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    • 68516小图
    • 68507小图
    • 68510小图
    • 68513小图
    • 68516小图
    • 68516小图
    • 68507小图
    • 68510小图
    • 68513小图
    • 68516小图

    Portable Stereotaxic Instrument for Mouse

    • The portable stereotaxic instrument cancels the traditional U-shaped frame, and the operation space is larger. This type is specially designed for mouse. The height of the nose bar and ear bars can be adjusted from 0-20mm, which is convenient for adjusting the level of the skull. The accuracy of non-digital models is 100 μm, and the accuracy of digital models is 10 μm.
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    Technical Specifications

    • Key Benefits
    • Technical Specifications
    • Order Information
    • Specific fixed base ( 255mm x 255mm) for mice, fixed more quickly.
    • Replace the U-frame, enlarge the operating space, more economical and reliable.
    • Unique UP indicator to prevent incorrect operation..
    • Double-lead screw design, more stable and accurate operation.
    • The ear bar is made of polyoxymethylene resin, 4 different fixed points with 1mm resolution for scales.

    1. Base plate size : 255mm x 255mm.

    2. Ear bars made of polyoxymethlene resin, unique and light.

    3. Height adjustment range for palate clip: 20mm (0mm~+20mm).

    4. Height adjustment range for ear bars: 20mm(0~+20mm).

    5. Ear bars with laser engraved scales (1mm resolution).

    6. Working distance in 3 dimension is 80 mm with precise alignment to 0.1mm resolution.

    7. Vertical direction: 180° rotation and lock at any angles.

    8. Horizontal direction: 360° rotation and lock at any angles.

    9. Dual-lead screws ensure stable, accurate and smooth manipulation.

    10. Accuracy and flexibility can be maintained at variable temperatures.

    11. Unique anti-clockwise UP mark engraved in the knob prevents incorrect operation.

    12. Vertical lock and fixing knob are separated to ensure accurate function at any angle.

    13. Replace the U-frame, enlarge the operating space, more economical and reliable

    14. Laser engraved scales enable comfortable reading.

    15. Ear bar locked plate pressing instead of clamping ensures more stability.

    16. Syringe pump, micro camera and drill can be attached to instruments.

    Category Model Product Description Remark
    Stereotaxic host
    (without accessories)    		 68805 Portable Mouse Stereotaxic Instrument, SGL M Standard configuration, non-digital model (accuracy is 100μm), including 68863S base, 68401 3-axis manipulator-left, without nose bar, ear bars, holder and mask.
    68806 Portable Mouse Stereotaxic Instrument, Dual M Standard configuration, non-digital model (accuracy is 100μm), including 68863D base, 68401 3-axis manipulator-left, 68402 3-axis manipulator-right, without nose bar, ear bars, holder and mask.
    68807 Portable Mouse Stereotaxic Instrument, SGL M, Digital Standard configuration, digital model (accuracy is 10μm), including 68863S base, 68409 3-axis digital manipulator-left, without nose bar, ear bars, holder and mask.
    68808 Portable Mouse Stereotaxic Instrument, Dual M, Digital Standard configuration, digital model (accuracy is 10μm), including 68863D base, 68409 3-axis digital manipulator-left, 68410 3-axis digital manipulatorright, without nose bar, ear bars, holder and mask.
    Required accessories (optional)* 68033 Nose Bar for 68030 Mouse Adaptor Optional, the cross-sectional size of the nose bar is 5* 5mm.
    68313 45°Ear Bars for 68030 Mouse Adaptor Optional, including two tips of 45° and rubber, the cross-sectional size of the ear bars is 5*5mm.
    68034 18°Ear Bars for 68030 Mouse Adaptor Optional, including two tips of 18° and serrated, the cross-sectional size of the ear bars is 5*5mm.
    68201 Standard Probe Holder-Corner, clamping range: 0.3-1.5mm.
    68217 Cannula Holder, clamping diameter: 3.5mm. The clamping part is made of plastic.
    68205 Cannula Holder, clamping diameter: 3.5mm. The clamping part is made of metal.
    68214 Ceramic Ferrule Holder, clamping diameter: 1.25mm.
    68215 Ceramic Ferrule Holder, clamping diameter: 2.5mm.
    68206 General Probe Holder, clamping range: 3-12mm.
    68218 Syringe Holder, the syringe barrel clamping range is 6mm-12mm, and
    the syringe needle clamping range is 0.3mm-1.5mm.
    68605 Microdrill Holder, clamping diameter: 14.5mm. Suitable for 78001 microdrill.

    *Indicates that other specifications can be selected, which can be viewed from the product catalog of RWD.

    Articles

    1. Diao, Y., Cui, L., Chen, Y., Burbridge, T. J., Han, W., Wirth, B., … & Zhang, J. (2018). Reciprocal connections between cortex and thalamus contribute to retinal axon targeting to dorsal lateral geniculate nucleus. Cerebral Cortex, 28(4), 1168-1182.
    2. Fan, X. C., Fu, S., Liu, F. Y., Cui, S., Yi, M., & Wan, Y. (2018). Hypersensitivity of prelimbic cortex neurons contributes to aggravated nociceptive responses in rats with experience of chronic inflammatory pain. Frontiers in molecular neuroscience, 11, 85.
    3. Liu, Y., Lai, S., Ma, W., Ke, W., Zhang, C., Liu, S., … & Shu, Y. (2017). CDYL suppresses epileptogenesis in mice through repression of axonal Nav1. 6 sodium channel expression. Nature communications, 8(1), 1-17.
    4. Tang, Y., Lin, Y. H., Ni, H. Y., Dong, J., Yuan, H. J., Zhang, Y., … & Chang, L. (2017). Inhibiting Histone Deacetylase 2 (HDAC 2) Promotes Functional Recovery From Stroke. Journal of the American Heart Association, 6(10), e007236.
    5. Huang, L., Yuan, T., Tan, M., Xi, Y., Hu, Y., Tao, Q., … & Luo, M. (2017). A retinoraphe projection regulates serotonergic activity and looming-evoked defensive behaviour. Nature communications, 8(1), 1-13.
    6. Zhu, M., Li, H., Gyanwali, B., He, G., Qi, C., Yang, X., … & Tang, A. (2017). Auditory brainstem responses after electrolytic lesions in bilateral subdivisions of the medial geniculate body of tree shrews. Neurological Sciences, 38(9), 1617-1628.
    7. Lei, Z., Wang, D., Chen, N., Ma, K., Lu, W., Song, Z., … & Wang, J. H. (2017). Synapse innervation and associative memory cell are recruited for integrative storage of whisker and odor signals in the barrel cortex through miRNA-mediated processes. Frontiers in cellular neuroscience, 11, 316.
    8. Zhou, H., Xiong, G. J., Jing, L., Song, N. N., Pu, D. L., Tang, X., … & Richter-Levin, G. (2017). The interhemispheric CA1 circuit governs rapid generalisation but not fear memory. Nature communications, 8(1), 1-10.
    9. Zhang, J., Liu, H., Du, X., Guo, Y., Chen, X., Wang, S., … & Zhang, W. (2017). Increasing of blood-brain tumor barrier permeability through transcellular and paracellular pathways by microbubble-enhanced diagnostic ultrasound in a C6 glioma model. Frontiers in neuroscience, 11, 86.
    10. Li, G. F., Zhao, H. X., Zhou, H., Yan, F., Wang, J. Y., Xu, C. X., … & Zhang, H. L. (2016). Improved anatomical specificity of non-invasive neuro-stimulation by high frequency (5 MHz) ultrasound. Scientific reports, 6(1), 1-11.
    11. Liu, M. G., Li, H. S., Li, W. G., Wu, Y. J., Deng, S. N., Huang, C., … & Xu, T. L. (2016). Acid-sensing ion channel 1a contributes to hippocampal LTP inducibility through multiple mechanisms. Scientific reports, 6, 23350.
    12. Zhao, Baisong, et al. “Hyperbaric oxygen pretreatment improves cognition and reduces hippocampal damage via p38 mitogen-activated protein kinase in a rat model.” Yonsei medical journal 58.1 (2017): 131-138.
    13. Zhao, Yunan, et al. “Decreased glycogen content might contribute to chronic stress-induced atrophy of hippocampal astrocyte volume and depression-like behavior in rats.” Scientific reports 7 (2017): 43192.
    14. Espinosa, P., Silva, R. A., Sanguinetti, N. K., Venegas, F. C., Riquelme, R., González, L. F., … & Sotomayor-Zárate, R. (2016). Programming of dopaminergic neurons by neonatal sex hormone exposure: effects on dopamine content and tyrosine hydroxylase expression in adult male rats. Neural plasticity, 2016.
    15. Li, Wei-Guang, et al. “ASIC1a regulates insular long-term depression and is required for the extinction of conditioned taste aversion.” Nature communications 7.1 (2016): 1-15.
    16. Wang, G. Q., Cen, C., Li, C., Cao, S., Wang, N., Zhou, Z., … & Wang, J. (2015). Deactivation of excitatory neurons in the prelimbic cortex via Cdk5 promotes pain sensation and anxiety. Nature communications, 6(1), 1-16.

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