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Wikipedia

Neuroinflammation

December 15, 2023

Neuroinflammation is inflammation of the nervous tissue. It may be initiated in response to a variety of cues, including infection, traumatic brain injury,[1] toxic metabolites, or autoimmunity.[2] In the central nervous system (CNS), including the brain and spinal cord, microglia are the resident innate immune cells that are activated in response to these cues.[2] The CNS is typically an immunologically privileged site because peripheral immune cells are generally blocked by the blood–brain barrier (BBB), a specialized structure composed of astrocytes and endothelial cells.[3] However, circulating peripheral immune cells may surpass a compromised BBB and encounter neurons and glial cells expressing major histocompatibility complex molecules, perpetuating the immune response.[4] Although the response is initiated to protect the central nervous system from the infectious agent, the effect may be toxic and widespread inflammation as well as further migration of leukocytes through the blood–brain barrier may occur.[2]

Causes edit

Neuroinflammation is widely regarded as chronic, as opposed to acute, inflammation of the central nervous system.[5] Acute inflammation usually follows injury to the central nervous system immediately, and is characterized by inflammatory molecules, endothelial cell activation, platelet deposition, and tissue edema.[6] Chronic inflammation is the sustained activation of glial cells and recruitment of other immune cells into the brain. It is chronic inflammation that is typically associated with neurodegenerative diseases. Common causes of chronic neuroinflammation include:

 
The initiation of neuroinflammation in the body. (Created with BioRender.com)

Viruses, bacteria, and other infectious agents activate the body’s defense systems and cause immune cells to protect the designed area from the damage. Some of these foreign pathogens can trigger a strong inflammatory response that can compromise the integrity of the blood-brain barrier and thus change the flow of inflammation in nearby tissue. The location along with the type of infection can determine what type of inflammatory response is activated and whether specific cytokines or immune cells will act.[7]

Neuroimmune response edit

See also: Neuroimmune system

Glial cells edit

Microglia are recognized as the innate immune cells of the central nervous system.[2] Microglia actively survey their environment and change their cell morphology significantly in response to neural injury.[8] Acute inflammation in the brain is typically characterized by rapid activation of microglia.[5] During this period, there is no peripheral immune response. Over time, however, chronic inflammation causes the degradation of tissue and of the blood–brain barrier. During this time, microglia generate reactive oxygen species and release signals to recruit peripheral immune cells for an inflammatory response.[8]

Astrocytes are glial cells that are the most abundant cells in the brain. They are involved in maintenance and support of neurons and compose a significant component of the blood–brain barrier. After insult to the brain, such as traumatic brain injury, astrocytes may become activated in response to signals released by injured neurons or activated microglia.[6][1] Once activated, astrocytes may release various growth factors and undergo morphological changes. For example, after injury, astrocytes form the glial scar composed of a proteoglycan matrix that hinders axonal regeneration.[6] However, more recent studies revealed that glia scar is not detrimental, but is in fact beneficial for axonal regeneration.[9]

Cytokines edit

Cytokines are a class of proteins regulating inflammation, cell signaling, and various cell processes such as growth and survival.[10] Chemokines are a subset of cytokines that regulate cell migration, such as attracting immune cells to a site of infection or injury.[10] Various cell types in the brain may produce cytokines and chemokines such as microglia, astrocytes, endothelial cells, and other glial cells. Physiologically, chemokines and cytokines function as neuromodulators that regulate inflammation and development. In the healthy brain, cells secrete cytokines to produce a local inflammatory environment to recruit microglia and clear the infection or injury. However, in neuroinflammation, cells may have sustained release of cytokines and chemokines which may compromise the blood–brain barrier.[11] Peripheral immune cells are called to the site of injury via these cytokines and may now migrate across the compromised blood brain barrier into the brain. Common cytokines produced in response to brain injury include: interleukin-6 (IL-6), which is produced during astrogliosis, and interleukin-1 beta (IL-1β) and tumor necrosis factor alpha (TNF-α), which can induce neuronal cytotoxicity. Although the pro-inflammatory cytokines may cause cell death and secondary tissue damage, they are necessary to repair the damaged tissue.[12] For example, TNF-α causes neurotoxicity at early stages of neuroinflammation, but contributes to tissue growth at later stages of inflammation.

Peripheral immune response edit

The blood–brain barrier is a structure composed of endothelial cells and astrocytes that forms a barrier between the brain and circulating blood. Physiologically, this enables the brain to be protected from potentially toxic molecules and cells in the blood. Astrocytes form tight junctions, and therefore may strictly regulate what may pass the blood–brain barrier and enter the interstitial space.[6] After injury and sustained release of inflammatory factors such as chemokines, the blood–brain barrier may be compromised, becoming permeable to circulating blood components and peripheral immune cells. Cells involved in the innate and adaptive immune responses, such as macrophages, T cells, and B cells, may then enter into the brain. This exacerbates the inflammatory environment of the brain and contributes to chronic neuroinflammation and neurodegeneration.

Traumatic brain injury edit

Traumatic brain injury (TBI) is brain trauma caused by significant force to the head.[6] Following TBI, there are both reparative and degenerative mechanisms that lead to an inflammatory environment. Within minutes of injury, pro-inflammatory cytokines are released. The pro-inflammatory cytokine Il-1β is one such cytokine that exacerbates the tissue damage caused by TBI. TBI may cause significant damage to vital components to the brain, including the blood–brain barrier. Il-1β causes DNA fragmentation and apoptosis, and together with TNF-α may cause damage to the blood–brain barrier and infiltration of leukocytes.[13] Increased density of activated immune cells have been found in the human brain after concussion.[1]

As the most abundant immune cells in the brain, Microglia are important to the brain’s defense against injury. The major caveat of these cells comes from the fact that their ability to promote recovery mechanism with anti-inflammatory factors, is inhibited by their secondary ability to make a large amount of pro-inflammatory cytokines. This can result in sustained brain damage as anti-inflammatory factors decrease in amount when more pro-inflammatory cytokines are produced in excess by microglia. The cytokines produced by microglia, astrocytes, and other immune cells, activate glial cells further increasing the number of pro-inflammatory factors that further prevent neurological systems from recovering. The dual nature of microglia is one example of why neuroinflammation can be helpful or hurtful under specific conditions.[14]

 
Role of Neuroinflammation in the Pathophysiology of TBI. (Created with BioRender.com)

Spinal cord injury edit

Spinal Cord Injury (SCI) can be divided into three separate phases. The primary or acute phase occurs from seconds to minutes after injury, the secondary phase occurs from minutes to weeks after injury, and the chronic phase occurs from months to years following injury.[15] A primary SCI is caused by spinal cord compression or transection, leading to glutamate excitotoxicity, sodium and calcium ion imbalances, and free radical damage.[16] Neurodegeneration via apoptosis and demyelination of neuronal cells causes inflammation at the injury site.[15] This leads to a secondary SCI, whose symptoms include edema, cavitation of spinal parenchyma, reactive gliosis, and potentially permanent loss of function.[15]

During the SCI induced inflammatory response, several pro-inflammatory cytokines including interleukin 1β (IL-1β), inducible Nitric Oxide Synthase (iNOS), Interferon-γ (IFN-γ), IL-6, IL-23, and tumor necrosis factor α (TNFα) are secreted, activating local microglia and attracting various immune cells such as naive bone-marrow derived macrophages.[17] These activated microglia and macrophages play a role in the pathogenesis of SCI.

Upon infiltration of the injury site's epicenter, macrophages will undergo phenotype switching from an M2 phenotype to an M1-like phenotype. The M2 phenotype is associated with anti-inflammatory factors such as IL-10, IL-4, and IL-13 and contributes to wound healing and tissue repair. However, the M1-like phenotype is associated with pro-inflammatory cytokines and reactive oxygen species that contribute to increased damage and inflammation.[18] Factors such as myelin debris, which is formed by the injury at the damage site, has been shown to induce the phenotype shift from M2 to M1.[19] A decreased population of M2 macrophages and an increased population of M1 macrophages is associated with chronic inflammation.[19] Short term inflammation is important in clearing cell debris from the site of injury, but it is this chronic, long-term inflammation that will lead to further cell death and damage radiating from the site of injury.[20]

Aging edit

Aging is often associated with cognitive impairment and increased propensity for developing neurodegenerative diseases, such as Alzheimer's disease.[21] Elevated inflammatory markers seemed to accelerate the brain aging process[22] In the aged brain alone, without any evident disease, there are chronically increased levels of pro-inflammatory cytokines and reduced levels of anti-inflammatory cytokines. The homeostatic imbalance between anti-inflammatory and pro-inflammatory cytokines in aging is one factor that increases the risk for neurodegenerative disease. Additionally, there is an increased number of activated microglia in aged brains, which have increased expression of major histocompatibility complex II (MHC II), ionized calcium binding adaptor-1 (IBA1), CD86, ED1 macrophage antigen, CD4, and leukocyte common antigen.[23] These activated microglia decrease the ability for neurons to undergo long term potentiation (LTP) in the hippocampus and thereby reduce the ability to form memories.[24]

 
Impairment of neuron LTP by activated Microglia. (Created with BioRender.com)

As one of the major cytokines responsible for maintaining inflammatory balance, IL-6 can also be used as a biological marker to observe the correlation between age and neuroinflammation. The same levels of IL-6 observed in the brain after injury, have also been found in the elderly and indicate the potential for cognitive impairment to develop. The unnecessary upregulation of IL-6 in the elderly population is a result of dysfunctional mediation by glial cells that can lead to the priming of glial cells and result in a more sensitive neuroinflammatory response.[25]

Role in neurodegenerative disease edit

Alzheimer's disease edit

Alzheimer's disease (AD) has historically been characterized by two major hallmarks: neurofibrillary tangles and amyloid-beta plaques.[26] Neurofibrillary tangles are insoluble aggregates of tau proteins, and amyloid-beta plaques are extracellular deposits of the amyloid-beta protein. Current thinking in AD pathology goes beyond these two typical hallmarks to suggest that a significant portion of neurodegeneration in Alzheimer's is due to neuroinflammation.[26][27] Activated microglia are seen in abundance in post-mortem AD brains. Current thought is that inflammatory cytokine-activated microglia cannot phagocytose amyloid-beta, which may contribute to plaque accumulation as opposed to clearance.[28] Additionally, the inflammatory cytokine IL-1β is upregulated in AD and is associated with decreases of synaptophysin and consequent synaptic loss. Further evidence that inflammation is associated with disease progression in AD is that individuals who take non-steroidal anti-inflammatory drugs (NSAIDs) regularly have been associated with a 67% of protection against the onset of AD (relative to the placebo group) in a four-year follow-up assessment.[29] Elevated inflammatory markers showed an association with accelerated brain aging, which might explain the link to neurodegeneration in AD-related brain regions.[22]

Parkinson's disease edit

The leading hypothesis of Parkinson's disease progression includes neuroinflammation as a major component.[30] This hypothesis stipulates that Stage 1 of Parkinson's disease begins in the gut, as evidenced by a large number of cases that begin with constipation[citation needed]. The inflammatory response in the gut may play a role[citation needed] in alpha-synuclein (α-Syn) aggregation and misfolding, a characteristic of Parkinson's disease pathology. If there is a balance between good bacteria and bad bacteria in the gut, the bacteria may remain contained to the gut. However, dysbiosis of good bacteria and bad bacteria may cause a “leaky” gut, creating an inflammatory response. This response aids α-Syn misfolding and transfer across neurons, as the protein works its way up to the CNS.[citation needed] The brainstem is vulnerable to inflammation, which would explain Stage 2, including sleep disturbances and depression. In Stage 3 of the hypothesis, the inflammation affects the substantia nigra, the dopamine producing cells of the brain, beginning the characteristic motor deficits of Parkinson's disease. Stage 4 of Parkinson's disease includes deficits caused by inflammation in key regions of the brain that regulate executive function and memory. As evidence supporting this hypothesis, patients in Stage 3 (motor deficits) that are not experiencing cognitive deficits already show that there is neuroinflammation of the cortex. This suggests that neuroinflammation may be a precursor to the deficits seen in Parkinson's disease.[30]

Amyotrophic lateral sclerosis edit

Unlike other neurodegenerative diseases, the exact pathophysiology of amyotrophic lateral sclerosis (ALS) is still far from being fully uncovered. Several hypotheses have been proposed to explain the development and progression of this lethal disease,[31] by which neuroinflammation is one of the above. It is characterised by the activation of microglia and astrocytes, T lymphocyte infiltration, and the production of pro-inflammatory cytokines.[32] Features of neuroinflammation were observed in the brain of living ALS patients,[33] post-mortem CNS samples,[34] and mouse models of ALS.[35] Multiple evidence has described the mechanism of how microglial and astrocyte activation can promote disease progression (reviewed by [36][37]). Replacement of mSOD1 microglia and astrocytes with the wild-type forms delayed motor neuron (MN) degeneration and extended the lifespan of ALS mice.[38][39] Infiltration of T cells was reported in both early and late stages of ALS.[38][40][41] Among all T cells, CD4+ T cells has drawn the most attention by being a neuroprotective agent during MN loss.[42] T regulatory (Treg) cells is also a safeguard against neuroinflammation, demonstrated by the evidence of inverse correlation of the number of Treg cells and disease progression/ severity.[38][43] Apart from the three phenotypes discussed, peripheral macrophages/ monocytes and the complement system are also suggested to be contributed to disease pathogenesis. Activation[44] and invasion[45][46] of peripheral monocytes observed in the spinal cord of ALS patients and mice may lead to MN loss. Expression of several complement components are reported to be upregulated in the samples isolated from ALS patients[47] and transgenic rodent models.[48] Further studies are required to elucidate their roles in ALS.

Multiple sclerosis edit

Multiple sclerosis is the most common disabling neurological disease of young adults.[49] It is characterized by demyelination and neurodegeneration, which contribute to the common symptoms of cognitive deficits, limb weakness, and fatigue.[50] In multiple sclerosis, inflammatory cytokines disrupt the blood–brain barrier and allow for the migration of peripheral immune cells into the central nervous system. When they have migrated into the central nervous system, B cells and plasma cells produce antibodies against the myelin sheath that insulates neurons, degrading the myelin and slowing conduction in the neurons. Additionally, T cells may enter through the blood–brain barrier, be activated by local antigen presenting cells, and attack the myelin sheath. This has the same effect of degrading the myelin and slowing conduction. As in other neurodegenerative diseases, activated microglia produce inflammatory cytokines that contribute to widespread inflammation. It has been shown that inhibiting microglia decreases the severity of multiple sclerosis.[30]

Role as a therapeutic target edit

Drug therapy edit

Because neuroinflammation has been associated with a variety of neurodegenerative diseases, there is increasing interest to determine whether reducing inflammation will reverse neurodegeneration. Inhibiting inflammatory cytokines, such as IL-1β, decreases neuronal loss seen in neurodegenerative diseases. Current treatments for multiple sclerosis include interferon-B, Glatiramer acetate, and Mitoxantrone, which function by reducing or inhibiting T Cell activation, but have the side effect of systemic immunosuppression [51] In Alzheimer's disease, the use of non-steroidal anti-inflammatory drugs decreases the risk of developing the disease.[29] Current treatments for Alzheimer's disease include NSAIDs and glucocorticoids. NSAIDs function by blocking conversion of prostaglandin H2 into other prostaglandins (PGs) and thromboxane (TX). Prostoglandins and thromboxane act as inflammatory mediators and increase microvascular permeability.

Exercise edit

Exercise is a promising mechanism of prevention and treatment for various diseases characterized by neuroinflammation.[23] Aerobic exercise is used widely to reduce inflammation in the periphery by activating protective systems in the body that stabilize internal environment.[52] Exercise has been shown to decrease proliferation of microglia in the brain, decrease hippocampal expression of immune-related genes and reduce expression of inflammatory cytokines such as TNF-α.

 
The neuroprotective and anti-inflammatory effects of exercise on cognitive diseases. (Created with BioRender.com)

Exercise can help protect the mind and body by maintaining the brain’s internal environment, focusing on recruiting anti-inflammatory cytokines, and activating cellular processes that proactively protect against damage while also initiating recovery mechanisms. The ability of physical activity to stimulate immune defenses against neuroinflammation-related diseases has been observed in recent clinical studies. The application of various exercises under a range of different conditions resulted in higher neurological metabolism, stronger protection against free radicals, and stronger neuroplasticity against neurological diseases. The resulting increase in brain function was due to the induced change in gene expression, increase in trophic factors, and reduction in pro-inflammatory cytokines.[53]

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Further reading edit

  • Maggi P, Macri SM, Gaitán MI, Leibovitch E, Wholer JE, Knight HL, Ellis M, Wu T, Silva AC, Massacesi L, Jacobson S, Westmoreland S, Reich DS (October 2014). "The formation of inflammatory demyelinated lesions in cerebral white matter". Annals of Neurology. 76 (4): 594–608. doi:10.1002/ana.24242. PMC 4723108. PMID 25088017.

December 15, 2023
neuroinflammation, inflammation, nervous, tissue, initiated, response, variety, cues, including, infection, traumatic, brain, injury, toxic, metabolites, autoimmunity, central, nervous, system, including, brain, spinal, cord, microglia, resident, innate, immun. Neuroinflammation is inflammation of the nervous tissue It may be initiated in response to a variety of cues including infection traumatic brain injury 1 toxic metabolites or autoimmunity 2 In the central nervous system CNS including the brain and spinal cord microglia are the resident innate immune cells that are activated in response to these cues 2 The CNS is typically an immunologically privileged site because peripheral immune cells are generally blocked by the blood brain barrier BBB a specialized structure composed of astrocytes and endothelial cells 3 However circulating peripheral immune cells may surpass a compromised BBB and encounter neurons and glial cells expressing major histocompatibility complex molecules perpetuating the immune response 4 Although the response is initiated to protect the central nervous system from the infectious agent the effect may be toxic and widespread inflammation as well as further migration of leukocytes through the blood brain barrier may occur 2 Contents 1 Causes 2 Neuroimmune response 2 1 Glial cells 2 2 Cytokines 3 Peripheral immune response 4 Traumatic brain injury 5 Spinal cord injury 6 Aging 7 Role in neurodegenerative disease 7 1 Alzheimer s disease 7 2 Parkinson s disease 7 3 Amyotrophic lateral sclerosis 7 4 Multiple sclerosis 8 Role as a therapeutic target 8 1 Drug therapy 8 2 Exercise 9 References 10 Further readingCauses editNeuroinflammation is widely regarded as chronic as opposed to acute inflammation of the central nervous system 5 Acute inflammation usually follows injury to the central nervous system immediately and is characterized by inflammatory molecules endothelial cell activation platelet deposition and tissue edema 6 Chronic inflammation is the sustained activation of glial cells and recruitment of other immune cells into the brain It is chronic inflammation that is typically associated with neurodegenerative diseases Common causes of chronic neuroinflammation include Toxic metabolites Autoimmunity Ageing Microbes Viruses Traumatic brain injury Spinal cord injury Air pollution Passive smoke nbsp The initiation of neuroinflammation in the body Created with BioRender com Viruses bacteria and other infectious agents activate the body s defense systems and cause immune cells to protect the designed area from the damage Some of these foreign pathogens can trigger a strong inflammatory response that can compromise the integrity of the blood brain barrier and thus change the flow of inflammation in nearby tissue The location along with the type of infection can determine what type of inflammatory response is activated and whether specific cytokines or immune cells will act 7 Neuroimmune response editSee also Neuroimmune system Glial cells edit Microglia are recognized as the innate immune cells of the central nervous system 2 Microglia actively survey their environment and change their cell morphology significantly in response to neural injury 8 Acute inflammation in the brain is typically characterized by rapid activation of microglia 5 During this period there is no peripheral immune response Over time however chronic inflammation causes the degradation of tissue and of the blood brain barrier During this time microglia generate reactive oxygen species and release signals to recruit peripheral immune cells for an inflammatory response 8 Astrocytes are glial cells that are the most abundant cells in the brain They are involved in maintenance and support of neurons and compose a significant component of the blood brain barrier After insult to the brain such as traumatic brain injury astrocytes may become activated in response to signals released by injured neurons or activated microglia 6 1 Once activated astrocytes may release various growth factors and undergo morphological changes For example after injury astrocytes form the glial scar composed of a proteoglycan matrix that hinders axonal regeneration 6 However more recent studies revealed that glia scar is not detrimental but is in fact beneficial for axonal regeneration 9 Cytokines edit Cytokines are a class of proteins regulating inflammation cell signaling and various cell processes such as growth and survival 10 Chemokines are a subset of cytokines that regulate cell migration such as attracting immune cells to a site of infection or injury 10 Various cell types in the brain may produce cytokines and chemokines such as microglia astrocytes endothelial cells and other glial cells Physiologically chemokines and cytokines function as neuromodulators that regulate inflammation and development In the healthy brain cells secrete cytokines to produce a local inflammatory environment to recruit microglia and clear the infection or injury However in neuroinflammation cells may have sustained release of cytokines and chemokines which may compromise the blood brain barrier 11 Peripheral immune cells are called to the site of injury via these cytokines and may now migrate across the compromised blood brain barrier into the brain Common cytokines produced in response to brain injury include interleukin 6 IL 6 which is produced during astrogliosis and interleukin 1 beta IL 1b and tumor necrosis factor alpha TNF a which can induce neuronal cytotoxicity Although the pro inflammatory cytokines may cause cell death and secondary tissue damage they are necessary to repair the damaged tissue 12 For example TNF a causes neurotoxicity at early stages of neuroinflammation but contributes to tissue growth at later stages of inflammation Peripheral immune response editThe blood brain barrier is a structure composed of endothelial cells and astrocytes that forms a barrier between the brain and circulating blood Physiologically this enables the brain to be protected from potentially toxic molecules and cells in the blood Astrocytes form tight junctions and therefore may strictly regulate what may pass the blood brain barrier and enter the interstitial space 6 After injury and sustained release of inflammatory factors such as chemokines the blood brain barrier may be compromised becoming permeable to circulating blood components and peripheral immune cells Cells involved in the innate and adaptive immune responses such as macrophages T cells and B cells may then enter into the brain This exacerbates the inflammatory environment of the brain and contributes to chronic neuroinflammation and neurodegeneration Traumatic brain injury editTraumatic brain injury TBI is brain trauma caused by significant force to the head 6 Following TBI there are both reparative and degenerative mechanisms that lead to an inflammatory environment Within minutes of injury pro inflammatory cytokines are released The pro inflammatory cytokine Il 1b is one such cytokine that exacerbates the tissue damage caused by TBI TBI may cause significant damage to vital components to the brain including the blood brain barrier Il 1b causes DNA fragmentation and apoptosis and together with TNF a may cause damage to the blood brain barrier and infiltration of leukocytes 13 Increased density of activated immune cells have been found in the human brain after concussion 1 As the most abundant immune cells in the brain Microglia are important to the brain s defense against injury The major caveat of these cells comes from the fact that their ability to promote recovery mechanism with anti inflammatory factors is inhibited by their secondary ability to make a large amount of pro inflammatory cytokines This can result in sustained brain damage as anti inflammatory factors decrease in amount when more pro inflammatory cytokines are produced in excess by microglia The cytokines produced by microglia astrocytes and other immune cells activate glial cells further increasing the number of pro inflammatory factors that further prevent neurological systems from recovering The dual nature of microglia is one example of why neuroinflammation can be helpful or hurtful under specific conditions 14 nbsp Role of Neuroinflammation in the Pathophysiology of TBI Created with BioRender com Spinal cord injury editSpinal Cord Injury SCI can be divided into three separate phases The primary or acute phase occurs from seconds to minutes after injury the secondary phase occurs from minutes to weeks after injury and the chronic phase occurs from months to years following injury 15 A primary SCI is caused by spinal cord compression or transection leading to glutamate excitotoxicity sodium and calcium ion imbalances and free radical damage 16 Neurodegeneration via apoptosis and demyelination of neuronal cells causes inflammation at the injury site 15 This leads to a secondary SCI whose symptoms include edema cavitation of spinal parenchyma reactive gliosis and potentially permanent loss of function 15 During the SCI induced inflammatory response several pro inflammatory cytokines including interleukin 1b IL 1b inducible Nitric Oxide Synthase iNOS Interferon g IFN g IL 6 IL 23 and tumor necrosis factor a TNFa are secreted activating local microglia and attracting various immune cells such as naive bone marrow derived macrophages 17 These activated microglia and macrophages play a role in the pathogenesis of SCI Upon infiltration of the injury site s epicenter macrophages will undergo phenotype switching from an M2 phenotype to an M1 like phenotype The M2 phenotype is associated with anti inflammatory factors such as IL 10 IL 4 and IL 13 and contributes to wound healing and tissue repair However the M1 like phenotype is associated with pro inflammatory cytokines and reactive oxygen species that contribute to increased damage and inflammation 18 Factors such as myelin debris which is formed by the injury at the damage site has been shown to induce the phenotype shift from M2 to M1 19 A decreased population of M2 macrophages and an increased population of M1 macrophages is associated with chronic inflammation 19 Short term inflammation is important in clearing cell debris from the site of injury but it is this chronic long term inflammation that will lead to further cell death and damage radiating from the site of injury 20 Aging editAging is often associated with cognitive impairment and increased propensity for developing neurodegenerative diseases such as Alzheimer s disease 21 Elevated inflammatory markers seemed to accelerate the brain aging process 22 In the aged brain alone without any evident disease there are chronically increased levels of pro inflammatory cytokines and reduced levels of anti inflammatory cytokines The homeostatic imbalance between anti inflammatory and pro inflammatory cytokines in aging is one factor that increases the risk for neurodegenerative disease Additionally there is an increased number of activated microglia in aged brains which have increased expression of major histocompatibility complex II MHC II ionized calcium binding adaptor 1 IBA1 CD86 ED1 macrophage antigen CD4 and leukocyte common antigen 23 These activated microglia decrease the ability for neurons to undergo long term potentiation LTP in the hippocampus and thereby reduce the ability to form memories 24 nbsp Impairment of neuron LTP by activated Microglia Created with BioRender com As one of the major cytokines responsible for maintaining inflammatory balance IL 6 can also be used as a biological marker to observe the correlation between age and neuroinflammation The same levels of IL 6 observed in the brain after injury have also been found in the elderly and indicate the potential for cognitive impairment to develop The unnecessary upregulation of IL 6 in the elderly population is a result of dysfunctional mediation by glial cells that can lead to the priming of glial cells and result in a more sensitive neuroinflammatory response 25 Role in neurodegenerative disease editAlzheimer s disease edit Alzheimer s disease AD has historically been characterized by two major hallmarks neurofibrillary tangles and amyloid beta plaques 26 Neurofibrillary tangles are insoluble aggregates of tau proteins and amyloid beta plaques are extracellular deposits of the amyloid beta protein Current thinking in AD pathology goes beyond these two typical hallmarks to suggest that a significant portion of neurodegeneration in Alzheimer s is due to neuroinflammation 26 27 Activated microglia are seen in abundance in post mortem AD brains Current thought is that inflammatory cytokine activated microglia cannot phagocytose amyloid beta which may contribute to plaque accumulation as opposed to clearance 28 Additionally the inflammatory cytokine IL 1b is upregulated in AD and is associated with decreases of synaptophysin and consequent synaptic loss Further evidence that inflammation is associated with disease progression in AD is that individuals who take non steroidal anti inflammatory drugs NSAIDs regularly have been associated with a 67 of protection against the onset of AD relative to the placebo group in a four year follow up assessment 29 Elevated inflammatory markers showed an association with accelerated brain aging which might explain the link to neurodegeneration in AD related brain regions 22 Parkinson s disease edit The leading hypothesis of Parkinson s disease progression includes neuroinflammation as a major component 30 This hypothesis stipulates that Stage 1 of Parkinson s disease begins in the gut as evidenced by a large number of cases that begin with constipation citation needed The inflammatory response in the gut may play a role citation needed in alpha synuclein a Syn aggregation and misfolding a characteristic of Parkinson s disease pathology If there is a balance between good bacteria and bad bacteria in the gut the bacteria may remain contained to the gut However dysbiosis of good bacteria and bad bacteria may cause a leaky gut creating an inflammatory response This response aids a Syn misfolding and transfer across neurons as the protein works its way up to the CNS citation needed The brainstem is vulnerable to inflammation which would explain Stage 2 including sleep disturbances and depression In Stage 3 of the hypothesis the inflammation affects the substantia nigra the dopamine producing cells of the brain beginning the characteristic motor deficits of Parkinson s disease Stage 4 of Parkinson s disease includes deficits caused by inflammation in key regions of the brain that regulate executive function and memory As evidence supporting this hypothesis patients in Stage 3 motor deficits that are not experiencing cognitive deficits already show that there is neuroinflammation of the cortex This suggests that neuroinflammation may be a precursor to the deficits seen in Parkinson s disease 30 Amyotrophic lateral sclerosis edit Unlike other neurodegenerative diseases the exact pathophysiology of amyotrophic lateral sclerosis ALS is still far from being fully uncovered Several hypotheses have been proposed to explain the development and progression of this lethal disease 31 by which neuroinflammation is one of the above It is characterised by the activation of microglia and astrocytes T lymphocyte infiltration and the production of pro inflammatory cytokines 32 Features of neuroinflammation were observed in the brain of living ALS patients 33 post mortem CNS samples 34 and mouse models of ALS 35 Multiple evidence has described the mechanism of how microglial and astrocyte activation can promote disease progression reviewed by 36 37 Replacement of mSOD1 microglia and astrocytes with the wild type forms delayed motor neuron MN degeneration and extended the lifespan of ALS mice 38 39 Infiltration of T cells was reported in both early and late stages of ALS 38 40 41 Among all T cells CD4 T cells has drawn the most attention by being a neuroprotective agent during MN loss 42 T regulatory Treg cells is also a safeguard against neuroinflammation demonstrated by the evidence of inverse correlation of the number of Treg cells and disease progression severity 38 43 Apart from the three phenotypes discussed peripheral macrophages monocytes and the complement system are also suggested to be contributed to disease pathogenesis Activation 44 and invasion 45 46 of peripheral monocytes observed in the spinal cord of ALS patients and mice may lead to MN loss Expression of several complement components are reported to be upregulated in the samples isolated from ALS patients 47 and transgenic rodent models 48 Further studies are required to elucidate their roles in ALS Multiple sclerosis edit Multiple sclerosis is the most common disabling neurological disease of young adults 49 It is characterized by demyelination and neurodegeneration which contribute to the common symptoms of cognitive deficits limb weakness and fatigue 50 In multiple sclerosis inflammatory cytokines disrupt the blood brain barrier and allow for the migration of peripheral immune cells into the central nervous system When they have migrated into the central nervous system B cells and plasma cells produce antibodies against the myelin sheath that insulates neurons degrading the myelin and slowing conduction in the neurons Additionally T cells may enter through the blood brain barrier be activated by local antigen presenting cells and attack the myelin sheath This has the same effect of degrading the myelin and slowing conduction As in other neurodegenerative diseases activated microglia produce inflammatory cytokines that contribute to widespread inflammation It has been shown that inhibiting microglia decreases the severity of multiple sclerosis 30 Role as a therapeutic target editDrug therapy edit Because neuroinflammation has been associated with a variety of neurodegenerative diseases there is increasing interest to determine whether reducing inflammation will reverse neurodegeneration Inhibiting inflammatory cytokines such as IL 1b decreases neuronal loss seen in neurodegenerative diseases Current treatments for multiple sclerosis include interferon B Glatiramer acetate and Mitoxantrone which function by reducing or inhibiting T Cell activation but have the side effect of systemic immunosuppression 51 In Alzheimer s disease the use of non steroidal anti inflammatory drugs decreases the risk of developing the disease 29 Current treatments for Alzheimer s disease include NSAIDs and glucocorticoids NSAIDs function by blocking conversion of prostaglandin H2 into other prostaglandins PGs and thromboxane TX Prostoglandins and thromboxane act as inflammatory mediators and increase microvascular permeability Exercise edit Exercise is a promising mechanism of prevention and treatment for various diseases characterized by neuroinflammation 23 Aerobic exercise is used widely to reduce inflammation in the periphery by activating protective systems in the body that stabilize internal environment 52 Exercise has been shown to decrease proliferation of microglia in the brain decrease hippocampal expression of immune related genes and 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11 001 PMID 21619866 McPherson RC Anderton SM September 2013 Adaptive immune responses in CNS autoimmune disease mechanisms and therapeutic opportunities Journal of Neuroimmune Pharmacology 8 4 774 90 doi 10 1007 s11481 013 9453 9 PMID 23568718 S2CID 16198820 Seo Dae Yun Heo Jun Won Ko Jeong Rim Kwak Hyo Bum November 2019 Exercise and Neuroinflammation in Health and Disease International Neurourology Journal 23 Suppl 2 S82 92 doi 10 5213 inj 1938214 107 ISSN 2093 4777 PMC 6905205 PMID 31795607 Seo Dae Yun Heo Jun Won Ko Jeong Rim Kwak Hyo Bum November 2019 Exercise and Neuroinflammation in Health and Disease International Neurourology Journal 23 Suppl 2 S82 92 doi 10 5213 inj 1938214 107 ISSN 2093 4777 PMC 6905205 PMID 31795607 Further reading editMaggi P Macri SM Gaitan MI Leibovitch E Wholer JE Knight HL Ellis M Wu T Silva AC Massacesi L Jacobson S Westmoreland S Reich DS October 2014 The formation of inflammatory demyelinated lesions in cerebral white matter Annals of Neurology 76 4 594 608 doi 10 1002 ana 24242 PMC 4723108 PMID 25088017 Retrieved from https en wikipedia org w index php title Neuroinflammation amp oldid 1189192839, wikipedia, wiki, book, books, library,

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