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== Overview of the Nervous System  ==
== Overview ==
[[Image:Nervous System.jpg|Nervous System|frameless|781x781px|center]]The nervous system is made up of vast neural networks; signalling within these circuits enables thinking, language, feeling, learning, memory, and all function and sensation.  It is well-established that through plasticity of existing cells our nervous systems can adapt to situations not previously encountered, but it also has been shown that cells (NSCs) are [[Neuroplasticity|plastic]] and involved in creating new connections in adaptation and response to injury.<ref name=":0">Parker E. Ludwig; [https://www.ncbi.nlm.nih.gov/books/NBK442010/ Matthew Varacallo Neuroanatomy, Central Nervous System (CNS)] Feb 2019 Available from:
[[File:Brain .png.jpeg|right|frameless]]
☀https://www.ncbi.nlm.nih.gov/books/NBK442010/ (last accessed 4.1.2020)
The nervous system is made up of vast neural networks; signalling within these circuits enables thinking, language, feeling, learning, memory, and all function and sensation.  It is well-established that through [[Neuroplasticity|plasticity]] of existing cells our nervous systems can adapt to situations not previously encountered, but it also has been shown that neural stem cells are plastic and involved in creating new connections in adaptation and response to injury.<ref name=":0">Parker E. Ludwig; [https://www.ncbi.nlm.nih.gov/books/NBK442010/ Matthew Varacallo Neuroanatomy, Central Nervous System (CNS)] Feb 2019.
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The Nervous System has three specific functions:  
The Nervous System has three specific functions:
# '''Sensory Input''' - [[Sensation|Sensory receptors]] present in the skin and organs respond to external &amp; internal stimuli by generating [[Introduction to Neurophysiology|nerve impulses]] that to the central nervous system  
#'''Sensory Input''' - [[Sensation|Sensory receptors]] present in the [[skin]] and organs respond to external &amp; internal stimuli by generating [[Introduction to Neurophysiology|nerve impulses]] that to the central nervous system
# '''Integration''' -&nbsp;The [[Brain Anatomy|brain]] and [[Spinal cord anatomy|spinal cord]] of the Central Nervous System combine and sum up all the data received from the body and send out nerve impulses.  
#'''Integration''' -&nbsp;The [[Brain Anatomy|brain]] and [[Spinal cord anatomy|spinal cord]] of the Central Nervous System combine and sum up all the data received from the body and send out nerve impulses.
# '''Motor Output''' &nbsp;- The nerve impulses from the Central Nervous System go to the effectors ([[Muscle|muscles]] and glands). Muscle contractions and gland&nbsp;secretions are responses to stimuli received by sensory receptors.  
#'''Motor Output''' &nbsp;- The nerve impulses from the Central Nervous System go to the effectors ([[Muscle|muscles]] and [[Hormones|glands]]). Muscle contractions and gland&nbsp;secretions are responses to stimuli received by sensory receptors.
The Nervous System is divided into two main divisions.<ref name="Barker">Barker; Barasi; Neal. Neuroscience at a glance; Blackwell science Ltd; 1999</ref>&nbsp;
The Nervous System is divided into two main divisions.<ref name="Barker">Thau L, Reddy V, Singh P. Anatomy, Central Nervous System. StatPearls Publishing; 2024 Jan-. Available [[from: https://www.ncbi.nlm.nih.gov/books/NBK542179/]]</ref>&nbsp;
# Central Nervous System (CNS)
# Central Nervous System (CNS)
# Peripheral Nervous System (PNS)
# Peripheral Nervous System (PNS)
 
[[Image:Nervous System.jpg|Nervous System|frameless|781x781px|center]]
== Central Nervous System ==
== Central Nervous System (CNS) ==
 
[[File:Spinal canal.png|thumb|Spinal cord and brain sit in respective cavities]]
The CNS 2 parts
The CNS two parts: Brain; Spinal Cord
# [[Brain Anatomy|Brain]]  
# [[Brain Anatomy|Brain]]  
The Brain is divided into four main parts<ref name=":0" />:  
The Brain is divided into four main parts<ref name=":0" />:  
* [[Brainstem|Brain stem]], consisting of the medulla, pons, and midbrain  
* [[Brainstem|Brain stem]], consisting of the medulla, pons, and midbrain  
* [[Cerebellum]]  
* [[Cerebellum]]  
* Diencephalon, with the thalamus and hypothalamus  
* Diencephalon, with the [[thalamus]] and [[hypothalamus]]
* Cerebral hemispheres (comprised of the cerebral cortex, [[Basal Ganglia|basal ganglia]], white matter, hippocampi and amygdalae). The right and left hemisphere are connected by the corpus callosum which facilitates communication between both sides of the brain. The Hemispheres are then further divided into four lobes.  
* [[Cerebrum|Cerebral hemispheres]] (comprised of the [[Cerebral Cortex|cerebral cortex]], [[Basal Ganglia|basal ganglia]], white matter, [[Hippocampus|hippocampi]] and [[Amygdala|amygdalae]]). The right and left hemisphere are connected by the [[Corpus Callosum|corpus callosum]] which facilitates communication between both sides of the brain. The Hemispheres are then further divided into four lobes.
2. The [[Spinal Injury|Spinal Cord]] (the caudal extension of the CNS).
2. The [[Spinal Injury|Spinal Cord]] (the caudal extension of the CNS).


Clinical Significance
== Neurons and Glial Cells ==
[[Image:Neuron.png|right|frameless|306x306px]][[Neurone|Neurones]] are cells of the nervous system, located within the [[Grey and White Matter|grey matter,]]<ref>Mercadante AA, Tadi P. Neuroanatomy, Gray Matter. StatPearls Publishing; 2024 Jan-. Available from: https://www.ncbi.nlm.nih.gov/books/NBK553239/</ref> and responsible for all neurological functions of the brain<ref>Ludwig PE, Reddy V, Varacallo M. Neuroanatomy, Neurons. StatPearls Publishing; 2024 Jan-. Available [[from: https://www.ncbi.nlm.nih.gov/books/NBK441977/]]</ref>.


Many neurological conditions affect the CNS. They range dramatically in scope, impact, and nature of the effect. Some conditions lead to progressively impaired movement eg [[Parkinson's|Parkinson disease]]. [[Huntington Disease|Huntington chorea]]. The demyelination in [[MS Multiple Sclerosis|multiple sclerosis]] can cause acute attacks, and over time, chronic degradation of function. Others may impact cognition such as the various [[Dementia|dementias]]. Epilepsy can cause uncontrolled excitation. [[Headache|Headaches]] often impair the daily function of patients. Traumatic injuries can cause [[Paraplegia|plegia or paresis]] and may result a wide range of deficits depending on the location and extent of the lesion<ref name=":0" />.
They are any of the impulse-conducting cells that constitute the brain, spinal column, and nerves in vertebrates, consisting of a nucleated cell body with one or more dendrites and a single [[Axons|axon]]. See [[Neurone]] link for more detailed information.


=== [[Cerebral Cortex]] ===
Neurones can be classified structurally and functionally:
[[File:Brain function related to anatomy.jpg|right|frameless|500x500px]]
The cerebrum consists of two cerebral hemispheres, the right and left hemisphere are connected by the corpus callosum which facilitates communication between both sides of the brain, with each hemisphere in the main connection to the contralateral side of the body i.e. the left hemisphere of the cerebrum receives information from the right side of the body resulting in motor control of the right side of the body and vice versa. 


The hemispheres are then further divided into four lobes;
Structurally:


#Occipital
* Bipolar neurones, which have one axon and one dendrite extending from the cell body.
#Parietal
* Multipolar neurones, which have one axon and multiple dendrites extending from the cell body.
#Temporal (medial part of which are a series of structures including the Hippocampus)
* Anaxonic neurones, which have no identifiable axon that can be distinguished from the dendrites.
#[[Frontal Lobe Brain Injury|Frontal]]
* Pseudounipolar neurones, which have a single axon that splits into two branches. The branches cover both functions of sending and receiving signals.


The outer layer of the cerebral hemisphere is termed the cerebral cortex. This is inter-connected via pathways that run sub-cortically. It is these connections as well as the connections from the cerebral cortex to the brainstem, spinal cord and [[Basal Ganglia|nuclei deep]] within the cerebral hemisphere that form the '''white matter of the cerebral hemisphere.&nbsp;'''The deep nuclei include structures such as the[[Basal Ganglia|&nbsp;'''basal ganglia''']] '''and the thalamus.'''
Functionally, neurons are broadly split into
== Meninges ==
The CNS is enclosed within the [[Bones of the skull|skull]] and vertebral column. These structures are separated by a series of membranes known as the Meninges. The '''Pia Mater''' is separated from the delicate '''arachnoid membrane''' by the '''subarachnoid space''', which is then in turn separated from the '''Dura mater '''by the '''Sub-dural space'''.


{{#ev:youtube|mGxomKWfJXs|400}}<ref>khanacademymedicine. Cerebral cortex. Available from: http://www.youtube.com/watch?v=mGxomKWfJXs [last accessed 19/10/2019] </ref>
* Sensory neurones, which respond to sensory inputs from the environment.
* Motor neurones, which send signals to muscles to control movement.
* interneurones, which enable communication between sensory and motor neurones.


== [[Neurone|Neurons]]  ==
=== Neuroglial Cells ===
[[Image:Neuron.png|right|frameless|306x306px]]The '''cell body''' contains the nucleus and surrounding cytoplasm. It is the focus of the cells metabolic processes, housing the mitochondria, golgi apparatus and peroxisomes.
[[File:Glia.png|right|frameless]]
*The&nbsp;'''Dendrites'''&nbsp;are neuronal processes that taper from the cell body outwards. They produce many branches and transmit information towards the cell body from synapses on the dendritic tree. their primary role is to increase the surface area for synapse formation, allowing a great number of synapses to integrate together.
Although there are about 86-100 billion neurones in the brain, there are about the same number of glial cells in the brain. Glial cells<ref>Xu S, Lu J, Shao A, Zhang JH, Zhang J. Glial cells: role of the immune response in ischemic stroke. Frontiers in immunology. 2020 Feb 26;11:502688.</ref>, or neuroglia, are cells that surround the neurones of the central nervous system embedded between them, providing both structural and physiological support.
*There is only one '''Axon''' per neuron. originates at the axon hillock conducting information away from the cell body towards the nerve terminal and synapses. It can however, branch to produce several processes. The initial segment of the axon, as it emerges from the cell body, is the most excitable part of the neuron because it has a high density of sodium channels at this point. Therefore, it is at this point that the action potential is generated.  
*A Lipid bilayer ('''cell''' '''membrane''') encloses the neuron. It is within this membrane that proteins are located. Some of these form ion channels, others form receptors to certain chemicals that are released by neurons. Others act as ion pumps, moving ions across the membrane. e.g Na+ - K+ exchange pump.
*The Axolemma is the axonal surface membrane while the axoplasm is contained within it.
*Many axons are surrounded by a '''Myelin sheath'''. This alters the conducting properties of the axon, allowing for fast action potential propagation, while the strength of the signal is maintained. This is able to happen due to the gaps in the sheath called the '''Nodes of Ranvier '''which contain many ion channels. The myelin sheath surrounds the axon from the origin near the cell body along the length of the axon to the terminal, before the axon branches.
*The myelin sheath is formed by '''Schwann cells''' in the PNS and '''Oligodendrocytes''' in the CNS.
*The '''synapse''' is the junction where the neuron meets another cell. in the CNS this will be another neuron. however in the PNS this may be a muscle cell, glandular cell or other organs. The physiology of synapses will be dealt with on the Physiopedia page Introduction to Neuro-physiology.


== [[Glial Cells|Neuroglial]] Cells  ==
There are four main classes of [[Glial Cells|neuroglial cells]] within the CNS.


There are four main classes of neuroglial cells ''within the CNS.''
#Astrocytes.
 
#Oligodendrocytes
#Astrocytes: Small stellate cells. Found throughout CNS. Form structural and supporting framework for neuronal cells and capillaries. They maintain integrity of blood brain barrier (BBB). They store and release some [[neurotransmitters]]. Disperse excess ions. Important role in development of NS and may have a role in injury recovery. May have a role in presenting antigen to the immune system when CNS and BBB damaged.  
#Ependymal cells
#Oligodendrocytes: Responsible for myelination of CNS neurons. Large numbers in the white matter. Each Olig. forms myelin for 3-50 fibres, and many others surround fibres without forming sheaths. Clinical disorders of these cells cause central demyelination in conditions such as [[Multiple Sclerosis|multiple sclerosis]].
#Microglial Cells
#Ependymal cells: Important for enabling movement of cerebrospinal fluid (CSF) as well as interacting with with Astrocytes to form a barrier separating the ventricles and CSF from neuronal environment. They line the central canal in the spinal cord.
#Microglial Cells: found throughout white and grey matter of the CNS. They are phagocytic in nature. Mediate immune responses within the CNS.


And&nbsp;''in the PNS'':  
And&nbsp;''in the PNS'':  
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#Schwann Cell: Found only in the PNS. Responsible for the myelination of the peripheral nerves by wrapping the cell around the axon. There are multiple layers of scwann cell membrane wrapped around the nerve. One schwann cell wraps around one axon and provides myelin for one internode. They are important for regeneration of damaged peripheral axons.
#Schwann Cell: Found only in the PNS. Responsible for the myelination of the peripheral nerves by wrapping the cell around the axon. There are multiple layers of scwann cell membrane wrapped around the nerve. One schwann cell wraps around one axon and provides myelin for one internode. They are important for regeneration of damaged peripheral axons.


== [[Basal Ganglia]]  ==
=== Cerebrum ===
See link
[[File:Brain function related to anatomy.jpg|right|frameless|500x500px]]
The [[cerebrum]] consists of two cerebral hemispheres, the right and left hemisphere are connected by the [[Corpus Callosum|corpus callosum]] which facilitates communication between both sides of the brain, with each hemisphere in the main connection to the contralateral side of the body i.e. the left hemisphere of the cerebrum receives information from the right side of the body resulting in motor control of the right side of the body and vice versa.  


== The [[Hypothalamus]]  ==
The hemispheres are then further divided into four lobes;


The hypothalamus lies on either side of the 3rd ventricle, below the [[thalamus]] and between the optic chiasm and the midbrain. It receives a large input from limbic structures. It has a significantly large efferent output to the ANS and has a highly significant role in the control of pituitary endocrine function.
#[[Occipital Lobe|Occipital]]
#[[Parietal Lobe|Parietal]]
#[[Temporal Lobe|Temporal]] (medial part of which are a series of structures including the [[Hippocampus]])
#[[Frontal Lobe Brain Injury|Frontal]]


The hypothalamus as well as inputting the ANS also has a large part to play in the homeostasis of many physiological systems such as hunger, thirst, water and sodium balance and temperature regulation. it also plays a role in memory and emotional responses, providing autonomic and endocrine responses.  
== Cerebral Cortex ==
The outer layer of the cerebral hemisphere is termed the [[Cerebral Cortex|cerebral cortex]]. This is inter-connected via pathways that run sub-cortically. It is these connections as well as the connections from the cerebral cortex to the brainstem, spinal cord and [[Basal Ganglia|nuclei deep]] within the cerebral hemisphere that form the [[Grey and White Matter|white matter]] of the cerebral hemisphere.&nbsp;The deep nuclei include structures such as the[[Basal Ganglia|&nbsp;basal ganglia]] and the [[thalamus]].
== Basal Ganglia ==
The “[[Basal Ganglia|basal ganglia]]” refers to a group of subcortical nuclei within the brain responsible primarily for motor control, as well as other roles such as motor learning, executive functions, emotional behaviours, and play an important role in reward and reinforcement, addictive behaviours and habit formation.


It also plays a role in the control of circadian rhythms via retinal input to suprachiasmatic nucleus. There may also be hypothalamus input into sexual and emotional behaviour independent of its endocrine role.  
== The Hypothalamus ==
[[File:Hypothalamus.gif|thumb|200x200px|Hypothalamus]]
The [[hypothalamus]] is an organ central to many autonomous functions of the human body, notably the regulation of homeostasis. It has a significantly large efferent output to the ANS and has a highly significant role in the control of pituitary endocrine function.


{{#ev:youtube|TVhm2rBGhB0|400}}<ref>Neuroscientifically Challenged. 2-Minute Neuroscience: Hypothalamus &amp; Pituitary Gland. Available from: http://www.youtube.com/watch?v=TVhm2rBGhB0 [last accessed 19/10/2019] </ref>
The hypothalamus lies on either side of the 3rd ventricle, below the [[thalamus]] and between the optic chiasm and the midbrain. It receives a large input from limbic structures. See link for detailed description.
== Meninges ==
The CNS is enclosed within the [[Bones of the skull|skull]] and vertebral column. These structures are separated by a series of membranes known as the [[Meninges]]<ref>Sehgal I, M Das J. Anatomy, Back, Spinal Meninges. StatPearls Publishing; 2024 Jan-. Available from: https://www.ncbi.nlm.nih.gov/books/NBK547755/</ref>. The pia Mater is separated from the delicate arachnoid membrane by the subarachnoid space, which is then in turn separated from the dura mater by the sub-dural space.


== [[Limbic System]] ==
* The outermost layer is the dura mater. It is composed of 2 fused layers: the outer layer that is directly attached to the skull is the periosteal layer and the inner layer is the meningeal layer. Only the meningeal layer continues down to surround the spinal cord. As the spinal dura mater is not directly attached to the vertebrae, there is an epidural space in the spine.  In the cranial dura mater, there are a few places where the meningeal layer separates from the periosteal layer and folds down into the cranial cavity to create dural reflections. The falx cerebri runs in the longitudinal fissure to separate the left and right hemispheres of the cerebrum. The other main dural reflection is the tentorium cerebelli, which separates the occipital and temporal lobes of the cerebrum from the cerebellum and brainstem.
This refers to a number of areas within the brain lying mainly on the medial side of the temporal lobe. It includes a number of structures as seen in the diagram.  
* The middle layer of the meninges is the arachnoid mater, a spider web-like layer closely attached to the meningeal layer of the dura mater. Arachnoid granulations which protrude into the dura mater allow drainage of cerebrospinal fluid into the systemic venous system.
* The innermost layer is the pia mater. It lies right along the surface of the brain, following the ridges and grooves like tightly adhered plastic wrap. It also forms sheaths around blood vessels as they enter the brain.
 
== Limbic System ==
The [[Limbic System|limbic system]] refers to a number of areas within the brain lying mainly on the medial side of the temporal lobe. It includes a number of structures as seen in the diagram.  


[[Image:Limbic2.jpg|right|frameless|450x450px]]
[[Image:Limbic2.jpg|right|frameless|450x450px]]
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* Long term potentiation (LTP) is the increase in the strength of a synaptic transmission with repetitive use, it can be seen to be effected in the hippocampus (primarily is involved with memory) and is thought to be important for memory acquisition.   
* Long term potentiation (LTP) is the increase in the strength of a synaptic transmission with repetitive use, it can be seen to be effected in the hippocampus (primarily is involved with memory) and is thought to be important for memory acquisition.   


=== [[Brainstem]] ===
=== Brainstem ===
[[File:Brainstem rotating.gif|thumb|200x200px|Brainstem red]]
The [[Brainstem]] lies at the base of the brain and the top of the spinal cord. It is the structure that connects the cerebrum of the brain to the spinal cord and cerebellum. It is composed of 3 sections in descending order: the midbrain, pons, and medulla oblongata. It is responsible for many vital functions of life, such as breathing, consciousness, blood pressure, heart rate, and sleep.  
 
See link
See link


== CNS Blood Supply  ==
== CNS Blood Supply  ==
# [[File:Circle of Willis en.svg.png|right|frameless]]Arterial blood supply to the brain comes from four vessels;  
[[File:Circle of Willis en.svg.png|alt=|thumb|Circle of Willis]]The CNS vasculature provides the nutrients necessary for the correct functioning of the central nervous system (CNS)<ref>Weerasuriya, A., Mizisin, A.P. The Blood-Nerve Barrier: Structure and Functional Significance. In: Nag, S. (eds) The Blood-Brain and Other Neural Barriers. Methods in Molecular Biology, 2011. vol 686. Humana Press. </ref>.
 
'''Brain''': Arterial blood supply to the brain comes from four vessels;
*Right and Left [[Internal Carotid Artery|Internal Carotid&nbsp;]]  
*Right and Left [[Internal Carotid Artery|Internal Carotid&nbsp;]]  
*Right and Left [[Vertebral Artery|Vertebral Arteries]]
*Right and Left [[Vertebral Artery|Vertebral Arteries]]


'''Basilar Artery''':
The internal carotid arteries branch to form two major cerebral arteries, the anterior and middle cerebral arteries. The right and left vertebral arteries come together at the level of the pons on the ventral surface of the brainstem to form the midline basilar artery. 


This has a number of branches: anterior and inferior cerebellar artery, artery to the labyrinth, pontine branches and superior cerebellar artery.  
Circle of Willis: The basilar artery joins the blood supply from the internal carotids in an arterial ring at the base of the brain (in the vicinity of the hypothalamus and cerebral peduncles) called the circle of Willis. The posterior cerebral arteries arise at this confluence, as do two small bridging arteries, the anterior and posterior communicating arteries. Conjoining the two major sources of cerebral vascular supply via the circle of Willis presumably improves the chances of any region of the brain continuing to receive blood if one of the major arteries becomes occluded<ref>Purves D, Augustine GJ, Fitzpatrick D, Katz LC, LaMantia AS, McNamara JO, Williams S. The blood supply of the brain and spinal cord. Neuroscience. 2001;2.Available: https://www.ncbi.nlm.nih.gov/books/NBK11042/<nowiki/>(accessed 6.5.2022)</ref>.  


'''Posterior Cerebral Arteries''':  
'''Spinal Cord''': The [[Spinal cord anatomy|spinal cord]] is supplied by a single anterior spinal artery and paired posterior spinal arteries. Anterior spinal artery: arises from the vertebral arteries and extends from the level of the lower brainstem to the tip of the conus medullaris. It supplies the ventral medial surface of the medulla and anterior 2/3 of the spinal cord. The posterior spinal arteries supply the dorsal 1/3 of the cord. There are reinforcing branches from other arteries along the length of the cord.


These supply blood to the posterior parietal cortex, occipital lobe and inferior temporal lobe. There are several branches of this artery that supply the midbrain, thalamus, subthalamus, posterior internal capsule, optic radiation and cerebral peduncle.  
If occlusion occurs, it is normally of the anterior spinal artery, producing loss of power and spinothalamic sensory deficit, but dorsal column sensory capabilities are maintained.


{| width="100%" cellspacing="1" cellpadding="1"
'''Venous Drainage'''
|-
[[File:Brain Sinuses.jpeg|right|frameless]]
| {{#ev:youtube|hfG8J_X1D5Q|350}}<ref>khanacademymedicine. Cerebral blood supply - Part 1. Available from: http://www.youtube.com/watch?v=hfG8J_X1D5Q [last accessed 19/10/2019] </ref>  
The cerebrum, cerebellum and brainstem are drained by numerous veins, which empty into the dural venous sinuses<ref>Bayot ML, Reddy V, Zabel MK. Neuroanatomy, Dural Venous Sinuses. StatPearls Publishing; 2024 Jan-. Available from: https://www.ncbi.nlm.nih.gov/books/NBK482257/</ref>. The spinal cord is supplied by anterior and posterior spinal veins, which drain into the internal and external vertebral plexuses .  
| {{#ev:youtube|kVulo3qDcUo|350}}<ref>khanacademymedicine. Cerebral blood supply - Part 2. Available from: http://www.youtube.com/watch?v=kVulo3qDcUo [last accessed 19/10/2019] </ref>
|}


'''Venous Drainage'''
If occlusion of either of these venous systems then raised intracranial pressure can develop.


Venous drainage of the brainstem and cerebellum is straight into the dural venous sinuses which are adjacent to the posterior cranial fossa.  
== The Cerebellum ==
[[File:Cerebellum gif.gif|alt=|thumb|150x150px|Cerebellum]]The [[cerebellum]]<ref>Kebschull JM, Casoni F, Consalez GG, Goldowitz D, Hawkes R, Ruigrok TJ, Schilling K, Wingate R, Wu J, Yeung J, Uusisaari MY. Cerebellum lecture: the cerebellar nuclei—core of the cerebellum. The Cerebellum. 2023 Feb 13:1-58.


The cerebral hemispheres have external and internal veins.  
</ref> is a vital component in the human brain as it plays a role in motor movement regulation and balance control. The cerebellum is neuron-rich, containing 80% of the brain’s neurons organized in a dense cellular layer, and it's surface area when unfolded is nearly 75% of the surface area of the cerebrum.


*External veins drain the cortex and drain into the transverse sinus. This then drains into the lateral sinus and empties into the internal jugular vein.  
== Spinal Cord ==
*Internal cerebral veins drain the deep structures of the cerebral hemisphere into the great vein of Galen, and then into the sinus.
The [[Spinal cord anatomy|spinal cord]]<ref>Bess S, Line B. Embryology and anatomy: spine/spinal cord. InThe Growing Spine: Management of Spinal Disorders in Young Children 2022 Feb 3 (pp. 3-12). Cham: Springer International Publishing.


If occlusion of either of these venous systems then raised intracranial pressure can develop.  
</ref> is part of the central nervous system and consists of a tightly packed column of nerve tissue that extends downwards from the brainstem through the central column of the spine. It is a relatively small bundle of tissue (weighing 35g and just about 1cm in diameter) but is crucial in facilitating our daily activities.  


'''Blood Supply to the Spinal Cord'''
The spinal cord carries nerve signals from the brain to other parts of the body (importantly the muscles we use to move) and receives sensory input from the body, partially processes it, and then transmits that information to the brain.
* The spinal cord is supplied by a single anterior spinal artery and paired posterior spinal arteries.
* Anterior spinal artery: arises from the vertebral arteries and extends from the level of the lower brainstem to the tip of the conus medullaris.
* It supplies the ventral medial surface of the medulla and anterior 2/3 of the spinal cord.
* The posterior spinal arteries supply the dorsal 1/3 of the cord.
* There are reinforcing branches from other arteries along the length of the cord.
* If occlusion occurs, it is normally of the anterior spinal artery, producing loss of power and spinothalamic sensory deficit, but dorsal column sensory capabilities are maintained.


== [[Cerebellum|The Cerebellum]].   ==
[[Spinal Nerves|Spinal nerves]] contain both motor and sensory nerve fibres, so they are considered mixed nerves. The cell bodies of the sensory neurons are housed in an enlargement called the dorsal root ganglion. Structurally, these sensory neurons are pseudounipolar. The cell bodies of the motor neurons are housed in the grey matter of the spinal cord, specifically the anterior horn. The sensory neurons communicate with the motor neurons at each level through interneurons.
[[File:Cerebellum gif.gif|right|frameless]]
See link


== [[Spinal cord anatomy|Spinal Cord]] ==
The dorsal root of each spinal cord segment is responsible for innervating specific corresponding areas of skin that can be mapped onto the surface of the body, termed dermatomes. Similarly, [[myotomes]] are groups of muscles that are innervated by a single ventral nerve root. [[Dermatomes]] and myotomes allow for clinical assessment of specific nerve root injuries or the level of a spinal cord injury.
[[File:Nervous system diagram.png|right|frameless|660x660px]]
See link 
== Peripheral Nervous System  ==


The PNS consists of nerve trunks that are formed from both afferent axons which conduct sensory information to the spinal cord, and efferent fibres which transmit impulses primarily to muscles. If a particular nerve is damaged, there is resulting weakness to the muscle it supplies as well as sensory loss from the region it conveys information from.
Spinal nerves C7 and above exit the vertebral column above their corresponding vertebrae. Spinal nerve C8 exits between the C7 and T1 vertebrae, and the rest of the spinal nerves exit below their corresponding vertebrae. Because the spinal cord is shorter than the vertebral column and ends at around the L1 or L2 vertebra, the spinal nerve roots below that level have to descend past the end of the spinal cord in the vertebral column before exiting below their corresponding vertebrae. This forms a bundle of spinal nerve roots below the spinal cord termed the [[Cauda Equina|cauda equina]].  


<br>The peripheral nerves connect with the spinal cord through foramina in the vertebra of the spine or with the brain through foramina in the skull.
After the spinal nerves exit the vertebral column they split up into dorsal and ventral rami. Dorsal rami innervate the skin and muscles of the back, while the ventral rami innervate the skin and muscles of the ventral and lateral trunk and extremities.  


=== Autonomic Nervous System  ===
In areas other than the thoracic, the ventral rami intermingle with each other to form networks called nerve plexuses. These eventually give rise to peripheral nerves that provide sensorimotor innervation to the body.


The main role of the ANS is to innervate the internal and glandular organs. Functions of the ANS include the regulation of “circulation, respiration, metabolism, secretion, body temperature, and reproduction.The peripheral component is defined in terms of the sympathetic, and parasympathetic systems. Efferent fibres of the ANS originate from the intermediate zone (lateral column) of the spinal cord or specific cranial nerve and sacral nuclei before synapsing in a ganglion. These are different for sympathetic or parasympathetic systems. Afferent fibres from the organs innervated by the ANS travel via the dorsal root to the spinal cord.<br>
== Peripheral Nervous System (PNS) ==
[[File:Autonomic and Somatic Nervous System.png|right|frameless|527x527px]]
The peripheral nervous system<ref name=":1">Murtazina A, Adameyko I. The peripheral nervous system. Development. 2023 May 1;150(9):dev201164.</ref> includes the nerves and [[Ganglion|ganglia]] that are outside of the central nervous system.  The peripheral nervous system is made up of two divisions: the somatic nervous system and the autonomic system. Each part of this system plays a vital role in how information is communicated throughout the body.  


The ANS includes nerve cells and fibres which innervate internal and glandular organs.There are always two successive neurons; preganglionic with cell body in the CNS and postganglionic.  
==== Neuromuscular Junction ====
Peripheral motor nerves<ref name=":1" /> consist of a neuromuscular junction, which is the synaptic connection between the motor neuron and the muscle. Information in the form of electrical impulses reach the presynaptic membrane at the end of an axon and trigger the release of neurotransmitters. In skeletal muscles, the neurotransmitter [[acetylcholine]] is often used. The neurotransmitters then cross the gap between the motor neuron and the motor end plate on the muscle, a space termed the synaptic cleft. The motor end plate contains receptors which then receive the neurotransmitters, and this signal is then translated into muscle action.


The&nbsp;ANS is divided into two Divisions:<br>
=== Autonomic Nervous System (ANS) ===


==== Sympathetic ====
The [[Autonomic Nervous System|autonomic system]]<ref>Jänig W. The integrative action of the autonomic nervous system: neurobiology of homeostasis. Cambridge University Press; 2022 Aug 4.</ref> is the part of the peripheral nervous system that's responsible for regulating involuntary body functions. Functions of the ANS include the regulation of “circulation, respiration, metabolism, secretion, body temperature, and reproduction.” 
Preganglionic neurons found in lateral horn of spinal cord from upper thoracic to mid-lumbar cord (T1-L3). Postganglionic cell bodies found in vertebral and prevertebral ganglia. Uses Noradrenalin as postganglionic transmitter.  


==== [[Parasympathetic System|Parasympathetic]] ====
The&nbsp;ANS is divided into two Divisions:
Preganglionic neurons have cell bodies in the brainstem and sacrum. Postganglionic cell bodies are found adjacent to or within the walls of the organ they supply. Uses acetylcholine (Ach) as postganglionic transmitter.


Both Parasympathetic and Sympathetic&nbsp;systems use Ach at the level of the ganglia.<br>
#[[Sympathetic Nervous System|Sympathetic]]: Preganglionic neurons found in lateral horn of spinal cord from upper thoracic to mid-lumbar cord (T1-L3). Postganglionic cell bodies found in vertebral and prevertebral ganglia. Uses Noradrenalin as postganglionic transmitter.
#[[Parasympathetic System|Parasympathetic]]: Preganglionic neurons have cell bodies in the brainstem and sacrum. Postganglionic cell bodies are found adjacent to or within the walls of the organ they supply. Uses [[acetylcholine]] (ACh) as postganglionic transmitter.
=== Somatic Nervous System ===
[[File:Nervous system diagram.png|right|frameless|660x660px]]


=== Somatic Nervous System ===
The somatic system<ref name=":2">Michael-Titus AT, Shortland P. The Nervous System: The Nervous System, E-Book. Elsevier Health Sciences; 2022 Jun 11.</ref> is the part of the peripheral nervous system responsible for carrying sensory and motor information to and from the central nervous system. The somatic nervous system derives its name from the Greek word soma, which means "body."


The Somatic Nervous System (SNS) is made up of nerves that are connected to skin, muscles and sensory organs (the eyes, ears, nose, skin, etc.). The SNS or voluntary nervous system is concerned with reactions to external stimulation. This system is under conscious control and is responsible for skeletal muscle contraction by way of the 31 pairs of spinal nerves. This system enables our voluntary control of muscles, as well as our reception of sights, sounds, sensations, tastes and smells.  
[[Cranial Nerves|Cranial]] and [[Spinal Nerves|spinal nerves]] contribute to the somatic nervous system. Cranial nerves provide voluntary motor control and sensation to the head and face. Spinal nerves supply the trunk and limbs. The posterior rami travel backwards to supply the vertebral column, vertebral muscles and skin of the back whilst the anterior rami supply the limbs and anterior trunk. The majority of anterior rami combine to form nerve plexuses from which many major peripheral nerves stem. The exception to this is the anterior rami of the thoracic region which travel relatively independently from one another without forming plexuses, as the intercostal and subcostal nerves of the trunk.  


{| width="100%" cellspacing="1" cellpadding="1"
Nervous plexuses are as follows:  
|-
| {{#ev:youtube|jA1NyCE4M2g|350}}<ref>khanacademymedicine. Autonomic Nervous System. Available from: http://www.youtube.com/watch?v=TVhm2rBGhB0 [last accessed 19/10/2019] </ref>
| {{#ev:youtube|ye28W_OygOw|350}}<ref>khanacademymedicine. Autonomic vs somatic nervous system. Available from: http://www.youtube.com/watch?v=TVhm2rBGhB0 [last accessed 19/10/2019] </ref>
|}


* C1-C4 form the [[Cervical Plexus|cervical plexus]]
* C5-T1 combine into the [[Brachial Plexus|brachial plexus]]
* T12-L4 form the [[Lumbar Plexus|lumbar plexus]]
* L4 - S4 combine into the [[Sacral Plexus|sacral plexus]]
=== Sensory Systems ===
=== Sensory Systems ===
[[Image:Sensory system.jpg|500px|right]]The sensory system is where information is transmitted to the spinal cord and brain from peripheral sensory receptors. These are specialised neurons or nerve endings.  
[[Image:Sensory system.jpg|500px|right]]The sensory nervous system<ref name=":2" /> is a part of the nervous system responsible for processing sensory information being where information is transmitted to the spinal cord and brain from peripheral sensory receptors. The sensory receptors are specialised neurons or nerve endings. For more see [[Sensation]]


The sensory receptor, afferent axon and cell body are known as the '''primary afferent'''. The process by which the signals are transmitted through this system is known as '''sensory transduction'''. The signal produced is sent to the CNS via peripheral or cranial nerves via several synapses, eventually terminating in the cortex where it is analysed.
There are five main sensory systems in mammals.  
 
'''There are five main sensory systems in mammals'''.  


#touch/pressure  
#touch/pressure  
Line 185: Line 186:
#taste  
#taste  
#smell/olfaction
#smell/olfaction
=== Pain Systems ===
[[File:Pain experience.png|right|frameless|pain]]
[[Pain Behaviours|Pain]] is defined as an unpleasant sensory or emotional experience, associated with potential or actual tissue damage. Nociception defines the processing of information about damaging stimuli by the nervous system up to the level of the cortex. Potentially damaging mechanical, thermal, and chemical stimuli are detected by nerve endings called nociceptors, which are found in the skin, on internal surfaces such as the periosteum, joint surfaces, and in some internal organs. 


==== Sensory receptors ====
There are two types of nociceptor: ''A delta fibres'': activated by high threshold mechanoreceptors. thinly myelinated; ''Unmyelinated C-fibres'': activated by polymodal nociceptors(PMN) and respond to intense mechanical stimulation, high temperatures and irritant chemicals.
A sensory receptor's adequate stimulus is the stimulus modality for which it possesses the adequate sensory transduction apparatus. Adequate stimulus can be used to classify sensory receptors:


*Baroreceptors respond to pressure in blood vessels
There are three main pathways that transmit nociceptive signals to the brain:
*Chemoreceptors respond to chemical stimuli
*Electromagnetic radiation receptors respond to electromagnetic radiation[1] Infrared receptors respond to infrared radiation
*Photoreceptors respond to visible light
*Ultraviolet receptors respond to ultraviolet radiation
*Electroreceptors respond to electric fields Ampullae of Lorenzini respond to electric fields, salinity, and to temperature, but function primarily as electroreceptors
*Hydroreceptors respond to changes in humidity
*Magnetoreceptors respond to magnetic fields
*Mechanoreceptors respond to mechanical stress or mechanical strain
*Nociceptors respond to damage, or threat of damage, to body tissues, leading (often but not always) to pain perception
*Osmoreceptors respond to the osmolarity of fluids (such as in the hypothalamus)
*Proprioceptors provide the sense of position
*Thermoreceptors respond to temperature, either heat, cold or both<br>
=== Pain Systems ===
[[Pain Behaviours|Pain]] is defined as an unpleasant sensory or emotional experience, associated with potential or actual tissue damage. Nociception defines the processing of information about damaging stimuli by the nervous system up to the level of the cortex.


Potentially damaging mechanical, thermal, and chemical stimuli are detected by nerve endings called nociceptors, which are found in the skin, on internal surfaces such as the periosteum, joint surfaces, and in some internal organs. The concentration of nociceptors varies throughout the body; they are found in greater numbers in the skin than in deep internal surfaces. The nociceptors are unspecialized free nerve endings that have their cell bodies outside the spinal column in the dorsal root ganglia. Nociceptors are categorized according to the axons which travel from the receptors to the spinal cord or brain.  
#[[Spinothalamic tract|Spinothalamic]] tract
#Spino reticular tract.  
#Spino mesencephalic


Nociceptors have a certain threshold; that is, they require a minimum intensity of stimulation before they trigger a signal. Once this threshold is reached a signal is passed along the axon of the neuron into the spinal cord.  
=== Motor Systems  ===
Motor systems are the areas of the nervous system responsible for controlling movement. Neural control of the somatic motor system involves complex feedback mechanisms between the brain, spinal cord, peripheral nerves, and musculoskeletal structures. Each component is functionally and structurally capable of adaptation and modulation to maintain as much efficiency as possible<ref>Seffinger MA, Hruby RJ. Evidence-based manual medicine: a problem-oriented approach. Elsevier Health Sciences; 2007. Available: https://www.sciencedirect.com/topics/neuroscience/somatic-motor-system (accessed 6.5.20220</ref>.  


In some conditions, excitation of pain fibers becomes greater as the pain stimulus continues, leading to a condition called hyperalgesia.  
== Grey and White Matter. ==
The central nervous system is made up of grey matter and white matter.


There are two types of nociceptor:  
# [[Grey and White Matter|Grey matter]]: named for its pinkish-gray color, is home to neural cell bodies, axon terminals, and dendrites, as well as all nerve synapses. This brain tissue is abundant in the [[cerebellum]], [[cerebrum]], and [[Brainstem|brain stem]]. It also forms a butterfly-shaped portion of the central [[Spinal cord anatomy|spinal cord]].
# [[Grey and White Matter|White matter]]: composed of bundles of [[axons]]. These axons are coated with myelin, a mixture of proteins and lipids, that helps conduct [[Neurone|nerve]] signals and protect the axons. White matter conducts, processes, and send nerve signals up and down the spinal cord<span class="reference" id="cite_ref-:0_1-0"></span>.


#''A delta fibres'': activated by high threshold mechanoreceptors. thinly myelinated.
== Viewing ==
#''Unmyelinated C-fibres'': activated by polymodal nociceptors(PMN) and respond to intense mechanical stimulation, high temperatures and irritant chemicals.


There are three main pathways that transmit nociceptive signals to the brain:  
Take a lot at these videos for further understanding.{{#ev:youtube|mGxomKWfJXs|400}}<ref>Neuroscientifically Challenged. 2-Minute Neuroscience: Hypothalamus &amp; Pituitary Gland. Available from: http://www.youtube.com/watch?v=TVhm2rBGhB0 [last accessed 19/10/2019] </ref>{{#ev:youtube|TVhm2rBGhB0|400}}{{#ev:youtube|vXb0ZvkFkS8|400}}<ref>khanacademymedicine. Motor unit. Available from: http://www.youtube.com/watch?v=vXb0ZvkFkS8 [last accessed 19/10/2019] </ref>
 
#Spinothalamic tract
#Spino reticular tract.  
#Spino mesencephalic


{{#ev:youtube|i5V_q7XqQN8|400}}<ref>UCL Centre for Anaesthesia. An Introduction to Pain Pathways and Mechanisms. Available from: http://www.youtube.com/watch?v=i5V_q7XqQN8 [last accessed 19/10/2019] </ref>
{{#ev:youtube|i5V_q7XqQN8|400}}<ref>UCL Centre for Anaesthesia. An Introduction to Pain Pathways and Mechanisms. Available from: http://www.youtube.com/watch?v=i5V_q7XqQN8 [last accessed 19/10/2019] </ref>


=== Motor Systems  ===
{| width="100%" cellspacing="1" cellpadding="1"
 
|-
[[Image:Motor paths.jpg|right|frameless]]Motor systems are the areas of the nervous system responsible for controlling movement. The movement can either be guided by input from the sensory systems (closed-loop) or triggered by a sensory cue, or an internal desire to move (open-loop). Most movements involve both types of control. Closed loop movements tend to involve the axial muscles (posture and balance) while open-loop movements involve the peripheral muscles (locomotion and fine skilled movements).<br>
|{{#ev:youtube|hfG8J_X1D5Q|350}}<ref>khanacademymedicine. Cerebral blood supply - Part 1. Available from: http://www.youtube.com/watch?v=hfG8J_X1D5Q [last accessed 19/10/2019] </ref>
# '''Level 1 -''' Highest level - concerned with initiation, planning, and programming of the movement. Response to internal desire to move (limbic system and post. parietal cortex.
|{{#ev:youtube|kVulo3qDcUo|350}}<ref>khanacademymedicine. Cerebral blood supply - Part 2. Available from: http://www.youtube.com/watch?v=kVulo3qDcUo [last accessed 19/10/2019] </ref>
# '''Level 2 -''' Cerebellum - responsible for balance and coordination of the movement.
|}
# '''Level 3 -''' Control of lower descending neurons via supraspinal descending motor pathways (corticospinal/pyramidal tract and tecto and rubrospinal, vestibulo spinal, extrapyramidal).
# '''Level 4 -''' Low level motor organisation in the spinal cord. Descending motor paths, and interneurons. Mediation of spinal cord reflexes. This is where the central pattern generators are situated.
# '''Level 5 -''' Lowest level. output neuron of the CNS to the muscle (motorneuron). Receives important input from sensory organs in the periphery - the muscle spindle and golgi tendon organ.
{{#ev:youtube|vXb0ZvkFkS8|400}}<ref>khanacademymedicine. Motor unit. Available from: http://www.youtube.com/watch?v=vXb0ZvkFkS8 [last accessed 19/10/2019] </ref>


== References  ==
== References  ==
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[[Category:Neurology]]  
[[Category:Neurology]]  
[[Category:Anatomy]]
[[Category:Anatomy]]
[[Category:Course Pages]]

Latest revision as of 23:48, 27 March 2024

Original Editor - Joanne Garvey and Naomi O'Reilly

Top Contributors - Joanne Garvey, Lucinda hampton, Naomi O'Reilly, Laura Ritchie, Kim Jackson, Kate Sampson, Rachael Lowe, Admin, Tarina van der Stockt, WikiSysop, Simisola Ajeyalemi, Adam Vallely Farrell, Rucha Gadgil, Rewan Elsayed Elkanafany, Jess Bell, Mande Jooste, Scott Buxton and George Prudden  

Overview[edit | edit source]

Brain .png.jpeg

The nervous system is made up of vast neural networks; signalling within these circuits enables thinking, language, feeling, learning, memory, and all function and sensation.  It is well-established that through plasticity of existing cells our nervous systems can adapt to situations not previously encountered, but it also has been shown that neural stem cells are plastic and involved in creating new connections in adaptation and response to injury.[1]

The Nervous System has three specific functions:

  1. Sensory Input - Sensory receptors present in the skin and organs respond to external & internal stimuli by generating nerve impulses that to the central nervous system
  2. Integration - The brain and spinal cord of the Central Nervous System combine and sum up all the data received from the body and send out nerve impulses.
  3. Motor Output  - The nerve impulses from the Central Nervous System go to the effectors (muscles and glands). Muscle contractions and gland secretions are responses to stimuli received by sensory receptors.

The Nervous System is divided into two main divisions.[2] 

  1. Central Nervous System (CNS)
  2. Peripheral Nervous System (PNS)
Nervous System

Central Nervous System (CNS)[edit | edit source]

Spinal cord and brain sit in respective cavities

The CNS two parts: Brain; Spinal Cord

  1. Brain

The Brain is divided into four main parts[1]:

2. The Spinal Cord (the caudal extension of the CNS).

Neurons and Glial Cells[edit | edit source]

Neuron.png

Neurones are cells of the nervous system, located within the grey matter,[3] and responsible for all neurological functions of the brain[4].

They are any of the impulse-conducting cells that constitute the brain, spinal column, and nerves in vertebrates, consisting of a nucleated cell body with one or more dendrites and a single axon. See Neurone link for more detailed information.

Neurones can be classified structurally and functionally:

Structurally:

  • Bipolar neurones, which have one axon and one dendrite extending from the cell body.
  • Multipolar neurones, which have one axon and multiple dendrites extending from the cell body.
  • Anaxonic neurones, which have no identifiable axon that can be distinguished from the dendrites.
  • Pseudounipolar neurones, which have a single axon that splits into two branches. The branches cover both functions of sending and receiving signals.

Functionally, neurons are broadly split into

  • Sensory neurones, which respond to sensory inputs from the environment.
  • Motor neurones, which send signals to muscles to control movement.
  • interneurones, which enable communication between sensory and motor neurones.

Neuroglial Cells[edit | edit source]

Glia.png

Although there are about 86-100 billion neurones in the brain, there are about the same number of glial cells in the brain. Glial cells[5], or neuroglia, are cells that surround the neurones of the central nervous system embedded between them, providing both structural and physiological support.

There are four main classes of neuroglial cells within the CNS.

  1. Astrocytes.
  2. Oligodendrocytes
  3. Ependymal cells
  4. Microglial Cells

And in the PNS:

  1. Schwann Cell: Found only in the PNS. Responsible for the myelination of the peripheral nerves by wrapping the cell around the axon. There are multiple layers of scwann cell membrane wrapped around the nerve. One schwann cell wraps around one axon and provides myelin for one internode. They are important for regeneration of damaged peripheral axons.

Cerebrum[edit | edit source]

Brain function related to anatomy.jpg

The cerebrum consists of two cerebral hemispheres, the right and left hemisphere are connected by the corpus callosum which facilitates communication between both sides of the brain, with each hemisphere in the main connection to the contralateral side of the body i.e. the left hemisphere of the cerebrum receives information from the right side of the body resulting in motor control of the right side of the body and vice versa.

The hemispheres are then further divided into four lobes;

  1. Occipital
  2. Parietal
  3. Temporal (medial part of which are a series of structures including the Hippocampus)
  4. Frontal

Cerebral Cortex[edit | edit source]

The outer layer of the cerebral hemisphere is termed the cerebral cortex. This is inter-connected via pathways that run sub-cortically. It is these connections as well as the connections from the cerebral cortex to the brainstem, spinal cord and nuclei deep within the cerebral hemisphere that form the white matter of the cerebral hemisphere. The deep nuclei include structures such as the basal ganglia and the thalamus.

Basal Ganglia[edit | edit source]

The “basal ganglia” refers to a group of subcortical nuclei within the brain responsible primarily for motor control, as well as other roles such as motor learning, executive functions, emotional behaviours, and play an important role in reward and reinforcement, addictive behaviours and habit formation.

The Hypothalamus[edit | edit source]

Hypothalamus

The hypothalamus is an organ central to many autonomous functions of the human body, notably the regulation of homeostasis. It has a significantly large efferent output to the ANS and has a highly significant role in the control of pituitary endocrine function.

The hypothalamus lies on either side of the 3rd ventricle, below the thalamus and between the optic chiasm and the midbrain. It receives a large input from limbic structures. See link for detailed description.

Meninges[edit | edit source]

The CNS is enclosed within the skull and vertebral column. These structures are separated by a series of membranes known as the Meninges[6]. The pia Mater is separated from the delicate arachnoid membrane by the subarachnoid space, which is then in turn separated from the dura mater by the sub-dural space.

  • The outermost layer is the dura mater. It is composed of 2 fused layers: the outer layer that is directly attached to the skull is the periosteal layer and the inner layer is the meningeal layer. Only the meningeal layer continues down to surround the spinal cord. As the spinal dura mater is not directly attached to the vertebrae, there is an epidural space in the spine. In the cranial dura mater, there are a few places where the meningeal layer separates from the periosteal layer and folds down into the cranial cavity to create dural reflections. The falx cerebri runs in the longitudinal fissure to separate the left and right hemispheres of the cerebrum. The other main dural reflection is the tentorium cerebelli, which separates the occipital and temporal lobes of the cerebrum from the cerebellum and brainstem.
  • The middle layer of the meninges is the arachnoid mater, a spider web-like layer closely attached to the meningeal layer of the dura mater. Arachnoid granulations which protrude into the dura mater allow drainage of cerebrospinal fluid into the systemic venous system.
  • The innermost layer is the pia mater. It lies right along the surface of the brain, following the ridges and grooves like tightly adhered plastic wrap. It also forms sheaths around blood vessels as they enter the brain.

Limbic System[edit | edit source]

The limbic system refers to a number of areas within the brain lying mainly on the medial side of the temporal lobe. It includes a number of structures as seen in the diagram.

Limbic2.jpg
  • The limbic system provides high level processing of sensory information. The main outflow of the limbic system is to the prefrontal cortex and the hypothalamus as well as to cortical areas. It appears to have a role in attaching behavioural significance and response to a given stimulus.
  • Damage to this area has profound effects on emotional responses.
  • Long term potentiation (LTP) is the increase in the strength of a synaptic transmission with repetitive use, it can be seen to be effected in the hippocampus (primarily is involved with memory) and is thought to be important for memory acquisition.

Brainstem[edit | edit source]

Brainstem red

The Brainstem lies at the base of the brain and the top of the spinal cord. It is the structure that connects the cerebrum of the brain to the spinal cord and cerebellum. It is composed of 3 sections in descending order: the midbrain, pons, and medulla oblongata. It is responsible for many vital functions of life, such as breathing, consciousness, blood pressure, heart rate, and sleep.  

See link

CNS Blood Supply[edit | edit source]

Circle of Willis

The CNS vasculature provides the nutrients necessary for the correct functioning of the central nervous system (CNS)[7].

Brain: Arterial blood supply to the brain comes from four vessels;

The internal carotid arteries branch to form two major cerebral arteries, the anterior and middle cerebral arteries. The right and left vertebral arteries come together at the level of the pons on the ventral surface of the brainstem to form the midline basilar artery.

Circle of Willis: The basilar artery joins the blood supply from the internal carotids in an arterial ring at the base of the brain (in the vicinity of the hypothalamus and cerebral peduncles) called the circle of Willis. The posterior cerebral arteries arise at this confluence, as do two small bridging arteries, the anterior and posterior communicating arteries. Conjoining the two major sources of cerebral vascular supply via the circle of Willis presumably improves the chances of any region of the brain continuing to receive blood if one of the major arteries becomes occluded[8].

Spinal Cord: The spinal cord is supplied by a single anterior spinal artery and paired posterior spinal arteries. Anterior spinal artery: arises from the vertebral arteries and extends from the level of the lower brainstem to the tip of the conus medullaris. It supplies the ventral medial surface of the medulla and anterior 2/3 of the spinal cord. The posterior spinal arteries supply the dorsal 1/3 of the cord. There are reinforcing branches from other arteries along the length of the cord.

If occlusion occurs, it is normally of the anterior spinal artery, producing loss of power and spinothalamic sensory deficit, but dorsal column sensory capabilities are maintained.

Venous Drainage

Brain Sinuses.jpeg

The cerebrum, cerebellum and brainstem are drained by numerous veins, which empty into the dural venous sinuses[9]. The spinal cord is supplied by anterior and posterior spinal veins, which drain into the internal and external vertebral plexuses .

If occlusion of either of these venous systems then raised intracranial pressure can develop.

The Cerebellum[edit | edit source]

Cerebellum

The cerebellum[10] is a vital component in the human brain as it plays a role in motor movement regulation and balance control. The cerebellum is neuron-rich, containing 80% of the brain’s neurons organized in a dense cellular layer, and it's surface area when unfolded is nearly 75% of the surface area of the cerebrum.

Spinal Cord[edit | edit source]

The spinal cord[11] is part of the central nervous system and consists of a tightly packed column of nerve tissue that extends downwards from the brainstem through the central column of the spine. It is a relatively small bundle of tissue (weighing 35g and just about 1cm in diameter) but is crucial in facilitating our daily activities.

The spinal cord carries nerve signals from the brain to other parts of the body (importantly the muscles we use to move) and receives sensory input from the body, partially processes it, and then transmits that information to the brain.

Spinal nerves contain both motor and sensory nerve fibres, so they are considered mixed nerves. The cell bodies of the sensory neurons are housed in an enlargement called the dorsal root ganglion. Structurally, these sensory neurons are pseudounipolar. The cell bodies of the motor neurons are housed in the grey matter of the spinal cord, specifically the anterior horn. The sensory neurons communicate with the motor neurons at each level through interneurons.

The dorsal root of each spinal cord segment is responsible for innervating specific corresponding areas of skin that can be mapped onto the surface of the body, termed dermatomes. Similarly, myotomes are groups of muscles that are innervated by a single ventral nerve root. Dermatomes and myotomes allow for clinical assessment of specific nerve root injuries or the level of a spinal cord injury.

Spinal nerves C7 and above exit the vertebral column above their corresponding vertebrae. Spinal nerve C8 exits between the C7 and T1 vertebrae, and the rest of the spinal nerves exit below their corresponding vertebrae. Because the spinal cord is shorter than the vertebral column and ends at around the L1 or L2 vertebra, the spinal nerve roots below that level have to descend past the end of the spinal cord in the vertebral column before exiting below their corresponding vertebrae. This forms a bundle of spinal nerve roots below the spinal cord termed the cauda equina.

After the spinal nerves exit the vertebral column they split up into dorsal and ventral rami. Dorsal rami innervate the skin and muscles of the back, while the ventral rami innervate the skin and muscles of the ventral and lateral trunk and extremities.

In areas other than the thoracic, the ventral rami intermingle with each other to form networks called nerve plexuses. These eventually give rise to peripheral nerves that provide sensorimotor innervation to the body.

Peripheral Nervous System (PNS)[edit | edit source]

Autonomic and Somatic Nervous System.png

The peripheral nervous system[12] includes the nerves and ganglia that are outside of the central nervous system.  The peripheral nervous system is made up of two divisions: the somatic nervous system and the autonomic system. Each part of this system plays a vital role in how information is communicated throughout the body.

Neuromuscular Junction[edit | edit source]

Peripheral motor nerves[12] consist of a neuromuscular junction, which is the synaptic connection between the motor neuron and the muscle. Information in the form of electrical impulses reach the presynaptic membrane at the end of an axon and trigger the release of neurotransmitters. In skeletal muscles, the neurotransmitter acetylcholine is often used. The neurotransmitters then cross the gap between the motor neuron and the motor end plate on the muscle, a space termed the synaptic cleft. The motor end plate contains receptors which then receive the neurotransmitters, and this signal is then translated into muscle action.

Autonomic Nervous System (ANS)[edit | edit source]

The autonomic system[13] is the part of the peripheral nervous system that's responsible for regulating involuntary body functions. Functions of the ANS include the regulation of “circulation, respiration, metabolism, secretion, body temperature, and reproduction.”

The ANS is divided into two Divisions:

  1. Sympathetic: Preganglionic neurons found in lateral horn of spinal cord from upper thoracic to mid-lumbar cord (T1-L3). Postganglionic cell bodies found in vertebral and prevertebral ganglia. Uses Noradrenalin as postganglionic transmitter.
  2. Parasympathetic: Preganglionic neurons have cell bodies in the brainstem and sacrum. Postganglionic cell bodies are found adjacent to or within the walls of the organ they supply. Uses acetylcholine (ACh) as postganglionic transmitter.

Somatic Nervous System[edit | edit source]

Nervous system diagram.png

The somatic system[14] is the part of the peripheral nervous system responsible for carrying sensory and motor information to and from the central nervous system. The somatic nervous system derives its name from the Greek word soma, which means "body."

Cranial and spinal nerves contribute to the somatic nervous system. Cranial nerves provide voluntary motor control and sensation to the head and face. Spinal nerves supply the trunk and limbs. The posterior rami travel backwards to supply the vertebral column, vertebral muscles and skin of the back whilst the anterior rami supply the limbs and anterior trunk. The majority of anterior rami combine to form nerve plexuses from which many major peripheral nerves stem. The exception to this is the anterior rami of the thoracic region which travel relatively independently from one another without forming plexuses, as the intercostal and subcostal nerves of the trunk.

Nervous plexuses are as follows:

Sensory Systems[edit | edit source]

Sensory system.jpg

The sensory nervous system[14] is a part of the nervous system responsible for processing sensory information being where information is transmitted to the spinal cord and brain from peripheral sensory receptors. The sensory receptors are specialised neurons or nerve endings. For more see Sensation

There are five main sensory systems in mammals.

  1. touch/pressure
  2. vision
  3. hearing and balance
  4. taste
  5. smell/olfaction

Pain Systems[edit | edit source]

pain

Pain is defined as an unpleasant sensory or emotional experience, associated with potential or actual tissue damage. Nociception defines the processing of information about damaging stimuli by the nervous system up to the level of the cortex. Potentially damaging mechanical, thermal, and chemical stimuli are detected by nerve endings called nociceptors, which are found in the skin, on internal surfaces such as the periosteum, joint surfaces, and in some internal organs.

There are two types of nociceptor: A delta fibres: activated by high threshold mechanoreceptors. thinly myelinated; Unmyelinated C-fibres: activated by polymodal nociceptors(PMN) and respond to intense mechanical stimulation, high temperatures and irritant chemicals.

There are three main pathways that transmit nociceptive signals to the brain:

  1. Spinothalamic tract
  2. Spino reticular tract.
  3. Spino mesencephalic

Motor Systems[edit | edit source]

Motor systems are the areas of the nervous system responsible for controlling movement. Neural control of the somatic motor system involves complex feedback mechanisms between the brain, spinal cord, peripheral nerves, and musculoskeletal structures. Each component is functionally and structurally capable of adaptation and modulation to maintain as much efficiency as possible[15].

Grey and White Matter.[edit | edit source]

The central nervous system is made up of grey matter and white matter.

  1. Grey matter: named for its pinkish-gray color, is home to neural cell bodies, axon terminals, and dendrites, as well as all nerve synapses. This brain tissue is abundant in the cerebellum, cerebrum, and brain stem. It also forms a butterfly-shaped portion of the central spinal cord.
  2. White matter: composed of bundles of axons. These axons are coated with myelin, a mixture of proteins and lipids, that helps conduct nerve signals and protect the axons. White matter conducts, processes, and send nerve signals up and down the spinal cord.

Viewing[edit | edit source]

Take a lot at these videos for further understanding.

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References[edit | edit source]

  1. 1.0 1.1 Parker E. Ludwig; Matthew Varacallo Neuroanatomy, Central Nervous System (CNS) Feb 2019.
  2. Thau L, Reddy V, Singh P. Anatomy, Central Nervous System. StatPearls Publishing; 2024 Jan-. Available from: https://www.ncbi.nlm.nih.gov/books/NBK542179/
  3. Mercadante AA, Tadi P. Neuroanatomy, Gray Matter. StatPearls Publishing; 2024 Jan-. Available from: https://www.ncbi.nlm.nih.gov/books/NBK553239/
  4. Ludwig PE, Reddy V, Varacallo M. Neuroanatomy, Neurons. StatPearls Publishing; 2024 Jan-. Available from: https://www.ncbi.nlm.nih.gov/books/NBK441977/
  5. Xu S, Lu J, Shao A, Zhang JH, Zhang J. Glial cells: role of the immune response in ischemic stroke. Frontiers in immunology. 2020 Feb 26;11:502688.
  6. Sehgal I, M Das J. Anatomy, Back, Spinal Meninges. StatPearls Publishing; 2024 Jan-. Available from: https://www.ncbi.nlm.nih.gov/books/NBK547755/
  7. Weerasuriya, A., Mizisin, A.P. The Blood-Nerve Barrier: Structure and Functional Significance. In: Nag, S. (eds) The Blood-Brain and Other Neural Barriers. Methods in Molecular Biology, 2011. vol 686. Humana Press.
  8. Purves D, Augustine GJ, Fitzpatrick D, Katz LC, LaMantia AS, McNamara JO, Williams S. The blood supply of the brain and spinal cord. Neuroscience. 2001;2.Available: https://www.ncbi.nlm.nih.gov/books/NBK11042/(accessed 6.5.2022)
  9. Bayot ML, Reddy V, Zabel MK. Neuroanatomy, Dural Venous Sinuses. StatPearls Publishing; 2024 Jan-. Available from: https://www.ncbi.nlm.nih.gov/books/NBK482257/
  10. Kebschull JM, Casoni F, Consalez GG, Goldowitz D, Hawkes R, Ruigrok TJ, Schilling K, Wingate R, Wu J, Yeung J, Uusisaari MY. Cerebellum lecture: the cerebellar nuclei—core of the cerebellum. The Cerebellum. 2023 Feb 13:1-58.
  11. Bess S, Line B. Embryology and anatomy: spine/spinal cord. InThe Growing Spine: Management of Spinal Disorders in Young Children 2022 Feb 3 (pp. 3-12). Cham: Springer International Publishing.
  12. 12.0 12.1 Murtazina A, Adameyko I. The peripheral nervous system. Development. 2023 May 1;150(9):dev201164.
  13. Jänig W. The integrative action of the autonomic nervous system: neurobiology of homeostasis. Cambridge University Press; 2022 Aug 4.
  14. 14.0 14.1 Michael-Titus AT, Shortland P. The Nervous System: The Nervous System, E-Book. Elsevier Health Sciences; 2022 Jun 11.
  15. Seffinger MA, Hruby RJ. Evidence-based manual medicine: a problem-oriented approach. Elsevier Health Sciences; 2007. Available: https://www.sciencedirect.com/topics/neuroscience/somatic-motor-system (accessed 6.5.20220
  16. Neuroscientifically Challenged. 2-Minute Neuroscience: Hypothalamus & Pituitary Gland. Available from: http://www.youtube.com/watch?v=TVhm2rBGhB0 [last accessed 19/10/2019]
  17. khanacademymedicine. Motor unit. Available from: http://www.youtube.com/watch?v=vXb0ZvkFkS8 [last accessed 19/10/2019]
  18. UCL Centre for Anaesthesia. An Introduction to Pain Pathways and Mechanisms. Available from: http://www.youtube.com/watch?v=i5V_q7XqQN8 [last accessed 19/10/2019]
  19. khanacademymedicine. Cerebral blood supply - Part 1. Available from: http://www.youtube.com/watch?v=hfG8J_X1D5Q [last accessed 19/10/2019]
  20. khanacademymedicine. Cerebral blood supply - Part 2. Available from: http://www.youtube.com/watch?v=kVulo3qDcUo [last accessed 19/10/2019]
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