1.A Rat Model of Striatonigral Degeneration Generated by Simultaneous Injection of 6-Hydroxydopamine into the Medial Forebrain Bundle and Quinolinic Acid into the Striatum.
Hyung Ho YOON ; Yong Hwan KIM ; Eun Sil SHIN ; Sang Ryong JEON
Journal of Korean Medical Science 2014;29(11):1555-1561
A double toxin-double lesion strategy is well-known to generate a rat model of striatonigral degeneration (SND) such as multiple system atrophy-parkinsonian type. However, with this model it is difficult to distinguish SND from Parkinson's disease (PD). In this study, we propose a new rat model of SND, which is generated by simultaneous injection of 6-hydroxydopamine into the medial forebrain bundle and quinolinic acid into the striatum. Stepping tests performed 30 min after intraperitoneal L-dopa administration at 6 weeks post-surgery revealed an L-dopa response in the PD group but not the SND group. Apomorphine-induced rotation tests revealed no rotational bias in the SND group, which persisted for 2 months, but contralateral rotations in the PD group. MicroPET scans revealed glucose hypometabolism and dopamine transporter impairment on the lesioned striatum in the SND group. Tyrosine hydroxylase immunostaining in the SND group revealed that 74.7% of nigral cells on the lesioned side were lost after lesion surgery. These results suggest that the proposed simultaneous double toxin-double lesion method successfully created a rat model of SND that had behavioral outcomes, multitracer microPET evaluation, and histological aspects consistent with SND pathology. This model will be useful for future study of SND.
Animals
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Apomorphine/pharmacology
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Behavior, Animal/drug effects
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Corpus Striatum/drug effects/pathology
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Disease Models, Animal
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Dopamine Plasma Membrane Transport Proteins/metabolism
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Glucose/metabolism
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Injections, Intraperitoneal
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Levodopa/pharmacology
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Male
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Medial Forebrain Bundle/drug effects/pathology
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Oxidopamine/*toxicity
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Parkinson Disease/metabolism/pathology
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Positron-Emission Tomography
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Quinolinic Acid/*toxicity
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Rats
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Rats, Wistar
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Striatonigral Degeneration/*chemically induced/metabolism/pathology
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Touch/drug effects
2.Kir2.1 Channel Regulation of Glycinergic Transmission Selectively Contributes to Dynamic Mechanical Allodynia in a Mouse Model of Spared Nerve Injury.
Yiqian SHI ; Yangyang CHEN ; Yun WANG
Neuroscience Bulletin 2019;35(2):301-314
Neuropathic pain is a chronic debilitating symptom characterized by spontaneous pain and mechanical allodynia. It occurs in distinct forms, including brush-evoked dynamic and filament-evoked punctate mechanical allodynia. Potassium channel 2.1 (Kir2.1), which exhibits strong inward rectification, is and regulates the activity of lamina I projection neurons. However, the relationship between Kir2.1 channels and mechanical allodynia is still unclear. In this study, we first found that pretreatment with ML133, a selective Kir2.1 inhibitor, by intrathecal administration, preferentially inhibited dynamic, but not punctate, allodynia in mice with spared nerve injury (SNI). Intrathecal injection of low doses of strychnine, a glycine receptor inhibitor, selectively induced dynamic, but not punctate allodynia, not only in naïve but also in ML133-pretreated mice. In contrast, bicuculline, a GABA receptor antagonist, induced only punctate, but not dynamic, allodynia. These results indicated the involvement of glycinergic transmission in the development of dynamic allodynia. We further found that SNI significantly suppressed the frequency, but not the amplitude, of the glycinergic spontaneous inhibitory postsynaptic currents (gly-sIPSCs) in neurons on the lamina II-III border of the spinal dorsal horn, and pretreatment with ML133 prevented the SNI-induced gly-sIPSC reduction. Furthermore, 5 days after SNI, ML133, either by intrathecal administration or acute bath perfusion, and strychnine sensitively reversed the SNI-induced dynamic, but not punctate, allodynia and the gly-sIPSC reduction in lamina IIi neurons, respectively. In conclusion, our results suggest that blockade of Kir2.1 channels in the spinal dorsal horn selectively inhibits dynamic, but not punctate, mechanical allodynia by enhancing glycinergic inhibitory transmission.
Animals
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Bicuculline
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pharmacology
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Disease Models, Animal
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Glycine
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metabolism
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Hyperalgesia
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drug therapy
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etiology
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metabolism
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Imidazoles
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pharmacology
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Inhibitory Postsynaptic Potentials
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drug effects
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physiology
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Male
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Mice, Inbred C57BL
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Neurons
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drug effects
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metabolism
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Neurotransmitter Agents
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pharmacology
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Peripheral Nerve Injuries
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drug therapy
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metabolism
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Phenanthrolines
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pharmacology
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Potassium Channels, Inwardly Rectifying
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antagonists & inhibitors
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metabolism
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Receptors, GABA-A
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metabolism
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Receptors, Glycine
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metabolism
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Strychnine
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pharmacology
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Synaptic Transmission
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drug effects
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physiology
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Tissue Culture Techniques
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Touch