Kensuke Orito

Delayed Treatment With Minocycline Ameliorates Neurologic Impairment Through Activated Microglia Expressing a High-Mobility Group Box1–Inhibiting Mechanism

Background and Purpose— Minocycline, a semisynthetic tetracycline antibiotic, has been reported to ameliorate brain injury and inhibit microglial activation after focal cerebral ischemia. However, the cerebroprotective mechanism of minocycline remains unclear. In the present study, we investigated that mechanism of minocycline in a murine model of 4-hour middle cerebral artery (MCA) occlusion. Methods— One day after 4-hour MCA occlusion, minocycline was administered intraperitoneally for 14 days. Neurologic scores were measured 1, 7, and 14 days after cerebral ischemia. Motor coordination was evaluated at 14 days by the rota-rod test at 10 rpm. Activated microglia and high-mobility group box1 (HMGB1), a cytokine-like mediator, were also evaluated by immunostaining and Western blotting. In addition, terminal deoxynucleotidyl transferase–mediated dUTP nick end-labeling immunostaining was carried out 14 days after cerebral ischemia. Results— Repeated treatment with minocycline (1, 5, and 10 mg/kg) for 14 days improved neurologic score, motor coordination on the rota-rod test, and survival in a dose-dependent manner. Minocycline decreased the expression of Iba1, a marker of activated microglia, as assessed by both immunostaining and Western blotting. Moreover, minocycline decreased the activation of microglia expressing HMGB1 within the brain and also decreased both brain and plasma HMGB1 levels. Additionally, minocycline significantly decreased the number of terminal deoxynucleotidyl transferase–mediated dUTP nick end-labeling–positive cells and prevented ischemic brain atrophy 14 days after cerebral ischemia. Conclusions— Our results suggest that minocycline inhibits activated microglia expressing HMGB1 and decreases neurologic impairment induced by cerebral ischemia. Minocycline will have a palliative action and open new therapeutic possibilities for treatment of postischemic injury via an HMGB1-inhibiting mechanism.

Inhibition of Reactive Astrocytes with Fluorocitrate Retards Neurovascular Remodeling and Recovery after Focal Cerebral Ischemia in Mice

Glial scarring is traditionally thought to be detrimental after stroke. But emerging studies now suggest that reactive astrocytes may also contribute to neurovascular remodeling. Here, we assessed the effects and mechanisms of metabolic inhibition of reactive astrocytes in a mouse model of stroke recovery. Five days after stroke onset, astrocytes were metabolically inhibited with fluorocitrate (FC, 1 nmol). Markers of reactive astrocytes (glial fibrillary acidic protein (GFAP), HMGB1), markers of neurovascular remodeling (CD31, synaptophysin, PSD95), and behavioral outcomes (neuroscore, rotarod latency) were quantified from 1 to 14 days. As expected, focal cerebral ischemia induced significant neurological deficits in mice. But over the course of 14 days after stroke onset, a steady improvement in neuroscore and rotarod latencies were observed as the mice spontaneously recovered. Reactive astrocytes coexpressing GFAP and HMGB1 increased in peri-infarct cortex from 1 to 14 days after cerebral ischemia in parallel with an increase in the neurovascular remodeling markers CD31, synaptophysin, and PSD95. Compared with stroke-only controls, FC-treated mice demonstrated a significant decrease in HMGB1-positive reactive astrocytes and neurovascular remodeling, as well as a corresponding worsening of behavioral recovery. Our results suggest that reactive astrocytes in peri-infarct cortex may promote neurovascular remodeling, and these glial responses may aid functional recovery after stroke.

Cannabidiol potentiates pharmacological effects of Δ9-tetrahydrocannabinol via CB1 receptor-dependent mechanism

Cannabidiol, a non-psychoactive component of cannabis, has been reported to have interactions with Delta(9)-tetrahydrocannabinol (Delta(9)-THC). However, such interactions have not sufficiently been clear and may have important implications for understanding the pharmacological effects of marijuana. In the present study, we investigated whether cannabidiol modulates the pharmacological effects of Delta(9)-THC on locomotor activity, catalepsy-like immobilisation, rectal temperature and spatial memory in the eight-arm radial maze task in mice. In addition, we measured expression level of cannabinoid CB(1) receptor at striatum, cortex, hippocampus and hypothalamus. Delta(9)-THC (1, 3, 6 and 10 mg/kg) induced hypoactivity, catalepsy-like immobilisation and hypothermia in a dose-dependent manner. In addition, Delta(9)-THC (1, 3 and 6 mg/kg) dose-dependently impaired spatial memory in eight-arm radial maze. On the other hand, cannabidiol (1, 3, 10, 25 and 50 mg/kg) did not affect locomotor activity, catalepsy-like immobilisation, rectal temperature and spatial memory on its own. However, higher dose of cannabidiol (10 or 50 mg/kg) exacerbated pharmacological effects of lower dose of Delta(9)-THC, such as hypoactivity, hypothermia and impairment of spatial memory. Moreover, cannabidiol (50 mg/kg) with Delta(9)-THC (1 mg/kg) enhanced the expression level of CB(1) receptor expression in hippocampus and hypothalamus. Cannabidiol potentiated pharmacological effects of Delta(9)-THC via CB(1) receptor-dependent mechanism. These findings may contribute in setting the basis for interaction of cannabinoids and to find a cannabinoid mechanism in central nervous system.

Cannabidiol prevents a post-ischemic injury progressively induced by cerebral ischemia via a high-mobility group box1-inhibiting mechanism.

We examined the cerebroprotective mechanism of cannabidiol, the non-psychoactive component of marijuana, against infarction in a 4-h mouse middle cerebral artery (MCA) occlusion model. Cannabidiol was intraperitoneally administrated immediately before and 3h after cerebral ischemia. Infarct size and myeloperoxidase (MPO) activity, a marker of neutrophil, monocyte/macropharge, were measured at 24h after cerebral ischemia. Activated microglia and astrocytes were evaluated by immunostaining. Moreover, high-mobility group box1 (HMGB1) was also evaluated at 1 and 3 days after MCA occlusion. In addition, neurological score and motor coordination on the rota-rod test were assessed at 1 and 3 days after cerebral ischemia. Cannabidiol significantly prevented infarction and MPO activity at 20h after reperfusion. These effects of cannabidiol were not inhibited by either SR141716 or AM630. Cannabidiol inhibited the MPO-positive cells expressing HMGB1 and also decreased the expression level of HMGB1 in plasma. In addition, cannabidiol decreased the number of Iba1- and GFAP-positive cells at 3 days after cerebral ischemia. Moreover, cannabidiol improved neurological score and motor coordination on the rota-rod test. Our results suggest that cannabidiol inhibits monocyte/macropharge expressing HMGB1 followed by preventing glial activation and neurological impairment induced by cerebral ischemia. Cannabidiol will open new therapeutic possibilities for post-ischemic injury via HMGB1-inhibiting mechanism.

Delayed treatment with cannabidiol has a cerebroprotective action via a cannabinoid receptor-independent myeloperoxidase- inhibiting mechanism

We examined the neuroprotective mechanism of cannabidiol, non‐psychoactive component of marijuana, on the infarction in a 4 h mouse middle cerebral artery (MCA) occlusion model in comparison with Δ9‐tetrahydrocannabinol (Δ9‐THC). Release of glutamate in the cortex was measured at 2 h after MCA occlusion. Myeloperoxidase (MPO) and cerebral blood flow were measured at 1 h after reperfusion. In addition, infarct size and MPO were determined at 24 and 72 h after MCA occlusion. The neuroprotective effect of cannabidiol was not inhibited by either SR141716 or AM630. Both pre‐ and post‐ischemic treatment with cannabidiol resulted in potent and long‐lasting neuroprotection, whereas only pre‐ischemic treatment with Δ9‐THC reduced the infarction. Unlike Δ9‐THC, cannabidiol did not affect the excess release of glutamate in the cortex after occlusion. Cannabidiol suppressed the decrease in cerebral blood flow by the failure of cerebral microcirculation after reperfusion and inhibited MPO activity in neutrophils. Furthermore, the number of MPO‐immunopositive cells was reduced in the ipsilateral hemisphere in cannabidiol‐treated group. Cannbidiol provides potent and long‐lasting neuroprotection through an anti‐inflammatory CB1 receptor‐independent mechanism, suggesting that cannabidiol will have a palliative action and open new therapeutic possibilities for treating cerebrovascular disorders.

Δ9-Tetrahydrocannabinol-induced catalepsy-like immobilization is mediated by decreased 5-HT neurotransmission in the nucleus accumbens due to the action of glutamate-containing neurons

Delta(9)-tetrahydrocannabinol (THC) has been reported to induce catalepsy-like immobilization, but the mechanism underlying this effect remains unclear. In the present study, in order to fully understand the neural circuits involved, we determined the brain sites involved in the immobilization effect in rats. THC dose-dependently induced catalepsy-like immobilization. THC-induced catalepsy-like immobilization is mechanistically different from that induced by haloperidol (HPD), because unlike HPD-induced catalepsy, animals with THC-induced catalepsy became normal again following sound and air-puff stimuli. THC-induced catalepsy was reversed by SR141716, a selective cannabinoid CB(1) receptor antagonist. Moreover, THC-induced catalepsy was abolished by lesions in the nucleus accumbens (NAc) and central amygdala (ACE) regions. On the other hand, HPD-induced catalepsy was suppressed by lesions in the caudate putamen (CP), substantia nigra (SN), globus pallidus (GP), ACE and lateral hypothalamus (LH) regions. Bilateral microinjection of THC into the NAc region induced catalepsy-like immobilization. This THC-induced catalepsy was inhibited by serotonergic drugs such as 5-hydroxy-L-tryptophan (5-HTP), a 5-HT precursor, and 5-methoxy-N,N-dimethyltryptamine (5-MeODMT), a 5-HT receptor agonist, as well as by anti-glutamatergic drugs such as MK-801 and amantadine, an N-methyl-d-aspartate (NMDA) receptor antagonist. THC significantly decreased 5-HT and glutamate release in the NAc, as shown by in vivo microdialysis. SR141716 reversed and MK-801 inhibited this decrease in 5-HT and glutamate release. These findings suggest that the THC-induced catalepsy is mechanistically different from HPD-induced catalepsy and that the catalepsy-like immobilization induced by THC is mediated by decreased 5-HT neurotransmission in the nucleus accumbens due to the action of glutamate-containing neurons.

Cardiovascular Profile of Ro 40–5967, a New Nondihydropyridine Calcium Antagonist, Delineated in Isolated, Blood-Perfused Dog Hearts

Summary: Coronary and cardiac effects of Ro 40–5967 were compared in isolated, blood-perfused dog heart preparations. Intraarterial Ro 40–5967 increased blood flow in all preparations. In sinoatrial preparations, Ro 40–5967 decreased sinus rate and produced atrial standstill when administered at high doses. In paced atrioventricular (AV) node preparations, Ro 40–5967 injected into the posterior septal artery (which perfuses the AV node) increased AV conduction time and at high doses produced second- or third-degree AV block. In the same preparations, Ro 40–5967 had little effect on AV conduction time, even at higher doses, when injected into the anterior septal artery (which perfuses the His-Purkinje ventricular system). In paced papillary muscle preparations, Ro 40–5967 reduced the force of contraction only at high doses. In spontaneously beating papillary muscle preparations, Ro 40–5967 decreased the force of contraction only at high doses and had no effect on the rate of automaticity even at higher doses. The dose that doubled blood flow was about one-fifth of the dose that produced a 15% decrease in sinus rate and also one-fifth of the dose that produced a 15% increase in AV conduction time. The dose that reduced the force of contraction by half was >10 times the dose that doubled blood flow. The results indicate that the cardiovascular profile of Ro 40–5967 differs from those of verapamil and diltiazem but instead resembles that of dihydropyridine derivatives, which are classified as vasoselective calcium antagonists.

A new analytical system for quantification scratching behaviour in mice

Background  Scratching behaviour is an important component of human atopic dermatitis. The duration of scratching determines the extent of skin damage and thus the rash, but quantification of this is difficult. Establishment of a method for measuring the duration of scratching is important in order to make objective assessments of the factors that may cause the itch and also the efficacy of new antipruritic drugs.

Pharmacokinetics of zonisamide and drug interaction with phenobarbital in dogs.

The purposes of the present study were to elucidate the pharmacokinetics of zonisamide, determine the presence of a drug interaction with phenobarbital, and evaluate how long any interaction lasted after discontinuation of phenobarbital in dogs. Five dogs received zonisamide (5 mg/kg, p.o. and i.v.) before and during repeated oral administration of phenobarbital (5 mg/kg, bid, for 30-35 days). Zonisamide (5 mg/kg, p.o.) was also administered 8, 10, and 12 weeks after discontinuation of phenobarbital. Blood was sampled until 24 h after each zonisamide administration and serum concentrations of zonisamide were determined. Repeated phenobarbital decreased the maximum serum concentration, area under the serum concentration vs. time curve, apparent elimination half-life, and bioavailability of zonisamide. Total clearance increased. Time to maximum serum concentration and volume distribution were not changed. The maximum serum concentration and area under the serum concentration vs. time curve of zonisamide continued to be low until 10 weeks after the discontinuation of phenobarbital. They were restored to the same serum concentration as before phenobarbital administration 12 weeks after the discontinuation of phenobarbital. These data suggested that repeated administration of a clinical dose of phenobarbital enhanced the clearance of zonisamide and the enhanced clearance lasted at least 10 weeks after the discontinuation of phenobarbital. Caution may be necessary when zonisamide is given with phenobarbital and when antiepileptic therapy is changed from phenobarbital to zonisamide.

Automatic Scratching Pattern Detection for Laboratory Mice Using High-Speed Video Images

Quantifying the rapid action of a mouse scratching its head with its hind leg can provide an objective behavioral indicator for atopic dermatitis, and the development of new drugs for this disease can be significantly expedited by automating such quantification. In this paper, we propose methods for extracting the scratching patterns of a mouse by focusing on its rapid and periodic behavioral patterns. We extracted the scratching patterns from the high-speed video images of actual laboratory mice, and our experimental results show that scratching can be automatically quantified without misinterpretations. Note to Practitioners - The proposed pattern detection method is completely free from the detection of false behaviors caused by markers painted on their skins. Therefore, practitioners in laboratory experiments can also easily apply it to other periodic behavior analyses, such as gait pattern analysis and tremble detection for automated quantitative evaluations of behaviors related to brain, heart, or other diseases, even if the experimented animals are sensitive to painting.