003 Meninges, Ventricular System, and Cerebrospinal Fluid Flashcards Preview

Neuroanatomy - Exam 1 > 003 Meninges, Ventricular System, and Cerebrospinal Fluid > Flashcards

Flashcards in 003 Meninges, Ventricular System, and Cerebrospinal Fluid Deck (40)
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1
Q

dura mater

A

 Outermost layer
 Thickest layer
 Composed of dense irregular connective tissue (collagenous)

2
Q

o Arachnoid mater

A

 Delicate middle layer
 Loose connective tissue
 Avascular
 Contacts inner surface of dura mater
 Arachnoid villi (AKA granulations or pacchionian villi) are specialization of the arachnoid that recycle CSF into the blood
 Attached to the pia mater by trabeculae that span the true subarachnoid space which is filled with CSF
 Has subarachnoid cisterns which are extended regions of the subarachnoid space that serves as reservoirs of CSF

3
Q

Pia mater

A

 Very thin layer
 Inner layer that is adherent to the CNS
 Highly vascular
 Denticulate ligaments
• Folds of extra thick pia mater located on the lateral aspects of the spinal cord
• Span the subarachnoid space and attach to the arachnoid
• Help anchor the spinal cord
 Filum terminale (AKA filum terminale internum)
• Single midline continuation of the pia mater that attaches the conus medullaris to the inferior aspect of the dural sac
• Anchors end of spinal cord to the vertebral column
 Tela choroidea
• Found in specific regions in each of the ventricles of the brain
• Folds of pia mater that support the choroid plexus, which is modified ependymal cells that produce CSF
o Subarachnoid space
 Between the arachnoid and the pia mater
 Filled with CSF

4
Q

Denticulate ligaments

A
  • Folds of extra thick pia mater located on the lateral aspects of the spinal cord
  • Span the subarachnoid space and attach to the arachnoid
  • Help anchor the spinal cord
5
Q

Filum terminale

A

(AKA filum terminale internum)
• Single midline continuation of the pia mater that attaches the conus medullaris to the inferior aspect of the dural sac
• Anchors end of spinal cord to the vertebral column

6
Q

Tela choroidea

A
  • Found in specific regions in each of the ventricles of the brain
  • Folds of pia mater that support the choroid plexus, which is modified ependymal cells that produce CSF
7
Q

Subarachnoid space

A

 Between the arachnoid and the pia mater

 Filled with CSF

8
Q

• define the leptomeninges and pachymeninx

A

o Leptomeninges
 Arachnoid and pia mater
o Pachymeninx
 Dura mater

9
Q

• list the general functions of the meninges

A

o Protection of CNS
o Keeps the brain and the spinal cord from collapsing under its own weight because CSF keeps them floating
o Involved in the blood supply of the CNS

10
Q

• compare and contrast the cranial and spinal dura mater

A

o dura mater is made of two layers that are fused together except at the dural venous sinuses
o Cranial
 Periosteal (AKA endosteal)
• Outer layer that forms the periosteum on the inner side of the inner table of the skull bones that form the cranial vault
• Fused to the inside of compact bone of the parts of the skullthat form the cranial cavity
 Meningeal
• Inner layer surrounding the brain
• Thinner than periosteal layer
• Inner surface is lined with simple squamous epithelium
• Forms tubular sheaths for cranial nerves as the exit the skull
o Sheaths transition into the epineurium of these nerves once they exit the skull
o The dural sheath of the optic nerve is continuous with the sclera
o Spinal Column
 Dura mater only has one layer that corresponds to the meningeal layer in the skull
 Ends inferiorly at the level of the 2nd sacral segment
 Anchored to the coccyx by the coccygeal ligament
 Does NOT attach to the surrounding bone so there is a true epidural space in this region
• Filled with fat and internal vertebral venous plexus
 Still forms tubular sheaths like in the cranium
 Dural Root sleeves transition into the epineurium of spinal nerves

11
Q

• explain the epidural and subdural spaces and their clinical significance

A

o Epidural space
 Only exists abnormally when the periosteal layer of the dura mater is torn and fluid is forced between the dura mater and the surrounding bone
o Subdural space
 Potential space that exists between the inner surface of the meningeal layer of the dura mater and the arachnoid
 Fluid can gather in this space (i.e. hematoma)
• Usually result from damage to external cerebral veins or dural venous sinuses

12
Q

Falx Cerebri

A

o Falx Cerebri
 Vertical partition that lies in the longitudinal fissure, so it is a single midline structure
 Attachments
• Anteriorly – crista galli of the ethmoid
• Superiorly – midline of cranial vault
• Posteriorly – internal occipital protruberance
• Inferiorly
o Posterior ¼ the midline portion of the tentorium cerebelli
o Anterior ¾ - free edge that does not attach to anything but lies along the corpus callosum

13
Q

Sinuses associated with falx cerebri

A
	Sinuses
•	Superior sagittal sinus
•	Inferior sagittal sinus
•	Straight sinus
•	Confluence of sinuses
14
Q

Falx Cerebelli

A

 Lies between the cerebellar hemispheres
 Attachments
• Anterior – free edge
• Posterior – midline of the skull in the region of the cerebellum
• Superior – falx cerebri and tentorium cerebelli

15
Q

Tentorium Cerebelli

A

 Horizontal
 Between the occipital lobes and cerebellum
 Tent shaped, with highest portion in the midline, which attaches to the posterior inferior portion of the falx cerebri
 Tentorial Notch
• Between the free margin and the dorsum sellae
• Midbrain is in this notch
 Peripheral attachments (anterior to posterior)
• Posterior clinoid processes
• Petrous portions of the temporal bones
• Grooves for the transverse sinus
• Internal occipital protruberance
 Sinuses
• Transverse sinuses
• Superior petrosal sinus
• Straight sinus
• Confluence of sinuses
 Divides the cranial cavity into two
• Supratentorial compartment – contains the forebrain
• Infratentorial compartment – contains the hindbrain

16
Q

Diaphragm Sellae

A

 Round horizontal sheet that forms a roof over the sella turcica/pituitary fossa
 Has a hole in the middle for the infundibulum (pituitary stalk)

17
Q

• describe blood and nerve supply of the dura mater

A
o	Blood Supply – meningeal arteries
	Anterior meningeal arteries
•	Arises from the ophthalmic artery
	Middle meningeal arteries
•	Largest
•	Arises from the maxillary arteries
•	Enters cranium through foramen spinosum
	Posterior meningeal arteries
•	Arise from occipital and/or vertebral arteries
o	Nerve supply
	Trigeminal Nerve – ophthalmic division
•	Anterior cranial fossa
•	Tentorium cerebelli
•	Lining of superior aspect of cranial cavity
•	Falx cerebri
	Trigeminal nerve – maxillary division
•	Middle cranial fossa
	Trigeminal nerve – mandibular division
•	Middle cranial fossa
	Vagus nerve
•	Posterior cranial fossa
	C1-3 spinal nerves
•	Posterior cranial fossa
	Spinal nerves (segmentally)
•	Spinal dura
	***irritation of the dura mater leads to headaches and migraines
18
Q

• describe the subarachnoid space, including the subarachnoid cisterns

A
o	Cisterna magna 
o	Superior cistern 
o	Mesencephalic cisterns 
o	Interpeduncular cisterns 
o	Chiasmatic cistern
o	Pontine cistern
o	Cisterns of the lateral cerebral fissure
o	Lumbar cistern
19
Q

Cisterna magna

A

(AKA cerebellomedullary cistern
 Largest cistern
 Located posterior to the medulla and inferior to the cerebellum
 Just above the foramen magnum
 Single midline structure
 CSF can be sampled from here but this is rarely done

20
Q

Superior cistern

A

(AKA cisterna vena magna cerebri)
 Deep in the space between the cerebral hemispheres and the cerebellum
 Posterior to the midbrain and superior to the cerebellum
 Single midline structure
 Contains the great cerebral brain

21
Q

Mesencephalic cistern

A

(AKA cisternae ambiens)
 NOT midline structures
 Located on the lateral sides of the midbrain, so have right and left
 Connect superior cisterns and the interpeduncular cisterns

22
Q

Interpeduncular cisterns

A
(AKA cisterna basalis)
	Located between cerebral peduncles 
	Anterior to the midbrain
	Single midline structure
	Oculomotor nerve runs through here
23
Q

Chiasmic cistern

A

 Small dilation of the subarachnoid space located just above the optic chiasm
 Single midline structure

24
Q

Pontine cistern

A

 Anterior to the pons
 Contains basilar artery
 Single midline structure

25
Q

Cisterns of the lateral cerebral fissure

A

 NOT midline structures, have right and left
 Located in the anterior aspects of the Sylvian fissures
 Between the frontal and temporal lobes of the cerebral hemispheres

26
Q

Lumbar cistern

A

 Only subarachnoid cistern NOT located in the head
 In the lower lumbar region of the spine
 Contains the cauda equine
 Usual place where CSF samples are taken via a lumbar puncture
 Single midline structure

27
Q

• describe the ventricular system of the brain

A
o	The remnants of the neural tube cavity in the region of the brain expand to form the ventricles of the brain
	lined with ependymal
	filled with CSF
o	4 ventricles in the brain
	2 lateral ventricles
	3rd ventricle
	4th ventricle
28
Q

Lateral ventricles

A

(right and left)
 Largest of the ventricles
 Horseshoe shaped (C-shaped)
 Remnants of the neural tube cavity in the region of the telencephalon
 Located in the cerebral hemispheres
 Parts
• Body (AKA pars centralis) – located in the parietal lobe
o Floor is formed by the thalamus
• Anterior horn (AKA anterior cornu) – located in the frontal lobe
o Left and right separated by septum pellucidum
 Double glial membrane
 Located in the midline
• Posterior horn (AKA posterior cornu) – located in the occipital lobe
• Inferior horn (AKA inferior cornu) – located in the temporal lobe
 Other C-shaped structures in relation to lateral ventricles
• Corpus Callosum
• Caudate nucleus
• Hippocampus

29
Q

Third ventricles

A

 Single structure in the midline
 Narrow cleft between the right and left halves of the thalamus
 Remnants of the neural tube cavity in the diencephalon
 In about 50% of people, the right and left halves of the thalamus form a solid bridge across the 3rd ventricle and meet in the midline
• Called interthalamic adhesion
 CSF leaves through the cerebral aqueduct
• Located on the posteroinferior aspect of the 3rd ventricle
• Represents the remnants of the neural tube cavity in the region of the mesencephalon

30
Q

4th ventricles

A

 Rhombus shaped
 Located in the region of the pons and medulla
 Represents the remnants of the neural tube in the rhombencephalon (both metencephalon and myelencephalon)
 The floor is considered the ventral side (anterior)
• AKA rhomboid fossa
• Consists of the posterior aspect of the pons and upper medulla
 The roof is its dorsal side (posterior)
• Made of 2 parts
o Superior medullary vellum (upper ½)
 Thin layer of neural tissue that separates the CSF of the 4th ventricle from the cerebellum
o Inferior medullary velum (lower ½ of the roof)
 Glial membrane that separates the CSF of the 4th ventricle from the cerebellum
 Openings
• Cerebral aqueduct – drains the 3rd ventricle into the 4th
• Central canal (of the spinal cord)
o Inferior opening
o represents the continuation of the neural tube cavity into the region of the spinal cord
o The ependyma here produces some serous fluid (that is not true CSF) that mixes with the 4th ventricle at the superior end of the central canal
• Foramen of Magendie (AKA median aperture)
o Single midline opening
o In the posterior aspect of the roof of the 4th ventricle
 In the region of the inferior medullary velum
o CSF can leave through this foramen to enter the cisterna magna
• Foramina of (von) Luschka
o Pair of openings (right and left)
o In lateral aspects of 4th ventricle
o CSF can leave through these to enter the pontine cistern of the subarachnoid space

31
Q

• describe the cerebrospinal fluid

A

o Produced by the choroid plexus
o A fluid that fills the ventricles of the brain and subarachnoid space
o There is a total of about 150 mL of CSF in the body
o 500 mL is produced daily
o Has a fairly rapid flow rate
o Much gets reabsorbed; it gets totally replaced 3x a day
o Similar in composition to blood plasma, with a few differences in ion concentrations
o Produced by
 Active transport of Na from the blood into the ventricles
 Water follows Na

32
Q

• describe the choroid plexus and how it works

A

o Made of
 fenestrated with diaphragms capillaries
 pia mater
 modified ependymal cells
o Supported by tela choroidea
o Some choroid plexus is in each of the ventricles

33
Q

• describe the pattern of flow of the cerebrospinal fluid

A

o Lateral ventricle
o Through Interventricular foramen of Monroe
o Into 3rd ventricle
o Through cerebral aqueduct
 AKA inter aqueduct; Sylvian aqueduct
o Into 4th ventricle
o Through foramen of magendie
 Into cisterna magna
o Through foramina of (von) Luschka
 Into pontine cistern (of the subarachnoid space)
o Flow in the suparachnoid space (sluggish flow rate)
 Mostly flows superiorly in the head to the sites of reabsorption
 Some flows into the spinal portion of subarachnoid space
• Travels inferiorly to the lumbar cistern
• Then travels back superiorly

34
Q

• What are arachnoid villi

A

o AKA granulations; pacchionian villi
o Envaginations of arachnoid that protrude mainly into the superior sagittal sinus
o Act as one-way valves that allow CSF to flow into the blood of the dural venous sinuses (recycling CSF back into the blood)

35
Q

o why the brain has to “float”

A

 Floating provides mechanical support
 Prevents the structures of the brain from being damaged under their own weight
 Floating caused by the buoyancy of the brain in CSF

36
Q

o epidural and subdural hematomas

A

 Epidural hematoma
• Caused by damage to the meningeal blood vessels
• Can causes detachment of the periosteal layer of the dura mater from the bone
• Blood is forced into the region between dura mater and the surrounding bone (this will create an epidural space)
 Subdural hematoma
• Blood gathers in the space between the inner surface of the meningeal layer of the dura mater and the arachnoid
• Usually result from damage to the external cerebral veins or dural venous sinuses

37
Q

o supratentorial and infratentorial regions of subarachnoid space

A

 connected by the narrow gap between the midbrain and the border of the tentorial incisures
 this region can get obstructed leading to ventricular dilation

38
Q

o tentorial incisura

A

 AKA tentorial notch
 U shaped hole in the tentorium cerebelli
 Expansion of the cerebelli can cause the medial portion of the temporal lobes to herniate through the tentorial notch
• The midbrain can get displaced laterally and get injured by the firm edge of the tentorium cerebelli

39
Q

o nerve supply of the dura mater and headaches/referral patterns

A

 the dura mater has a rich nerve supply and is sensitive to paint
 Headaches result from stimulation of the dura mater nerve supply
 Referral patterns
• Problems in the anterior cranial fossa refers to :
o Structures innervated by ophthalmic division of CN V:
 Forehead
 Temples
 Eyes
• Problems in the middle cranial fossa refers to:
o Structures innervated by the maxillary and mandibular division of CN V:
 Cheeks
 Jaw
 Mouth
• Problems in the posterior cranial fossa refer to:
o Structures innervated by the vagus and cervical nerves:
 Neck
 Region behind the ear

40
Q

o Hydrocephalus

A

 AKA water on the brain
 Occurs with the obstruction of CSF pathways
 CSF cannot be recycled back into the blood properly so it builds up in the ventricular system
 Causes
• Ventricular dilation
• Results in pressure on and often damage to brain tissues
 In children where the skull has not completely developed, the skull can expand
 Communicating hydrocephalus
• Occurs when the flow of CSF is NOT obstructed
• CSF is either
o over-produced (papilloma)
o cannot reenter the blood (i.e. blockage of arachnoid villi)
 Noncommunicating hydrocephalus
• Occurs when there is a blockage of CSF flow either
o within the ventricular system where the ventricles communicate with the subarachnoid space
o within the subarachnoid space (i.e. at the tentorial notch)