The impact of glial inhibition on the spinal instrumental learning paradigm

Vichaya, Elisabeth Good

15 May 2009

Although neural plasticity has traditionally been studied within the brain, evidence indicates that the spinal cord is quite plastic as well. Spinal neurons can even support a simple form of instrumental learning (Grau et al., 1998), as indicated by spinally transected rats’ ability to exhibit an increase in hind limb flexion duration when limb extension is associated with shock (controllable shock). If limb extension is not associated with shock (uncontrollable shock), a learning deficit develops. Recent research indicates that other forms of plasticity, such as long-term potentiation and central sensitization, do not depend on neural activity alone, but also on glial cells. I examined whether glial cells are also necessary in spinal instrumental learning and the learning deficit. Therefore, two glial inhibitors were selected: minocycline and fluorocitrate. To examine the role of glial cells in spinal instrumental learning, rats received intrathecal minocycline, fluorocitrate, or saline prior to testing with 30-minutes of controllable leg-shock. Results indicate that both drugs dose-dependently reduced acquisition, with higher doses resulting in shorter response durations. Once the response was acquired, fluorocitrate did not alter response maintenance. This suggests that glial cells are involved in the acquisition, but not the maintenance, of spinal learning. To examine the role of glial cells in the spinal learning deficit rats were given intrathecal minocycline, fluorocitrate, or saline prior to testing with 6-minutes of uncontrollable tail shock or no shock. Twenty-four hours later all rats were tested with 30-minutes of controllable leg-shock. Results indicated the learning deficit induced by uncontrollable shock was prevented by prior administration of fluorocitrate. Minocycline did not prevent the deficit; moreover, it appears that even in the absence of shock, minocycline caused a learning deficit. Overall, this data indicate that glial cells are necessary for the acquisition of spinal instrumental learning and the learning deficit. Furthermore, it provides further evidence for the role of glial cells in plasticity.

glia

plasticity

spinal instrumental learning

fluorocitrate

minocycline

Effects of Hyperthermia and Subsequent Minocycline Treatment in Acute Ischemic Stroke

Rahman, Shakib Hafizur

Unknown Date

No description available.

stroke

hyperthermia

matrix metalloprotease

minocycline

laminin

ischemia

Minocycline for acute stroke treatment: a systematic review and meta-analysis of randomized clinical trials

Malhotra, Konark, Chang, Jason J., Khunger, Arjun, Blacker, David, Switzer, Jeffrey A., Goyal, Nitin, Hernandez, Adrian V., Pasupuleti, Vinay, Alexandrov, Andrei V., Tsivgoulis, Georgios

08 1900

El texto completo de este trabajo no está disponible en el Repositorio Académico UPC por restricciones de la casa editorial donde ha sido publicado. / Background: Various randomized-controlled clinical trials (RCTs) have investigated the neuroprotective role of minocycline in acute ischemic stroke (AIS) or acute intracerebral hemorrhage (ICH) patients. We sought to consolidate and investigate the efficacy and safety of minocycline in patients with acute stroke. Methods: Literature search spanned through November 30, 2017 across major databases to identify all RCTs that reported following efficacy outcomes among acute stroke patients treated with minocycline vs. placebo: National Institute of Health Stroke Scale (NIHSS), Barthel Index (BI), and modified Rankin Scale (mRS) scores. Additional safety, neuroimaging and biochemical endpoints were extracted. We pooled mean differences (MD) and risk ratios (RR) from RCTs using random-effects models. Results: We identified 7 RCTs comprising a total of 426 patients. Of these, additional unpublished data was obtained on contacting corresponding authors of 5 RCTs. In pooled analysis, minocycline demonstrated a favorable trend towards 3-month functional independence (mRS-scores of 0–2) (RR = 1.31; 95% CI 0.98–1.74, p = 0.06) and 3-month BI (MD = 6.92; 95% CI − 0.92, 14.75; p = 0.08). In AIS subgroup, minocycline was associated with higher rates of 3-month mRS-scores of 0–2 (RR = 1.59; 95% CI 1.19–2.12, p = 0.002; I2 = 58%) and 3-month BI (MD = 12.37; 95% CI 5.60, 19.14, p = 0.0003; I2 = 47%), whereas reduced the 3-month NIHSS (MD − 2.84; 95% CI − 5.55, − 0.13; p = 0.04; I2 = 86%). Minocycline administration was not associated with an increased risk of mortality, recurrent stroke, myocardial infarction and hemorrhagic conversion. Conclusions: Although data is limited, minocycline demonstrated efficacy and seems a promising neuroprotective agent in acute stroke patients, especially in AIS subgroup. Further RCTs are needed to evaluate the efficacy and safety of minocycline among ICH patients. / Revisión por pares / Revisión por pares

Intracerebral hemorrhage

Ischemic stroke

Minocycline

Recovery

Effects of Short-Term Minocycline Treatments on Inflammatory Cell Response in the Acute Stage Following TBI

Ayub, Henna

26 April 2013

Following traumatic brain injury (TBI), neuroinflammation contributes to the secondary injury. Microglia are the resident immune cells of the central nervous system (CNS), and when activated can exert either protective or detrimental effects on surrounding tissue. They are often segregated into subpopulations based on their type of activation, either pro- inflammatory (M1, classically activated), or anti-inflammatory (M2, alternatively activated). Minocycline, an anti-inflammatory drug, is known to be neuroprotective and to have effect on microglia. However, the effect of minocycline on subpopulations of inflammatory cells in the acute stage following injury is unclear. It is also unclear whether minocycline has a different treatment effect on injury-induced inflammatory responses in young and aged populations. In this study, we compared the effect of minocycline treatments on the microglial markers and the M2 subtype in both young (3-month-old) and aged (20-month-old) rats, sacrificed at three days after a moderate controlled cortical impact (CCI) injury. Minocycline treatments were either given beginning at 30 minutes post-injury or 4 hours post-injury for three days. Inflammatory cell markers ED1, OX6, and Iba1, as well as Arginase 1, a marker for alternatively activated macrophages/microglia, were used to label inflammatory cells. Staining intensity of each marker was analyzed in both the peri-lesion cortical tissue and the ipsilateral hippocampus regions. Our findings have found that 3-day minocycline treatment significantly attenuated TBI- induced inflammatory cell response especially in the aged rats. Minocycline treatment did not show any significant changes in the prevalence of the M2 phenotype. Our findings suggest that minocycline may exert its anti-inflammatory effect mostly on inhibition of M1 phenotype rather than promoting M2 phenotype.

TBI

Minocycline

Anatomy

Medicine and Health Sciences

Nervous System

Targeting inflammation and neurogenesis in an animal model of small-vessel stroke

Hua, Rui

03 July 2007

Therapeutic strategies of stroke can take two directions: to prevent brain damage from stroke or aid in its repair after a stroke. In this thesis, a rat stroke model, which mimics the human small vessel stroke, was used. Two potential repair strategies were investigated with this model, reduction of inflammatory processes with the aid of minocycline treatment and replacing necrotic neurons with new ones with the aid of neurogenesis of endogenous progenitor cells. <p>The stroke model is induced by disrupting the medium-size pial vessels within a 5mm-circular brain surface of adult Wistar rats. This leads to a cone-shaped cortical lesion. Therefore it mimics the clinical situation of lacunar infarction, the most frequent outcome of small vessel stroke. <p>Minocycline, a second-generation tetracycline, prevented cavitation and facilitated the repopulation of the lesion by reactive astrocytes. However, I could not identify the molecular target as the number of activated microglia, infiltrating leukocytes and CD3+ lymphocytes as well as interleukin-1β expression were not significantly altered. Doublecortin (DCX) is a microtubule-associated protein expressed by migrating neuroblasts and immature neurons. After injury, DCX-positive cells appeared in the neocortex at the base of the lesion. These cells exhibit a morphology resembling differentiated post-migratory neurons with long branched processes. Some of the DCX-positive cells were also immunoreactive for βIII-tubulin, another marker of immature neurons. This might indicate a migratory pathway for developing neuroblasts from the subventricular zone (SVZ) through the corpus callosum to the lesion. SVZ cells were labeled with carboxyfluorescein diacetate, succinimidyl ester (CFSE) stereotaxical injections. Although rostral migratory stream and olfactory bulb were intensely labeled, no CFSE containing cells were found in the cortex underneath the lesion. These results suggest that the DCX-positive cells may not originate from neural precursors from the SVZ, but might be generated from local progenitor cells. In summary, using the PVD II model, which mimics the lacunar stroke, I found that neuroblasts appeared spontaneously near the lesion in the cerebral cortex and were attempting to upregulate neuronal properties. Reducing inflammation with post-stroke minocycline treatment prevented cavitation. I think both findings open up exciting new avenues for treatment of lacunar infarctions.

minocycline

neuroblasts

reactive gliosis

cavitation

focal ischemia

doublecortin

Anatomical specificity of acidic saline model of chronic pain and the role of glia

Jasper, Lisa

27 September 2007

Research into the mechanisms of hyperalgesia is ongoing with the goal of improving clinical management of chronic pain. One animal model of chronic musculoskeletal pain uses two injections of acidic saline into a lateral gastrocnemius muscle to induce a long-lasting bilateral decrease in paw withdrawal thresholds. This study tested whether the two injections need to occur in the same muscle. Male Sprague-Dawley rats were injected with acidic saline (pH 4.0) in either the lateral or medial head of gastrocnemius or the contralateral gastrocnemius (lateral head). All animals received a second injection in the ipsilateral gastrocnemius (lateral head). Mechanical withdrawal thresholds were reduced in all groups when tested 24 hours after the second injection. Animals in which the first muscle injection was substituted with a non-specific treatment (intraperitoneal injection of lipopolysaccharide) developed bilateral hyperalgesia after a single acidic saline injection. Thus, the mechanism of hyperalgesia in this model is not restricted to the injected tissues and may include central nervous system structures. Consistent with this, an inhibitor of glia cell activation (minocycline) blocked the development of bilateral hyperalgesia. These data indicate that the central nervous system may play a large role in mediating chronic musculoskeletal pain. / October 2007

hyperalgesia

allodynia

muscle

pain

glia

minocycline

von frey

Targeting inflammation and neurogenesis in an animal model of small-vessel stroke

Hua, Rui

03 July 2007

Therapeutic strategies of stroke can take two directions: to prevent brain damage from stroke or aid in its repair after a stroke. In this thesis, a rat stroke model, which mimics the human small vessel stroke, was used. Two potential repair strategies were investigated with this model, reduction of inflammatory processes with the aid of minocycline treatment and replacing necrotic neurons with new ones with the aid of neurogenesis of endogenous progenitor cells. <p>The stroke model is induced by disrupting the medium-size pial vessels within a 5mm-circular brain surface of adult Wistar rats. This leads to a cone-shaped cortical lesion. Therefore it mimics the clinical situation of lacunar infarction, the most frequent outcome of small vessel stroke. <p>Minocycline, a second-generation tetracycline, prevented cavitation and facilitated the repopulation of the lesion by reactive astrocytes. However, I could not identify the molecular target as the number of activated microglia, infiltrating leukocytes and CD3+ lymphocytes as well as interleukin-1β expression were not significantly altered. Doublecortin (DCX) is a microtubule-associated protein expressed by migrating neuroblasts and immature neurons. After injury, DCX-positive cells appeared in the neocortex at the base of the lesion. These cells exhibit a morphology resembling differentiated post-migratory neurons with long branched processes. Some of the DCX-positive cells were also immunoreactive for βIII-tubulin, another marker of immature neurons. This might indicate a migratory pathway for developing neuroblasts from the subventricular zone (SVZ) through the corpus callosum to the lesion. SVZ cells were labeled with carboxyfluorescein diacetate, succinimidyl ester (CFSE) stereotaxical injections. Although rostral migratory stream and olfactory bulb were intensely labeled, no CFSE containing cells were found in the cortex underneath the lesion. These results suggest that the DCX-positive cells may not originate from neural precursors from the SVZ, but might be generated from local progenitor cells. In summary, using the PVD II model, which mimics the lacunar stroke, I found that neuroblasts appeared spontaneously near the lesion in the cerebral cortex and were attempting to upregulate neuronal properties. Reducing inflammation with post-stroke minocycline treatment prevented cavitation. I think both findings open up exciting new avenues for treatment of lacunar infarctions.

minocycline

neuroblasts

reactive gliosis

cavitation

focal ischemia

doublecortin

Minocycline Treatment and the Necessity to Develop a Novel Outcome Measure for Children with Angelman Syndrome

Grieco, Joseph Christopher

01 January 2015

Angelman syndrome (AS) is a rare genetic disorder affecting 1/10,000 to 1/20,000 births. This disorder arises through the genetic disruption of the maternal UBE3A allele, which when coupled with epigenetic silencing of the paternal allele UBE3A allele, gives rise to an absence of UBE3A protein in the central nervous system. Clinical manifestations of the syndrome vary in severity and include poor motor function, deficits in language and severe intellectual impairments. Previous research in the Angelman syndrome mouse model revealed abnormalities in dendritic spine density and morphology of hippocampal pyramidal cells. As seen in humans with AS, mice show abnormal behavioral characteristics that include deficits in motor coordination and ability as well as hippocampal dependent associative fear conditioning. Physiologically, these animals exhibit severe deficits in long-term potentiation (LTP) when compared to wildtype littermates. In an attempt to reduce the time from laboratory study to human translation, we began to search a small molecule library for established compounds with the ability to improve the behavioral and physiological defects normally associated with the AS mouse. One compound, minocycline, was found to normalize the density of dendritic spines in the hippocampus as well as recover the associative memory of AS mice. Moreover, a significant increase in LTP after theta-burst stimulation was also observed in area CA1 hippocampal pyramidal neurons of AS mice treated with minocycline when compared to saline vehicle control mice. These results suggest treatment with minocycline improves synaptic function and learning and memory of AS mice and may provide similar improvements to patients with Angelman syndrome. Twenty-five participants ages 4-12 were enrolled in a clinical trial examining the safety and tolerability of minocycline in children with Angelman syndrome. Patients were evaluated at 3 time points, baseline (T1), after 8 weeks of treatment (T2) and again 8 weeks after the drug was discontinued (T3). Each evaluation was identical and included laboratory testing, EEG recording and neuropsychological examination. Results of the study showed minocycline was safe and well tolerated with only minor adverse effects reported. While no change was observed in EEG recordings, significant increases in the mean clinical global impressions severity scale score were observed after treatment with minocycline. Moreover, participants showed significant improvement in the raw scores of the communication and self-care domains of the Bayley Scale of Infant and Toddler Development, 3rd Edition. These results show for the first time, a therapeutic with the ability to improve the characteristic behaviors of Angelman syndrome. Unfortunately, currently available neuropsychological measures were found to be insensitive to the behavioral phenotype of AS. The primary outcome measure, the Bayley Scale of Infant and Toddler Development, 3rd Edition relies on verbal communication and for the examinee to perform specific tasks on command. These testing methods are not compatible with this patient population and resulted in raw scores outside of 2 standard deviations from the mean. The inability of the participants to perform on these exams led us to develop a novel outcome measure; one that relies on observation rather than verbal communication. 9 children with AS and 7 healthy children were enrolled in an observational study in which 30 minutes of free play activity was video recorded. Using behavioral coding software, 3 independent raters quantified stereotypical AS behaviors as well as communication methods. Speech attempts were categorized into five difference types of vocalizations and revealed children with AS used less advance forms of vocalization consisting mostly of phonation control. Phonetic inventories show mostly front or back vowel usage suggesting little tongue movement occurs during speech production. These results suggest deficits in verbal ability may be related to a childhood apraxia of speech. Impairments in balance and motor coordination have been associated with AS. In an attempt to measure gross motor function, spatiotemporal gait parameters were collected using an electronic walkway and gait analysis software. Results show the gait of children with AS most resembles that of patients with ataxia but without cognitive impairment. In an attempt to develop a single quantitative measure able to describe the severity of gait-related disability, statistical methods were used to create a gait index for patients with AS. The results of this study provides AS researchers with the tools necessary to accurately measure changes in behavior and gait during the clinical evaluation of potential therapeutics

Angelman

Ataxia

Autism

Imprinting

Minocycline

Tetracycline

Molecular Biology

Neurosciences

Physiology

Anatomical specificity of acidic saline model of chronic pain and the role of glia

Jasper, Lisa

27 September 2007

Research into the mechanisms of hyperalgesia is ongoing with the goal of improving clinical management of chronic pain. One animal model of chronic musculoskeletal pain uses two injections of acidic saline into a lateral gastrocnemius muscle to induce a long-lasting bilateral decrease in paw withdrawal thresholds. This study tested whether the two injections need to occur in the same muscle. Male Sprague-Dawley rats were injected with acidic saline (pH 4.0) in either the lateral or medial head of gastrocnemius or the contralateral gastrocnemius (lateral head). All animals received a second injection in the ipsilateral gastrocnemius (lateral head). Mechanical withdrawal thresholds were reduced in all groups when tested 24 hours after the second injection. Animals in which the first muscle injection was substituted with a non-specific treatment (intraperitoneal injection of lipopolysaccharide) developed bilateral hyperalgesia after a single acidic saline injection. Thus, the mechanism of hyperalgesia in this model is not restricted to the injected tissues and may include central nervous system structures. Consistent with this, an inhibitor of glia cell activation (minocycline) blocked the development of bilateral hyperalgesia. These data indicate that the central nervous system may play a large role in mediating chronic musculoskeletal pain.

hyperalgesia

allodynia

muscle

pain

glia

minocycline

von frey

Anatomical specificity of acidic saline model of chronic pain and the role of glia

Jasper, Lisa

27 September 2007

Research into the mechanisms of hyperalgesia is ongoing with the goal of improving clinical management of chronic pain. One animal model of chronic musculoskeletal pain uses two injections of acidic saline into a lateral gastrocnemius muscle to induce a long-lasting bilateral decrease in paw withdrawal thresholds. This study tested whether the two injections need to occur in the same muscle. Male Sprague-Dawley rats were injected with acidic saline (pH 4.0) in either the lateral or medial head of gastrocnemius or the contralateral gastrocnemius (lateral head). All animals received a second injection in the ipsilateral gastrocnemius (lateral head). Mechanical withdrawal thresholds were reduced in all groups when tested 24 hours after the second injection. Animals in which the first muscle injection was substituted with a non-specific treatment (intraperitoneal injection of lipopolysaccharide) developed bilateral hyperalgesia after a single acidic saline injection. Thus, the mechanism of hyperalgesia in this model is not restricted to the injected tissues and may include central nervous system structures. Consistent with this, an inhibitor of glia cell activation (minocycline) blocked the development of bilateral hyperalgesia. These data indicate that the central nervous system may play a large role in mediating chronic musculoskeletal pain.

hyperalgesia

allodynia

muscle

pain

glia

minocycline

von frey