• Typical Electrical Neuron & Chemical Synapse
• At Neuron Terminal
  • Depolarization causes calcium gates open
  • Calcium flows into terminal
  • NT is released [Read more…]

• 300+ types
  • Most Common In Brain
    • Glutamate 90%
    • GABA 9%
  • Other 1% [Read more…]

• Hormones
  • Inexact definition
  • Secreted from glands
  • Endorphins [Read more…]

• I. Stimulants
  • Mostly psychological dependence
  • No physiological addiction
  • Also called analeptics
  • Invigorating or restorative
  • Effects [Read more…]

Brain Development

18 days after conception

Primitive streak

• Outer layer of embryo thickens
• Ectoderm forms a plate
• Edges curl up
• Make a neural tube
• Cells inside tube become neurons & glial cells

Tube with 3 bulges

1. Forebrain

• Cerebral cortex
• Basal ganglia
• Limbic system
• Thalamus
• Hypothalamus

2. Midbrain

• Superior colliculi = vision
• Inferior collicui = hearing
• Homeostasis & reflexes

3. Hindbrain

• Medulla oblongata
• Cerebellum
• Pons

Two Phases

1st Phase: Symmetrical division

• 2 identical founder cells
• radial glial cells
• Spread out like tree
• Neurons climb tree to their proper position

2nd Phase: Asymmetrical Division

• About 3 months
• Divide into neuron & founder cells
• End of cortical development
• founder cells receive signal (cell death)

Five Stages of Neurons

1. Proliferation

• Production of new cells
• Cells along the ventricles divide to become neurons and glia.

2. Migration

• Primitive neurons find their spots
• Chemicals guide cells

3. Differentiation

• Neurons get axon & dendrites
• Makes them different
• Axon grow before dendrites
• During migration

4. Myelination

• Glia cells produce myelin sheaths
• first in spinal cord
• Then in brain
• Lasts til about 30

5. Synaptogenesis

• Continues throughout life
• Forming synapses

 

Brain Anatomy

2 Fists; Cross your arms

Occipital Lobes

Temporal Lobes

Parietal Lobes

Frontal Lobes

1. Primary Motor Cortex
2. Pre-Motor Cortex

Supplemental Motor Cortex

• Mirror neurons
• Connect directly to spine
• Help, don’t know how
• balance?
• coordination?

Pre-Motor Cortex

• Connects direct to spine
• Not fully understood
• Planning?
• Spatial guidance?
• Actions of others?

Posterior Parietal Cortex

• 3-D view of world

3. Pre-Frontal Cortex

Dorsolateral

• fairly new
• develops til 30
• connects to basal ganglia+
• rules about rules
• working memory
• damaged in schizophrenia
• drug abuse
• alcohol
• ?

Orbitofrontal

• above the eyes
• Gambling
• Alzheimer’s
• Drug addiction
• Also rules about:
  • decision making
  • inhibit bad behavior
• OCD
• Overruling reflexes: antisaccade task
  • Object appears in periphery
  • Must look in opposite direction
  • Top-down processing overruling reflex
  • Improves with age unless
  • Very young (hard to look away from attention getter)
  • ADHD

Ventromedial

• regulation of emotion
• decision making
• rules about
• risk
• fear

Other Structures

• Anterior Cingulate Cortex
• Corpus Callosum
• Hippocampus

Connections

• When neurons reach home, connect with each other
• Grow dendrites & axons
• Synapse formation
• Synapse elimination

Pathfinding

• Getting axons to their spots
• Chemical Path-finding

Weiss (1924)

• grafted extra leg to a salamander
• axons grew, moved in sync with other legs
• theory:
  • nerves attach to muscles randomly
  • variety of messages are sent
  • each one tuned to a dif. muscle

Sperry (1943)

• Severed optic nerve axons
• Rotated them 180°
• Grow back to their original target locations in midbrain

Chemical Gradients

• Axons attracted by some chemicals, repelled by others
• TOPDV protein is 30x more concentrated in dorsal retina than ventral retina axons
• Highest connect to highest
• Lowest concentration axons connect to lowest

Neural Darwinism

• During development
• Synapses form randomly
• Selection process keeps some and rejects others
• Chemical guidance
• Neurotrophic factors

NGF

• Muscles & synapse survival produce & release NGF (nerve growth factor)
• Not enough NGF, axons degenerate and cell bodies die
• Neurons automatically dieif don’t make synaptic connection
• Apoptosis = cell death

Neurotrophin

• promotes survival & activity
• similar to NGF

BDNF

• Brain-derived neurotrophic factor
• most abundant neurotrophin in cortex
• Make more than enough
• Neurotrophins are also
• used in adult brains
• More axon & dendrite branching
• Deficiencies of neurotrophins lead to cortical shrinking and brain diseases

Cortex Differentiation

• Different parts of cortex have different shapes
• Shape and functions depend on input received
• If transplant immature neurons
• Become like neighbors
• If transplant later
• Some new, some old attributes
• Redesign our brain to fit (within limits)
• Experience fine tunes
• Enriched environments
• Thicker cortex
• More dendritic branching
• Best enrichment = activity

Age & Neurons

Stem cells

• Nose cells always undifferentiated
• Periodically divide & make new olfactory cells
• At 30, frontal cortex begins to thin
• Much individual variation

60+

• Synapses alter more slowly (learn)
• Hippocampus gradually shrinks
• Compensate by using more brain areas

 

Blood-Brain Barrier

(Paul Ehrlich, 1800’s)

• Injected blue dye into animals
• All tissues turned blue EXCEPT brain and spinal cord

Why need BBB?

• Keeps most chemicals out of brain
• Brain has no immune system
• Neurons can’t replicate-replaced
• No way to fix damage
• Viruses that do enter kill you
  • Rabbies
• Neural disorders last whole life
  • Chicken pox-shingles

How it works

Semi-permeable

• Keeps out harmful chemicals
• Keeps out medications
• Cancer med
• Dopamine for Parkinson’s

Astrocytes form layer around brain blood vessels

• may be responsible for transporting ions from brain to blood

Endothelial cells line capillaries

• Small spaces between each
• Some things can move between them
• Loosely joined in body, large gaps
• Tightly joined in brain, blocking most molecules

Large molecules can’t easily pass thru

Molecules with a high electrical charge are slowed down

What can cross passively

• Small uncharged molecules
• Oxygen & carbon dioxide
• Molecules dissolve in fats
• Capillary walls are fats

What can cross actively

• An active transport system
• protein-mediated process
• uses energy to pump chemicals
• E.g., burn glucose for energy

Broken by:

• Hypertension (high blood pressure)
• Development (not fully formed at birth)
• High concentrations of some substances
• Microwaves & radiation
• Inflammation
• Brain injury
• Infections
• Alzheimer’s disease
  • endothelial cells shrink
  • makes gaps
  • harmful chemicals enter

Nourishing Neurons

• Almost all need glucose
  • Practically only nutrient that crosses blood-brain barrier in adults
  • Ketones can also cross but are in short supply.
• If you can’t use glucose: Korsakoff’s syndrome
  • thiamine (vitamin B1) deficiency
  • inability to use glucose
  • neuron death
  • severe memory impairment

Transfer

• Far transfer = do well in one, do well in other tasks
• Near transfer = practice task, do better on that task only
• Train the brain – doesn’t work

Blind from birth

• better at discriminating objects by touch
• increased activation in occipital lobe (vision) doing touch tasks
• Use occipital cortex for Braille
• sighted people don’t
• Concept of straight

Learning to read

• Learn to read as adults
• More gray matter in cortex
• Thicker corpus callosum

Music Training

• Pro musicians
  • Bigger temporal lobe (30%)
  • 2x greater response to pure tones (in auditory cortex)
• Violin players
  • larger area devoted to left fingers in the postcentral gyrus
• Writer’s Cramp (Violinist’s Cramp)
  • Spend all day writing
  • Fingers get jerky, clumsy & tired
  • Practice too much
  • expanded representation of each finger overlaps neighbor

 

 

 

 

[Read more…]