this is the second lecture in the series on the "neurocranium" and dealt with a variety of topics such as structure of the brain, functions of each lobe, blood supply, spinal cord, meninges, glial cells, and the blood brain barrier.
the cerebral portion of the brain is divided up into different lobes, which have been shown to have distinct cognitive and emotional correlates. for example, the frontal lobe is the primary motor area, and is also involved in speech and behavior. the parietal lobes are involved in somatosensory input, prioprioception, sense of self. the temporal lobes are involved in audition, olfaction, and memory. the occipital lobes are involved in vision. cerebellum, midbrain, medulla, are underneath the cerebral portion and are involved more in basic physiological processes. for example, the medulla is involved in autonomic regulation of the cardiovascular system and respiration. the hypothalamus is involved in autonomic, affective, and hormonal activity. the midbrain is involved in motor control. the cerebellum is involved in motor coordination and timing.
the blood supply to the brain comes ultimately from the brachiocephalic branch of the aorta, which branches into the common carotid and the subclavian. the vertebral arteries branch off of the subclavian, travel in the transverse foramen of C1-C6,
and penetrate the atlanto-occipital membrane. from there they ascend on the ventral surface of the brainstem and combine to form the basilar artery, from which other arteries branch out (see diagram) such as the pontine and cerebellar arteries. the common carotid artery, on the other hand, branches into the internal and external common carotid; the internal common carotid branches into the anterior and middle cerebral arteries, which supply blood to the lateral and medial cerebral cortex, internal capsule, basal ganglia, and cingulate gyrus. the occlusions in each of these small branches can produce different effects (see diagram).a few details about the spinal cord: it extends down to L1, beyond which the dura extends until S2. the spinal cord ends at the conus medullaris, a tapering down of the cord which ends in the caudus equinus, which is a splaying out of a horse tail-like arrangement of nerve rootlets. around the spinal cord, there are the three meninge layers: pia, arachnoid, dura mater. denticulate ligaments are pial "projections" into the arachnoid and dura mater which serve to anchor the spinal cord. the filum terminale is the pial strand that connects from the end of the spinal cord (L1) to the end of the dural sac (S2).
a few notes about glial cells and the blood brain barrier. glial cells were covered briefly in histology as the cells that "support" the neurons. in the central nervous system these cells are astrocytes, oligodendrocytes. oligodendrocytes are the cells that produce the myelin sheath that increases the rate of neuronal conduction. whereas schwann cells can only wrap around 1 axon, a single oligodendrocytes can wrap up to 50 different axons. astrocytes provide electrical insulation between neurons, secrete neuronal growth factors and cytokines, and absorb neurotransmitters. they can be further divided into protoplasmic and fibrous- fibrous astrocytes are involved in repairing damaged neuronal tissue. astrocytes also aid in the maintenance of the blood brain barrier, which is made up of astrocyte foot processes, basal lamina, pericytes, and endothelium.
questions
general anatomy and fissures...
1. cerebral hemispheres include...
2. the cerebral cortex is the site for...
3. what are gyri and sulci/fissures?
4. what are the three main fissures in the brain?
5. what does the longitudinal fissure separate?
6. what does the lateral fissure separate?
7. what does the central fissure separate?
functions of...
8. frontal lobe
9. parietal lobe
10. occipital lobe
11. temporal lobe
12. medulla
13. cerebellum
14. pons
15. midbrain
16. thalamus
17. hypothalamus
cerebral arteries...
18. where does the common carotid artery branch off from?
19. where does the common carotid artery split?
20. what does the internal carotid artery split into?
21. what does the internal carotid artery supply blood to?
22. what is the difference between an ischemic and hemorrhagic stroke?
23. where does the middle cerebral artery run?
24. what do the cortical branches supply blood to and what occurs during a stroke of these arteries?
25. what do the lateral striate branches supply blood to and what occurs during a stroke of these arteries?
26. what does the anterior cerebral artery supply blood to?
27. what happens after stroke in the anterior cerebral artery?
basivertebral arteries...
28. describe the passage of the vertebral artery.
29. vertebral arteries unite to form...
30. where is the path of the basilar artery? what does it branch into?
31. what does occlusion in the anterior and posterior spinal branch lead to?
32. what does occlusion in the posterior inferior cerebellar branch lead to?
33. what does occlusion in the anterior inferior and superior cerebellar branch lead to?
34. what does occlusion in the pontine arteries lead to?
35. what does occlusion in the labyrinthine branch lead to?
36. how do occlusions of the vertebral basilar arteries result in deficits in vision?
37. how do occlusions of the vertebral basilar arteries result in problems with balance?
posterior cerebral and circle of willis...
38. where does the posterior cerebral artery project to?
39. what happens when the posterior cerebral artery is occluded?
40. what is the circle of willis?
41. what does the anterior communicating artery connect?
42. what does the posterior communicating artery connect?
spinal cord...
43. how far down does the spinal cord extend?
44. how far down does the spinal dura extend?
45. what is the conus medullaris?
46. what is the cauda equina?
47. where is the junctional zone between the central and peripheral nervous systems?
48. what does the dura turn into at this point?
meninges and spinal veins...
49. how far down does the dura mater extend?
50. what is in the epidural space?
51. what is arachnoid mater?
52. what are denticulate ligaments?
53. what is the filum terminale?
54. where would one extract CSF from the spinal cord?
55. what are the two ways of administering anesthetic to the spinal cord?
56. what does the basivertebral vein do?
57. what is the connection between the basivertebral veins and prostate cancer?
58. describe the vertebral vein's use as a shunt.
glial cells and blood brain barrier...
59. what are oligodendrocytes and what do they do?
60. "unlike schwann cells, oligodendrocytes do not..."
61. what do astrocytes do?
62. what is the difference between protoplasmic and fibrous astrocytes?
63. what are microglia and what do they do?
64. what cell types line the ventricles?
65. what makes up the blood brain barrier?
66. what is the blood brain barrier maintained and induced by?
67. describe the transport of glucose, amino acids, and gases through the blood brain barrier.
68. which brain regions is there no blood brain barrier?
answers
1. white matter, basal ganglia, cerebral cortex.
2. sensorimotor integration, perceptive quality of our experiences
3. gyri are convolutions of the cortex and sulci are divisions or gaps between the gyri.
4. longitudinal, lateral, central.
5. the left and right hemispheres.
6. the frontal and temporal lobes.
7. the frontal and parietal lobes.
8. primary motor area, speech, behavior
9. sensorimotor, prioprioception, association of sensorimotor-audition-vision, formation of egocentric space, sense of self
10. vision
11. audition, olfaction, memory
12. autonomic control over respiration, cardiovascular systems
13. motor coordination and timing
14. cerebellar connection
15. motor control
16. sensorimotor information to cerebral cortex
17. autonomic, hormonal, affective activity
18. the brachiocephalic branch of the aortic arch.
19. at the carotid sinus into the internal and external carotid arteries.
20. anterior and middle cerebral arteries
21. most of the cerebral hemispheres.
22. ischemic is blockage of the cerebral artery via a thrombus or embolus which leads to necrosis. hemorrhagic is rupture of the artery which causes a hematoma, which leads to necrosis.
23. in the lateral fissure; along the lateral surface of the cerebral cortex.
24. lateral surface of cortex. stroke causes sensory, motor, language deficits.
25. internal capsule and basal ganglia. stroke causes hemiplegia.
26. medial surface of cerebral cortex, including cingulated gyrus.
27. sensory, motor, emotional deficits.
28. branches off the subclavian artery, passes through transverse foramina of C1-C6, and penetrates the atlanto occipital membrane.
29. basilar artery on ventral medulla.
30. the ventral surface of the brainstem; branches into cerebellar, pontine, posterior cerebral arteries.
31. loss of spinal cord function
32. Wallenberg syndrome: loss of sensation of pain, heat, muscle coordination.
33. loss of muscle coordination.
34. cranial nerve dysfunction.
35. deafness and vertigo.
36. torsion/compression of vertebral basilar arteries can reduce blood flow to brain stem, cerebellum, occipital lobe- anoxia in the occipital lobe causes loss of vision.
37. anoxia in cerebellum or inner ear can cause problems with balance.
38. temporal and occipital lobes.
39. visual deficits.
40. the anterior and posterior communicating arteries.
41. anterior cerebral arteries.
42. middle and posterior cerebral arteries.
43. down to L1.
44. down to S2.
45. tapered end of the spinal cord.
46. the “horse’s tail”, the end of the spinal cord which branches into nerve roots that extend to lumbar and sacral foramina.
47. the intervertebral foramina
48. the epineurium that covers the dorsal and ventral rami and ganglia.
49. S2
50. veins and fat.
51. the meninge layer in between the dura and pia mater, with trabeculae inside the subarachnoid space.
52. pial connective tissue that suspends spinal cord to the inside of arachnoid / dura mater.
53. a pial strand that connects down to the end of the dural sac.
54. from the subarachnoid space.
55. to the epidural and subdural spaces.
56. drains vertebral bodies.
57. prostate cancer can metastasize into vertebrae through the basivertebral veins.
58. blood shunts from caval veins into vertebral veins if IVC constricted (while coughing, for example)
59. cells in the CNS that myelinate up to 50 axons.
60. "cover unmyelinated axons, which lay bare in the CNS"
61. electrically insulate neurons from each other, uptake neurotransmitters and ions, and secrete neuronal growth factors and cytokines.
62. protoplasmic interconnect neurons, induce early growth and development of the blood/brain barrier, whereas fibrous form astrocytic scars after brain tissue destruction.
63. phagocytic cells related to monocyte/macrophages which consume debris and secrete cytokines during inflammation.
64. ependymal cells.
65. endothelium, pericytes, basal lamina, astrocyte foot processes.
66. maintained by astrocytes.
67. glucose and amino acids pass through BBB via transport proteins, and gases diffuse through lipid membrane.
68. hypothalamus, area postrema, other periventricular regions.
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