and around the fiber 1) When there is Deformation, at frequency vibrating back and forth, an action potential is generated through sodium potassium changes 2) EPSP generates AP at first node of Ranvier (initial segment 3) AP propagates down axon to dorsal root up into spinal cord molecules mediating mechanotransduction in pacian corpuscle are really unknown.

Answer 48

Sensory transduction (mechanoreceptor in a muscle) -if you have a fiber, the way it communicates its intensity, is though its number of action potentials Ex: a mechanoreceptor in muscle: If you stretch muscle a little it, generates a few spikes -stretch muscle a lot- generate a lot more action potentials Action potentials: all or none phenomenon (either they are firing or not firing) you can encode Duration of Action potential: by how long the thing is spiking or generating action potentials Pattern is important with AP's : at beginning of stimulus, AP fires rapidly , whereas towards the end, the AP fires more slowlly (since it encodes its duration of stretch)

Answer 49

if we activate more and more receptors (as we touch skin, or hear louder and louder tone), we can get more and more axons to fire Action potentials Recruitment of receptors, ; when you keep adding more neighbors or a combination of receptors together to create a message -more pressure- recruit receptors

Answer 50

Single Sensory Unit: a weak stimulus will have a few receptors to fire a little bit of Action potentials (slower rate) However a strong stimulus will have neurons send more receptors to be activated and allow for a FASTER FIRING of AP's Multiple sensory units: a weak stimulus, will have few receptors as well leading to some firing of AP's -A strong stimulus and multiple sensory units will activate many neurons at at the same time to fire lots and lots of AP's - the three neurons will generate AP's at the same time and another secondary neuron will collect that information and give a read out as to how population of primary neurons respond -amplification by single neuron or by multiple neurons is called amplification and corresponds to recruitment

Answer 51

Touch; MECHANORECPTORS -small and large receptive fields Meissner's corpuscle; small receptive field where you are innervation a number go regions in a small area of skin (on fingers, or palm) Pacinian corpuscle : large receptive field ; higher number of receptors neurons innervate a large area of hand

Answer 52

FINE Touch: -Small Receptive Fields: **Meissner's corpuscles (RAPIDLY adapting) -distinguish between two points on the skin -receptor can tell you about edges **Merkel's discs (Slowly adapting) -Localize touch and determine texture (tell you about how big edge) -These receptors are numerous in the DISTAL than the Proximal parts of the body (more abundant in hairless portions of the body- skin and lips) -( fire continuously )

Answer 53

CRUDE Touch -Large receptive Fields (one neuron innervates large patch of skin) **Pacininan corpuscles (RAPIDLY adapting) subcutaneous, tendons, and ligaments -heavy pressure and vibrations ' (fire at onset and offset of stimuli) **Ruffini's endings (slowly adapting) seen in joint capsules ( fire throughout due to magnitude of change)

Answer 54

receptive field size- tell us where AP happened and get richer sense of environment due to fine and crude touch that encode different properties of somatosensation

Answer 55

Intensity and Duration of stimulus; Intensity- coded by NUMBER Of receptors activated and frequency of AP coming from receptor Duration; coded by duration of AP's in sensory neurons sustained stimulation leads to ADAPTATION (neuron gets used to stimulus) -Tonic receptors - (encoding how much) -Phasic receptors- (edges and dynamic changes)

Answer 56

Fine touch Pathway -transmitted by Dorsal Column- Medial Leminiscus System (brain stem) components; fine touch Vibration Position Pressure Crude Touch Pathway -transmitted by Anterolateral system components: Crude touch pain temperature tickle and itch

Answer 57

Nerve Fiber Classification A fibers; Myelinated Subtypes; alpha, beta, gamma,delta (some overlap in ranges) side note; alpha (proprioreceptor of skeletal muscles, beta (mechanoreceptor of skin; 6-12 um) Delta (pain and temperature) -Fastest conducting and largest diameter (20 um) B fibers: Slower myelinated C fibers: UN Myelinated -Slower conducting than A fibers and smallest diameter (0.5-2 m/sec, 0.5 um) These fibers are so slow due to having no myelin (can't jump node to node)

Answer 58

Sensory Axons Enter CNS: Spinal cord -Divisions of spinal gray matter: -Dorsal horn -Intermediate zone -Ventral horn 1) Myelinated ABeta axons (touch-sensitive) -Enter as Dorsal root (immediately) -Ascend to brain through dorsal columns Abeta and Adult fibers mediate pain -Fast (Adelta fibers) pain is sharp C fibers mediate pruritus (itch) -Slow pain (C) is throbbing two main systems are the Alpha Beta axons that go straight to Dorsal root, dorsal columns and other fibers synapse at laminal I-IV (Alpha delta fibers and C fibers)

Answer 59

Fine touch: A beta fibers from fine touch corpuscles come in, immediately ascend through dorsal column, cuneatus, and gracile tracts. That information makes its first synapse in MEDULLA in the Nucleus gracilis and Nucleus Cuneate Once made synapse in medulla, the secondary neuron sends axon that desiccates (crosses) the midline ( near Medial Leminiscus) and ascends through tract into Thalamus Once synapse in thalamus it goes to central cerebral cortex and ends up in somatosensory cortex. 1st synapse: medulla second synapse: thalamus

Answer 60

Nucleus Cuneate and Nucleus gracilis (where it makes its first synapse in medulla) then desiccates and ascends through medial leminsicus on contralateral side -motor neurons activating muscles also decussate this region (sensory and motor info decussate (cross) in region of medulla; med lem)

Answer 61

Pain pathways- pain sensation fibers transmitted : A Delta fibers and C fibers will synapse on Lamina I-IV in dorsal horn. These sensory neurons will send axons that desiccate (cross) at level of spinal segment and ascend through anterolateral system of ascending tracts on contralateral side through either Paleospinalthoalmic tract (Slow pain) or into Neospinothalamic tract (fast pain; Alpha Delta) and into thalamus, then cortex. Fine touch pathway: Alpha fibers go straight through dorsal--> gracilis/cuneate into medulla (first synapse)---> Nucleus gracilis,/cuneate---> decussation at midline for medial lemniscus and synapse at thalamus--> cerebral cortex

Answer 62

Referred pain: when pain in organs is poorly localized ex; someone has heart attack, but complains arm hurts Referred pain occurs if: Multiple primary sensory neurons converge on single ascending tract pain organs: afferents poorly organized. neurons stay in lamina I-IV ex: painful stimulus of skin that synapse on neuron Pain in viscera is uncommon; pain sensors and axons will synapse on same neuron that a patch of skin would synapse (hijacks it) brain cannot tell which of two fibers are activated with pain.

Answer 63

Somatic Senses: Fine Touch -Primary sensory neurons from receptor to MEDULLA -secondary sensory neurons always cross over from medulla--> thalamus Tertiary sensory neurons --> Somatosensory cortex (post central gyrus) Fast Pain (alpha Delta fibers) -Primary sensory neurons from receptor to SPINAL CORD (laminae II and V of the Dorsal Horn) secondary sensory neuron: always cross over in Spinal Cord to THALAMUS Tertiary sensory neuron --->somatosensory cortex (post central gyrus) process; fine touch (ascend dorsal column-->medulla-->thalamus-->cortex -Fast Pain (Adelta) : desiccate--> ascend contralateral side of thalamus--> cortex

Answer 64

Trigeminal nerve- info comes in through the spinal tract into main sensory nucleus to first synapse there, Then it decussates and ascends into thalamus (through trigeminal lemniscius and trigmenial thalamic tract)

Answer 65

Homunculus and somatotopic organization for fine touch are organized in thalamus, nucleus cuneatus/gracillius and organized across spinal cords in those tracts (same for fine touch, anterolateral and Motor pathway) ***The Somatic organization (homunculus also occurs) also applies for fine touch, anterolateral pathway (pain) and Motor activity and their pathways. homunculus for cortex: used for both sensory and motor information .

Answer 66

Somatosensory Cortex -Cortical Somatotopy (homunculus) : represents the landscape or number of neurons dedicated to encoding Fine touch in hands, lips and touch in these areas, more neurons encode somatosensory information to do better 2 point discrimination (determine where an object is better localized on skin) finest 2 point discrimination on finger types to protect and perceive different textures of objects.

Answer 67

Somatosensory Cortex -Primary somatosensory cortex (S1) = Brodmann's Area 3b Adjacent areas: -Postcentral gyrus: 3a, 1, 2 -posterior parietal cortex: 5, 7 area 1: sense texture of object area 2: perceive shape and size of object; more involved with proprioreceptoin although you get same info into 3b, that is processed to other ares with different neural network structures to extract different features from initial sensory info Once 3b 1 and 2 are done with extraction and processing, they are then transmitted through cortical areas 5 7 (change from knowing if it is an edge on object, to what actual object is) **areas 1, 2, 5, 7: building of small pieces of sensory phenomenon into something you can understand as an object.**

Answer 68

Cortex Architecture -different stains (*Golgi stain (big pyramid neurons) *Nissle stain (big neurons, and small neurons); *Weigert stain (stain fibers; afferent come up from thalamus into regions, horizontal fibers) ***The neocortex has SIX layers (each layer has the role of extracting APs into something that one can sense and perceive. -**Extremely complex -**repeated motifs -**Well organized

Answer 69

Vernon Mountcastle talked about cortical columns in a newspaper review in cortex, there are are processing units: you can count 30 cells in a column the column extracts one thing from sensory world and columns are linked together each fibrisae- has hair cell receptors; somatopy of virbraise pad represented thought CNS -barrel shaped objects called barrels (in rat cortex) that relate to whisker in barrel column: that processes information from one particular whisker (delineation work across cortex) use visual cortex of cortical columns; individual columns might process and favor movement in different directions (ex: left, northeast, west, etc) cortex: we directional receptive fields and colors seen . cortical columns: basic building blocks of the way brain works

Answer 70

Cortical connections: the process of somatosensory information traveling up VPL thalamus and arriving at Layer 4 (third synapse of layer 4 neurons) those neurons make a synapse on layer 2. Cell bodies are on layer 3. These neurons send projections back down yo to thalamus. Layer 4 neurons will also synapse on Layer 5 neurons which send information to other brain regions -**Hence information flows through circuit into layer 4, up to 2, 3 down to 5 and 6**

Answer 71

Lateral fibers running throughout cortex at each layer At, each layer, there is a dense interconnect between cortical columns. These interconnects are important for receptive fields. Neural coding: you touch receptive field and neuron fires, which activate preferential pathway and activate specific cortical column. As stimulus gets greater, higher probably of activating neighboring cortical columns (as stimulus gets stronger and stronger) This amplification and recruitment are decoded as how strong that information was.

Answer 72

interconnects between cortical column, allows one column to shut off its neighboring column. information is coming up from pathway 1, these columns will be preferentially activated, but will send information to other columns to shut everything else off (by making Peak in graph as sharp as possible) neighboring neuron doing the same thing will clarify and differentiate two peaks in graphs (if preferential column tries to shut off other column) This provides clear separation of peaks (to determine 2 point discrimation or determine where an edge is) allow the ability shape receptive fields and differentiate two places in space

Answer 73

Classical systems; -the Number of nuclei is DIFFERENT in different sensory systems -Use VENTRAL thalamic nuclei that project to Primary sensory cortices -neurons processes only input from ONE sensory modality Non-classical systems -Use DORSAL and MEDIAL thalamic nuclei that project to SECONDARY cortices and other parts of the CNS -Receive input from MORE than one sense ex; receive information from 2 different sensory receptors (2 different corpuscles )

Answer 74

Non-classical pathway (ex: pain pathways); Usually sensory input is suppose to go to dorsal thalamus (like in classical) , but also sends fibers to reticular formation (like locus cerrelus to create AROUSAL signal, wake animal up) and from thalamus it normally goes straight to SI cortex, BUT it can also go to Limbic system, Association cortex and secondary somatosensory system (SII). This variations of classical pathways seen in this pathway allows us much more Complex associations and perceptions of our environment. "Rat somatosensory pathway: info comes up Dorsal column-->reticular formation--> medial lemniscus to thalamus and goes to primary somatosensory cortex. This pathway encodes, "WHERE" something happened in space, and how much it did. Classical pathways; Sensory info from skin receptors moved though dorsal column, decussate (cross midline) and go through VPL to primary somatosensory cortex (SI)

Answer 75

*Rat somatosensory pathway: info comes up Dorsal column-->reticular formation--> medial lemniscus to thalamus and goes to primary somatosensory cortex (SI) . This pathway encodes, "WHERE" something happened in space, and how much it did. *Non classical pathways; encodes more information about "WHAT" happened; like textures and more rich information These pathways show how different they are and how they can be used together

Answer 76

Connections of the Visual Cortex: connections -Primary Visual Cortex (V1) -Input from LGN -Output to all other levels Secondary Visual Cortex (V2) -Output to all other Levels -After V2: -output to the parietal lobe- Dorsal stream -output to the inferior temporal lobe- Ventral Stream -Output to superior temporal sulcus (STS) - STS stream ***Visual information will comine in and initially end up in V1 (primary visual cortex). This information will then be processed in occipital lobe and go through secondary visual cortices V2, V3 and V4. Once information reaches these cortices, it will be processed into 1 of 2 pathways: either into dorsal stream to parietal lobe (for visual guidance of movements; "WHERE" or Ventral stream (in temporal lobe, for object perception for knowing "WHAT" object is present) It can also go to STS (superior temporal stream) which in involved in visuospatial functions like biological movement.

Answer 77

Dorsal stream: Visual guidance of movements Ventral stream: Object perception STS (superior temporal stream ): visuospatial functions (bio movement)

Answer 78

after goes sensory information goes through secondary processes (V1-V4), it ends up in association areas l like PREFRONTAL CORTEX to allow you to build behaviors off of what you perceive in world around you . starts with sensory info coming in--> sensation--> perception to secondary cortices--> become information to generate behavior in high cortices (like cortex) ***integration of input from different sensory systems occurs in ASSOCATION CORTICES***

Answer 79

Disorders of Sensory systems: -impaired conduction of physical stimulus to receptors -Impaired functions of receptors -Impaired function of sensory nerves (ex: hearing loss) -Impaired or changed function of central nervous system