Parkinson's disease and a dopamine-derived neurotoxin, 3,4-Dihydroxyphenylacetaldehyde : implications for proteins, microglia, and neurons

Eckert, Laurie Leigh

01 December 2012

Parkinson's disease (PD) is a prevalent neurodegenerative disorder for which the greatest risk factor is age. Four to five percent of 85-year-olds suffer from this debilitating disease, which is characterized by the selective loss of dopaminergic neurons within the substantia nigra and the presence of protein aggregates known as Lewy bodies. While the etiology of this disease is still unknown, recent research implicates oxidative stress, activated microglia, and reactive dopamine (DA) metabolites to play a role in the initiation or progression of the disease. Activated microglia cause injury to dopaminergic neurons via a host of mechanisms, including reactive oxygen species production, release of cytokines, and phagocytic activity. Microglial activation has been detected in the brains of PD patients, but the source of this activation has not been elucidated. Previous research has shown electrophiles and endogenous neurotoxins to play a role in this microglial activation. The interaction between the neurotoxic metabolite of DA, 3,4-dihydroxyphenylacetaldehyde (DOPAL), and microglia has not been explored. DOPAL is a highly reactive, bifunctional electrophile produced by oxidative deamination of DA by monoamine oxidase (MAO). DOPAL is oxidized in the major metabolism pathway to 3,4-dihydroxyphenylacetic acid (DOPAC) by aldehyde dehydrogenase (ALDH). DOPAL has previously been shown to be 100-fold more toxic than DA in vitro and in vivo. Potent inhibition of the rate-limiting enzyme in DA biosynthesis, tyrosine hydroxylase, by DOPAL has been well-established. DOPAL-mediated aggregation of Α-synuclein, the primary component of PD-hallmark Lewy bodies, has been suggested but was further explored in this work. Results presented in this body of work include further determination of the aggregation of Α-synuclein by DOPAL, including evidence of covalent modification. The interaction of DOPAL with BV-2 microglia, an immortalized cell line, was addressed in depth through exploration of DOPAL catabolism, toxicity, and generation of an activational response. Metabolism of DOPAL to DOPAC was altered in activated microglia, with the production of DOPAC reduced by ~40%. Metabolism of DOPAL to DOPAC was also inhibited by both 4-hydroxynonenal and malondialdehyde, gold standards of lipid peroxidation. Both of these compounds were found to be significantly toxic to BV-2 cells at concentrations well below those considered toxic to dopaminergic cells. Alternatively, DOPAL and DA were found to be non-toxic to this cell line, while DOPAL was shown to be significantly toxic to dopaminergic cells at concentrations as low as 10 ΜM. Significant activation of BV-2 microglia by DOPAL was observed at 10 ΜM and above by release of TNF-Α. Morphological changes, release of IL-6, and changes in expression of COX-2 also indicated activation by DOPAL but not DA or DOPAC. BV-2-conditioned media, generated by incubation with DA, DOPAL, or DOPAC, was added to MN9D cells, and toxicity was measured by the MTT assay. BV-2 conditioned media generated by DOPAL incubation produced the greatest toxicity for MN9D cells. These results implicate DOPAL in dopaminergic cell death through microglial activation.

3,4-dihydroxyphenylacetaldehyde

alpha-synuclein

microglia

oxidative stress

Parkinson's disease

Pharmacy and Pharmaceutical Sciences

Immunomodulation As A Potential Therapeutic Approach For Alzheimer’s Disease

Nikolic, William Veljko

13 June 2008

Alzheimer's disease (AD) is the most prevalent form of progressive dementia and is characterized by the accumulation of amyloid beta (Aß) peptide in the brain and in the cerebral vessels forming cerebral amyloid angiopathy (CAA). As previously reported, an active immunization strategy of mice with Aß1-42 peptide results in decreased Th1 and increased Th2 cytokine responses as well as an effectively clearance of CNS Aß. This approach has also yielded favorable results for many patients, unfortunately, a small percentage of these study participants developed severe aseptic meningoencephalitis likely secondary to CNS invasion of activated T-cells. We have previously demonstrated that disruption of CD40-40L pathway reduces Aß plaque load, promotes Th2 response, and rescues from cognitive impairments. However, direct blockage of the CD40 pathway by passive vaccination with anti-CD40L antibody leads to immunosupression. Therefore, in its current form this therapeutic strategy poses an unacceptable risk to the recipient of treatment, aged individual. For those reasons, the identification and characterization of alternative modulators/inhibitors of CD40 signaling may be necessary for the development of safe and effective AD immunotherapy. This proposal introduces novel immunomodulatory therapies that are based on previous vaccination strategies or cell based therapies across medial field. We showed that transcutaneous vaccination can both be efficacious and safe, thus clearly demonstrating that the right combination of the antigens, adjuvants, and the routes of administration are crucial for the right vaccine. Furthermore, we demonstrated that the effects of current Aß vaccine strategies could be enhanced by a simultaneous blockade of CD40-40L signaling. As an alternative approach, we explored the possibility of cell-based therapies and showed that human umbilical cord blood cells, which are currently used as a treatment for systemic lupus erythematosus and leukemia, and currently investigated against stroke, amyotropic lateral sclerosis, age-related macular degeneration, multiple sclerosis, and Parkinson's disease, and showed that not just they improved the AD like pathology in transgenic animals but altered both the brain and peripheral inflammation levels. Lastly, we discussed the involvement of microglia, one of the key players in both AD pathogenesis and Aß clearance and suggesed that microglia in actuality has a continuum of physiological activation states that contribute to proinflammation, antiinflammation, and phagocytosis.

Inflammation

CD40

Immunization

Human umbilical cord blood cells

Microglia

American Studies

Arts and Humanities

CYTOKINE CONTROL OF GLIOMA ADHESION AND MIGRATION

Baghdadchi, Negin

01 June 2014

Glioblastoma multiforme (GBM) is the most lethal primary central nervous system tumor, with median survival after diagnosis of less than 12 months because dissemination into the brain parenchyma limits the long-term effectiveness of surgical resection, and because GBM cells are resistant to radiation and chemotherapy. This sad dismal prognosis for patients with GBM emphasizes the need for greater understand of the fundamental biology of the disease. Invasion is one of the major causes of treatment failure and death from glioma, because disseminated tumor cells provide the seeds for tumor recurrence. Inflammation is increasingly recognized as an important component of invasion. In the brain, inflammation can occur by activation of microglia, the resident macrophages of the brain, or by tumor-associated blood macrophages. Therefore, we hypothesize that activity of the innate immune system in the brain can influence tumor progression by secreting cytokines such as Tumor Necrosis Factor alpha (TNF-α). In this study, we show that patient-derived glioma spheres undergo morphological changes in response to TNF‑α that are associated with changes in migration behavior in vitro. These morphological changes include appearance of tumor islands in site different from where the primary tumor cells were seeded. We further showed that TNF‑α treated cells significantly increased expression of cell adhesion molecules such as CD44 and VCAM-1. Furthermore, we demonstrate increased cell density also caused increased in expression of cell adhesion molecules. The extent to which these are recapitulated in vivo will be investigated.

Glioblastoma multiforme (GBM)

TNF-α

Microglia

Invasion

The Effect of Two Novel Anti-Inflammatory Drugs on Sensorimotor Gating and Microglial Activation in the Poly I:C Rodent Model of Schizophrenia

Shelton, Heath W, Gill, W. Drew, Gabbita, Prasad, Brown, Russell W

12 April 2019

Antipsychotic medications remain the first line of treatment for individuals diagnosed with schizophrenia (SCZ). However, antipsychotic treatment is often not compliant due to dysregulation of both the central (CNS) and autonomic (ANS) nervous systems, resulting in debilitating dose-dependent side effects. Recent work suggests a new approach for treatment of SCZ that could potentially lower treatment doses and reduce side effects. Increased neuroinflammation has been shown in patients diagnosed with SCZ, particularly within the prefrontal cortex (PFC) and hippocampal (HPC) regions of the brain. Tumor necrosis factor-alpha (TNFa) is one of the key pro-inflammatory cytokines observed to be secreted during the inflammatory response. When TNFa is chronically secreted, resident CNS microglia become pro-inflammatory and toxic to the local environment. Microglial activation alongside of dopamine dysregulation thereby results in both the behavioral and neuroinflammatory aspects of SCZ. In this study, we hypothesized dietary administration of two different novel TNFamodulators (PD2024 – Experiment 1 and PD340 – Experiment 2) developed by our collaborators from P2D Bioscience, Inc. (Cincinnati, OH) would alleviate auditory sensorimotor gating deficits and reduce microglial cell activation caused by neonatal polyinosinic:polycytidylic acid (Poly I:C) treatment in rats, which is a validated rodent model of SCZ. Four groups (Experiment 1: Poly IC/PD2024, Poly IC/Control, Saline/PD2024, Saline/Control and Experiment 2: Poly IC/PD340, Poly IC/Control, Saline/PD340, Saline/Control) were intraperitoneally administered either Poly I:C (2 mg/kg) or saline (0.9% NaCl) from postnatal days 5-7. From P30-67, animals were placed on the experimental diet containing either low (10 mg/kg) or high (30 mg/kg) doses of either PD2024 or PD340, whereas the control animals remained on a normal diet. Prepulse inhibition (PPI) was used to test for auditory sensorimotor gating (behavioral abnormalities) in both adolescence (P44-46) and in adulthood (P60-66). At P67, immunohistochemistry (IHC) and confocal microscopy were used to evaluate and examine microglial cell activation using the Iba1-GFP antibody (neuroinflammatory abnormalities) in the PFC and HPC. Results revealed auditory sensorimotor gating deficits in Poly IC/Controls were alleviated in both adolescence and adulthood with either PD2024 or PD340. It was also found that both TNFa modulators significantly reduced microglial activation in the HPC, but not the PFC. The data supports our hypothesis that dietary administration of PD2024 or PD340 alleviates behavioral deficits and decreases neuroinflammation generated from the Poly I:C rodent model of SCZ. Therefore, an approach with a TNFa modulator alongside of current antipsychotic medications could treat both the behavioral and neuroinflammatory aspects of SCZ.

Schizophrenia

Neuroinflammation

TNF-alpha

Microglia

Poly I:C

Behavioral Problems or Disorders

Inflammation

Altered Axon Initial Segment Structure and Function In Inflammatory Disease

Clark, Kareem C

01 January 2017

Axonal pathology is a key contributor to long-term disability in multiple sclerosis (MS), an inflammatory demyelinating disease of the central nervous system (CNS), but the mechanisms that underlie axonal insults remain unclear. While most axonal pathologies characterized in MS are a direct consequence of myelin loss, we propose that axonal pathologies also occur independent of demyelination. In support of this idea, we recently reported that mice that develop experimental autoimmune encephalomyelitis (EAE), a model commonly used to mimic the pathogenesis of MS, exhibit a structural and functional disruption of the axon initial segment (AIS), a subdomain of the axon that acts as the trigger-zone for action potential generation. Importantly, this disruption is independent of myelin loss. Although the mechanism responsible for AIS disruption remains unclear, we observed an attenuation of the AIS insult following treatment with a known scavenger of oxygen free radicals. To further investigate the role of oxidative stress in modulating AIS stability, we employed an in vitro model in which neurons were exposed to a spontaneous reactive oxygen and nitrogen species generator. Through this approach, we demonstrated that oxidative stress is capable of AIS modulation acting through induction of cytosolic calcium (Ca2+) influx from both extracellular and intracellular sources, resulting in calpain protease activation. Furthermore, because rises in intracellular Ca2+ are central to these and other mechanisms of AIS disruption, we next investigated the cisternal organelle (CO), an AIS-localized Ca2+-regulating structure. Although this organelle could prove to be central to AIS modulation, very little is known about the mechanisms regulating its stability. Through this line of investigation, we provide the first evidence of pathological alteration to the CO in a disease state. This disruption precedes loss of AIS protein clustering and axo-axonic GABAergic input in both EAE and MS postmortem tissue. Overall, these studies reveal a primary axonal insult, independent of myelin loss, in a disease classically characterized as a white-matter pathology. Instead, this insult is most likely driven by oxidative stress through local Ca2+ dysregulation at the AIS, providing novel therapeutic targets for MS.

Axon Initial Segment

Multiple Sclerosis

Cisternal Organelle

EAE

Microglia

Oxidative Stress

Nervous System Diseases

MECHANISMS REGULATING AXON INITIAL SEGMENT STABILITY

Benusa, Savannah D

01 January 2018

Axon initial segment (AIS) disruption has been described in a number of pathological environments where neuroinflammation is a contributing factor; however, whether this disruption is reversible in unknown. To address the principle of AIS structural recovery, we employed an acute neuroinflammatory model. Acute neuroinflammation induced disruption of AIS structural and functional domains and, importantly, upon resolution of neuroinflammatory conditions, was reversed. Consistent with other studies, we observed a close interaction of microglia with AISs, and utilized this acute neuroinflammatory model to investigate the relationship between reactive microglia and AIS integrity. Gene expression analysis of microglial transcription profiles identified reactive oxygen species (ROS)-producing enzymes as candidates in AIS pathogenesis. Experiments employing mice lacking the major ROS-producing enzyme NOX2, identified ROS as mediators of AIS disruption. Furthermore, we established calcium-dependent protease calpain as a disruptor of AIS protein clustering in inflammation-induced disruption. Since we observed an intimate interaction between microglia and the AIS, we conducted studies designed to identify a candidate in microglia that regulates microglial-AIS contact. During chronic inflammatory conditions, microglia enhance contact with AISs often completely surrounding the domain. Concomitant with this morphological change, neurofascin (Nfasc) expression increased in microglia. Nfasc is a cell adhesion molecule with cell-specific isoforms known to mediate glial-neuronal interactions, but until now, was not reported to be expressed by microglia. Here, I characterize the unique Nfasc isoform expressed by microglia and present evidence that suggests that microglial Nfasc may mediate microglial-AIS contact, a potentially pivotal interaction in the induction of AIS disruption by pro-inflammatory factors.

Axon Initial Segment

Neuroinflammation

Reactive Oxygen Species

NOX2

AIS Plasticity

Microglia

Neurofascin

Molecular and Cellular Neuroscience

Inactivation génique des transporteurs ABC peroxysomaux ABCD1 et ABCD2 dans les cellules microgliales BV-2 : étude de la physiopathogenèse de l’adrénoleucodystrophie liée à l’X. / Inactivation of peroxisomal ABC transporters, ABCD1 and ABCD2 in BV-2 microglial cells : Towards a better understanding of X-linked adrenoleukodystrophy

Raas, Quentin

17 December 2018

L’adrénoleucodystrophie liée à l’X (X-ALD) est une maladie neurodégénérative sévère caractérisée par une accumulation d’acides gras à très longue chaîne (AGTLC), conséquence d’un défaut de β-oxydation peroxysomale. La maladie est associée à l’absence de la protéine ABCD1, transporteur ABC du peroxysome qui, tout comme son homologue le plus proche, ABCD2, participe à l’import des AGTLC-CoA au sein du peroxysome, l’unique site de leur dégradation par β-oxydation. La compréhension des mécanismes physiopathologiques est aujourd’hui limitée par le manque de modèles expérimentaux pertinents, cellulaires ou animaux. Puisque le défaut peroxysomal dans la microglie apparait comme un événement pathogénique majeur, nous avons généré des lignées de cellules microgliales incapable de transporter et/ou β-oxyder les AGTLC au sein du peroxysome. Quatre lignées cellulaires microgliales BV-2 déficientes en ABCD1, ABCD2, ABCD1 et ABCD2 ou ACOX1 (l’enzyme limitante de la β-oxydation peroxysomale) ont ainsi été générées par édition génique par CRISPR-Cas9. Ces cellules déficientes présentent d’importants défauts biochimiques, une accumulation d’AGTLC mais aussi des changements des contenus en acides gras et cholestérol. Les analyses ultrastructurales effectuées démontrent l’existence d’importantes inclusions lipidiques et indiquent également une augmentation du nombre de peroxysomes et mitochondries dans ces cellules. Les profils transcriptomiques signalent des altérations de la plasticité de ces cellules microgliales et de leur capacité de reprogrammation métabolique en réponse à un stimulus inflammatoire. Les fonctions de phagocytose ou de présentation antigénique des cellules microgliales semblent être affectées par le défaut peroxysomal. Enfin, les résultats obtenus à l’aide de ces modèles suggèrent que l’altération du métabolisme lipidique peroxysomal modifie l’organisation des membranes cellulaires. Ces lignées cellulaires apparaissent donc comme des modèles prometteurs, d’un grand intérêt pour la compréhension de la physiopathologie et l’identification de cibles thérapeutiques de cette maladie neurodégénérative complexe. / X-linked adrenoleukodystrophy (X-ALD) is a severe neurodegenerative disorder characterized by very-long-chain fatty acid (VLCFA) accumulation resulting from a peroxisomal β-oxidation defect. The disease is caused by mutations in the ABCD1 gene, which encodes for a peroxisomal half ABC transporter predicted, like its closest homologue ABCD2, to participate in the entry of VLCFA-CoA into the peroxisome, the unique site of their β-oxidation. Progress in understanding the physiopathogenesis of X-ALD suffers from the lack of appropriate cell and animal models. Since peroxisomal defects in microglia seem to be a key element of the onset of the disease, we generated four microglial cell lines unable to transport and/or β-oxidize VLCFA into the peroxisome. BV-2 microglial cells were engineered with CRISPR-Cas9 to generate four microglial cell lines deficient in ABCD1, ABCD2, both ABCD1 and ABCD2 or ACOX-1 (the first rate-limiting enzyme of the peroxisomal β-oxidation system). Biochemical defects and lipid content changes associated with VLCFA accumulation but also fatty acids and cholesterol changes were identified in deficient microglia. Ultrastructural investigations confirmed cytosolic lipid inclusions and an increased number of peroxisome and mitochondria. Transcriptomic profiles of deficient microglia are indicative of an impaired plasticity and an impaired capacity to operate the metabolic shift required upon an inflammatory stimulation. Peroxisomal defect is likely to affect phagocytosis and antigen presentation capacity of microglia. Peroxisomal lipid metabolism defect is also suggested to modify cell membranes organization. Altogether, these novel mutant cell lines represent a promising model that should permit identification of new therapeutic targets for this complex neurodegenerative disease.

CRISPR-Cas9

Peroxysome

Abcd1

Microglie

Microglia

Abcd1

Peroxisome

CRISPR-Cas9

571.6

Cholesterol metabolism in the Niemann-Pick Type C brain

Peake, Kyle

06 1900

Niemann-Pick Type C (NPC) disease is an autosomal recessive disorder that results in accumulation of unesterified cholesterol in late endosomes/lysosomes (LE/Ls), leading to progressive neurodegeneration and premature death. Microglia are resident immune cells of the central nervous system, which upon activation can secrete potentially neurotoxic molecules such as tumor necrosis factor-alpha (TNFα). Inappropriate activation of microglia has been implicated in NPC disease. Primary microglia cultures from the cerebral cortex of Npc1-/- mice have an altered cholesterol distribution characteristic of NPC-deficient cells. Immunocytochemical analysis revealed increased TNFα staining in Npc1-/- microglia. However, Npc1-/- and Npc1+/+ microglia showed similar mRNA levels of pro-inflammatory cytokines and similar levels of TNFα secretion. To determine whether Npc1-/- microglia contribute to neuron death in NPC disease, microglia were co-cultured with cerebellar granule cells. Surprisingly, the extent of neuronal death was the same in neurons cultured with Npc1+/+ or Npc1-/- microglia. Thus, Npc1-/- microglia have an altered phenotype compared to Npc1+/+ microglia, but this does not lead to neuron death in an in vitro co-culture system. Treatment options for NPC disease remain limited. A consequence of cholesterol sequestration in the LE/Ls, is that cholesterol movement to the endoplasmic reticulum, where cholesterol metabolism is regulated, is impaired. Cyclodextrin (CD), a compound that binds cholesterol, has recently been found to delay the onset of neurological symptoms and prolong life of Npc1-/- mice. Since the brain consists of both neurons and glia, it remains unclear if CD acts directly on neurons and/or other cells in the brain. Neurons cultured from the cerebellum and astrocytes cultured from the cortex of Npc1-/- mice were treated with a low dose (0.1mM) of CD. This treatment decreased cholesterol sequestration and decreased the rate of cholesterol synthesis in Npc1-/- neurons and astrocytes. CD also decreased mRNAs encoding proteins involved in cholesterol synthesis in Npc1-/- neurons and increased genes involved in cholesterol efflux in Npc1-/- astrocytes. Moreover, CD increased cholesterol esterification in Npc1-/- astrocytes. These results suggest that cholesterol trapped in LE/Ls in Npc1-/- neurons and astrocytes was released by CD treatment and reached the ER, thereby regulating cholesterol homeostasis. / Experimental Medicine

Niemann Pick Type C

cyclodextrin

microglia

inflammation

tumor necrosis factor

neurodegeneration

NPC

cholesterol

neurons

astrocytes

PET and the Multitracer Concept: An Approach to Neuroimaging Pathology

Engler, Henry

January 2008

Patients suffering from different forms of neurodegenerative diseases, such as: Creutzfeldt Jacob Disease (CJD), Alzheimer disease (AD), mild cognitive impairment (MCI), frontotemporal dementia and Parkinson’s disease (PD) were examined with Positron Emission Tomography (PET) and the combination of different radiotracers: 15O-water, N-[11C-methyl]-L-deuterodeprenyl (DED), [18F] 2-fluorodeoxyglucose: (FDG), N-methyl-[11C]2-(4-methylaminophenyl)-6-hydroxybenzothiazole (PIB) and L-[11C]-3,4-dihydroxiphenyl-alanine (DOPA). The radiotracers and the combinations of different radiotracers were selected with the intention to detect, in the brain, patterns of neuronal dysfunction, astrocytosis, axon degeneration or protein aggregation (amyloid), in the brain which are pathognomonic for specific diseases and may contribute to improve clinical differential diagnoses. Examinations in healthy volunteers were performed to allow comparisons with patients. In addition, animal studies were conducted to complement the information. In some cases, the PET findings could be compared with the results of autopsies. In contrast to the micropathology, in which only a limited part of a tissue (obtained post-mortem or by biopsy) is inspected, one PET acquisition provides an image of the whole system (e.g.: the brain and the cerebellum). This form of imaging pathology is “in vivo”, where the examination is innocuous for the patient. This thesis is an attempt to stimulate the development of new tracers, new tracer combinations and methods that directly or indirectly describe the anatomo-physiopathological changes produced in the brain in neurodegenerative diseases. A better description of different diseases can be obtained, confirming or questioning the clinical diagnoses and widening our understanding of the mechanisms underlying neurodegeneration. Different pathologies can produce similar symptoms and thus causing confusion regarding clinical diagnosis. The used PET combinations improved the accuracy of the diagnoses. The incipient knowledge emerging from a new neuroimaging pathology in combination with other disciplines may open the way to new classifications of dementias and neurodegenerative diseases based on an “in vivo” pathology.

Neurosciences

PET (Positron Emission Tomography)

multitracer

neuroimaging pathology

astrocytes

microglia

neurodegeneration

amyloid

AD

CJD

PD

Neurovetenskap

Evaluation of the Use of a Bioengineered Hydrogel Containing Hyaluronan to Reduce Inflammation and Scarring following Spinal Cord Injury Associated with Arachnoiditis

Austin, James W.

10 December 2012

Background: Spinal cord injury (SCI) is heterogeneous in nature and can be complicated by inflammation and scarring in the subarachnoid space (arachnoiditis). The constellation of traumatic injury and arachnoiditis can lead to extensive intraparenchymal cysts or post-traumatic syringomyelia (PTS), due to alterations in fluid flow and pressure dynamics in the subarachnoid space. Hypothesis: Intrathecal injection of a bioengineered hydrogel containing hyaluronan (HA) will improve functional recovery following severe spinal cord injury associated with arachnoiditis. Methods: Acute to subacute pathophysiological events were characterized in non-injured sham rats, rats receiving a clip compression/contusion injury (SCI), rats receiving an intrathecal kaolin injection (Arachnoiditis) and in rats receiving SCI plus kaolin injection (PTS). Next, a HA containing hydrogel (HAMC) or artificial cerbralspinal fluid (aCSF) control was injected into the subarachnoid space 24 hours following PTS injury. To assess treatment efficacy, subacute pathophysiology was assessed as was long-term neurobehavioural and neuroanatomical recovery. Finally, in vitro studies examined the effect of HA on TLR4 activation using lipopolysaccharide in primary rat microglial cultures. Results: PTS animals exhibited a greater parenchymal injury response as compared to the sum of SCI alone or arachnoiditis alone. Injection of HAMC reduced the extent of scarring and inflammation in the subarachnoid space and improved neurobehavioural and neuroanatomical recovery relative to aCSF controls. These improvements were associated with reduced chondroitin sulfate proteoglycan and IL-1α expression and a trend towards and axonal preservation. In vitro studies demonstrated that HA is capable of reducing TLR4 mediated inflammation in microglia. Conclusions: Acute arachnoiditis potentiates the intensity of intraparenchymal inflammatory and scarring events following SCI. When HAMC was injected intrathecally following PTS injury, it mitigated some of the pernicious effects of arachnoiditis. Part of the therapeutic action of HAMC can be attributed to the ability of HA to reduce TLR4 mediated inflammation in microglia, possibly through an extracellular mechanism.

Spinal cord injury

Inflammation

Microglia

Hyaluronan

Arachnoiditis

Post-traumatic syringomyelia

Scarring

0317