Lecture #5 Plasticity, Healing, Aging

Question 1

Plasticity

Answer 1

• Experience can influence neural activity
• Maximal during critical periods

Question 2

Critical Period

Answer 2

• Time which a behavior requires specific environmental influences to develop normally

Question 3

Significance of Plasticity

Answer 3

• Provide individuality
• Recovery of function following brain trauma

Question 4

Functional alterations of neural circuitry

Answer 4

• Changes in the existing synaptic connections

Question 5

Anatomical alterations of neural circuitry

Answer 5

• longer term
• Growth of new synaptic connections

Question 6

Short-Term

Answer 6

• Facilitation
• Depression
• Last a few minutes or less

Question 7

*Facilitation

Answer 7

• Elevation of presynaptic Calcium levels
• Increase in neurotransmitter release
• Bigger Postsynaptic potential

Question 8

*Depression

Answer 8

• Decrease in neurotransmitter release in response to high-frequency stimulation
• Progressive depletion of synaptic vesicles

Question 9

Long-Term

Answer 9

• Anatomical Change
• Long term Potentiation (Cerebellum)
• Long term depression

Question 10

State-Dependent

Answer 10

The state of the membrane potential of the postsynaptic cell determines whether or not LTP occurs

Question 11

Input Specificity

Answer 11

• LTP induced by activation at one synapse does not occur in other

Question 12

Associativity

Answer 12

• If one synapse is weakly activated while adjacent synapse onto the same cell is strongly activated, both synapses undergo LTP

Question 13

Steps of Long-Term Potentiation

Answer 13

• High-frequency stimulation with release of glutamate
• Simultaneous depolarization through non-NMDA receptors & activation of NMDA receptors
• Large and fast increase of Calcium

-Activation of Calcium dependent enzymes (intracellular signaling pathways)

Question 14

Effects of Long-Term Potentiation

Answer 14

• Increase in sensitivity to the neurotransmitter
• Increase in excitatory postsynaptic potential size
• Change in gene expression and synthesis of proteins

Question 15

Potential cellular and molecular mechanisms of Hebb’s Postulate

Answer 15

Cells that fire together, wire together

Question 16

Steps of Long-Term Depression

Answer 16

• Low frequency stimulation with release of glutamate
• Simultaneous depolarization through non-NMDA receptors & activation of NMDA receptors
• Small and slow increase of Calcium
• Activation of Calcium dependent enzymes (intracellular signaling pathways)

Question 17

Effects of Long-Term Depression

Answer 17

• Decrease in sensitivity to the neurotransmitter
• Decrease in excitatory postsynaptic potential size
• Changes in gene expression and synthesis of proteins

Question 18

Growth of New Synaptic Connections

Answer 18

• Long lasting effects of long term potentiation
• Pruning of preexisting synapse and production of new ones

Question 19

Memory

Answer 19

Long-term potentiation in the hippocampus can help with consolidating memories of events and facts

Question 20

Primary Somatosensory Cortex

Answer 20

The area previously dedicated to the amputated digit becomes dedicated to the adjacent digits

Question 21

Primary Motor Cortex

Answer 21

Areas previously dedicated to the hands become dedicated to the feet

Question 22

Intermodal

Answer 22

Blind humans reading Braille have increased blood flow In both primary visual and visual association areas

Question 23

What is important about Cortical Maps?

Answer 23

Activation of previously inactive connections is thought to play an important role

Question 24

Tissue healing involves?

Answer 24

• Regeneration
• Repair
• Combination of both

Question 25

What is Regeneration?

Answer 25

Regrowth of original tissue

Question 26

Regeneration occurs only if?

Answer 26

• Parenchymal cells can undergo cell mitosis
• Surrounding connective tissue is intact

Question 27

Regeneration must have cells that can?

Answer 27

Divide

Question 28

What is Repair?

Answer 28

• Replacement of non regenerated parenchymal cells with connective tissue
• Formation of a connective tissue scar

Question 29

Repair occurs with?

Answer 29

• Necrosis of permanent parenchymal cells
• excessive necrosis of tissues

Question 30

Neurons

Answer 30

• Majority are not capable of regeneration
• Neurogenesis requires a population of neural stem cells
• Neural stem cells only give rise to interneurons in the olfactory bulb and hippocampus

Question 31

Neuron axons and dendrites can regenerate if?

Answer 31

• Their cell bodies, basement membranes, and endoneurium are intact
• Cell body intact, scaffolding present

Question 32

Glial Cells

Answer 32

• Capable of regeneration
• Responsible for repair

Question 33

Damage to the PNS and CNS can occur from?

Answer 33

• Physical Trauma
• Hypoxia
• Degenerative disease

Question 34

CNS Repair occurs in response to?

Answer 34

Neuronal cell death through necrosis/apoptosis

Question 35

Necrosis

Answer 35

• sequence of morphologic changes that occur in irreversibly injured cells

Question 36

Apoptosis

Answer 36

Programmed cell death

Question 37

Breakdown and Removal of Necrotic Tissue

Answer 37

Formation of an Empty Cavity

Question 38

Microglia & Macrophages

Answer 38

Phagocytosis and produce and secrete chemical mediators and growth factors

Question 39

Endothelial Cells

Answer 39

Involved in angiogenesis

Question 40

Fibroblasts

Answer 40

• Only present if blood-brain barriers are broken / Menings are penetrated

Question 41

Astrocytes

Answer 41

• Involved in gliosis and produce and secrete many molecules that serve structural functions

Question 42

Gliosis

Answer 42

Astrocytes form a dense aggregate with their cytoplasmic processes within the empty cavity

Question 43

Purpose of CNS Repair

Answer 43

• Reestablish the physical and chemical integrity in the CNS

Question 44

Axonal Regeneration occurs in response to?

Answer 44

Damage to axons

Question 45

Axotomy

Answer 45

• Transaction of an axon more slowly by crushing
• Axon Regeneration more likely to occur

Question 46

Axon Degeneration

Answer 46

• Proximal Segment: undergo reversible ultrastructural changes
• Distal Segment: Undergoes Wallerian degeneration, nerve terminals fail rapidly

Question 47

Migration and Proliferation of Cells

Answer 47

• PNS: Schwann, promote axon regeneration
• CNS: Astrocytes, form glial scars that prevent axon growth and secrete molecules that inhibit axon regeneration
• Oligodendrocytes: inhibit axon regeneration

Question 48

Axonal Sprouting - PNS

Answer 48

• Axonal sprouts grow from the proximal segment, enter the connective tissue of the distal segment
• Process largely directed by Schwann Cells

Question 49

Axonal Sprouting - CNS

Answer 49

• Axonal sprouts approach glial scars
• Axonal growth cones develop bulbous abnormalities and unable to migrate through glial scar

Question 50

Significance of Axon regeneration

Answer 50

• Restore normal tissue structure and function
• Axonal regeneration is greater in the PNS

Question 51

What in the PNS are critical to successful regeneration?

Answer 51

Schwann cells

Question 52

What prevents neuronal regrowth in the CNS?

Answer 52

Formation of glial scars

Question 53

Damage in the CNS

Answer 53

Neuronal cell death

Question 54

Greater life expectancy increases?

Answer 54

the risk of dementia - impaired memory and cognitive capacities

Question 55

What is the most common cause of senile dementia?

Answer 55

Alzheimer disease

Question 56

Similarities of the Mechanisms of Aging

Answer 56

• May result from changes in informational macromolecules (DNA, RNA, and proteins)

Question 57

What are the 3 mechanisms of Aging

Answer 57

1. Errors in the duplication of DNA increase with age
2. There is a specific genetic program for aging
3. A cell can only divide a limited number of times

Question 58

Structural Alterations for CNS (5)

Answer 58

1. Decrease in Brain Volume and Weight - loss of tissue and neuron shrinkage
2. Decrease in Nerve Conduction Velocity - fragmentation and loss of myelin
3. Decrease in receptors and neurotransmitters
4. Decrease in and alterations of synapses
5. Increase in concentration of Plaques and Tangles

Question 59

Senile Plaques

Answer 59

• Extracellular deposits of beta-amyloid protein

Question 60

Neurofibrillary Tangles

Answer 60

• Filamentous inclusions
• Lesions are abundant in Alzheimer disease

Question 61

Structure Alterations for PNS (4)

Answer 61

1. Decrease in Number of Unmyelinated and Myelinated Nerve Fibers - loss of motor units
2. Decrease in Nerve Conduction Velocity - fragmentation and loss of myelin
3. Alterations of Density and Morphology of Sensory Receptors - vestibular, visual, and somatosensory systems
4. Decrease in and Alterations of Synapses

Question 62

Age-related structural alterations can cause

Answer 62

• Diminished blood supply occurs in the CNS and PNS

Question 63

Motor functional alterations

Answer 63

• Posture less erect,
• Postural reflexes are slowed
• Slow Gait
• Stride length shorter
  Increase in risk of falls

Question 64

Cognitive functional alterations

Answer 64

• Decrease in speed of learning, problem-solving, and general intelligence