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patch clamp micromanipulator  (Scientifica)

 
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    Structured Review

    Scientifica patch clamp micromanipulator
    Left: Overview of the experimental setup showing perfusion inflow and outflow tubing, a low-magnification objective, a high-magnification water-immersion objective, and both white and infrared (IR)-LEDs mounted on a <t>micromanipulator.</t> The LEDs should be connected to an adjusted power supply unit and positioned so that their beams strike the plane of the experimental chamber at a 10–20° angle. Note that the LEDs must remain above the bath solution and should not be submerged. Right: Overview of spinal cord preparation in the experimental chamber. The ex vivo spinal cord preparation is affixed to a metal plate at an approximately 45° angle so that the dorsal horn is on top. The spared dorsal root is connected to a suction electrode and is slightly pulled to reveal the underlying dorsal horn. Modified from [17].
    Patch Clamp Micromanipulator, supplied by Scientifica, used in various techniques. Bioz Stars score: 86/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
    https://www.bioz.com/result/patch clamp micromanipulator/product/Scientifica
    Average 86 stars, based on 1 article reviews
    patch clamp micromanipulator - by Bioz Stars, 2026-05
    86/100 stars

    Images

    1) Product Images from "Optogenetic Approach for Investigating Descending Control of Nociception in Ex Vivo Spinal Cord Preparation"

    Article Title: Optogenetic Approach for Investigating Descending Control of Nociception in Ex Vivo Spinal Cord Preparation

    Journal: Bio-protocol

    doi: 10.21769/BioProtoc.5483

    Left: Overview of the experimental setup showing perfusion inflow and outflow tubing, a low-magnification objective, a high-magnification water-immersion objective, and both white and infrared (IR)-LEDs mounted on a micromanipulator. The LEDs should be connected to an adjusted power supply unit and positioned so that their beams strike the plane of the experimental chamber at a 10–20° angle. Note that the LEDs must remain above the bath solution and should not be submerged. Right: Overview of spinal cord preparation in the experimental chamber. The ex vivo spinal cord preparation is affixed to a metal plate at an approximately 45° angle so that the dorsal horn is on top. The spared dorsal root is connected to a suction electrode and is slightly pulled to reveal the underlying dorsal horn. Modified from [17].
    Figure Legend Snippet: Left: Overview of the experimental setup showing perfusion inflow and outflow tubing, a low-magnification objective, a high-magnification water-immersion objective, and both white and infrared (IR)-LEDs mounted on a micromanipulator. The LEDs should be connected to an adjusted power supply unit and positioned so that their beams strike the plane of the experimental chamber at a 10–20° angle. Note that the LEDs must remain above the bath solution and should not be submerged. Right: Overview of spinal cord preparation in the experimental chamber. The ex vivo spinal cord preparation is affixed to a metal plate at an approximately 45° angle so that the dorsal horn is on top. The spared dorsal root is connected to a suction electrode and is slightly pulled to reveal the underlying dorsal horn. Modified from [17].

    Techniques Used: Ex Vivo, Modification



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    Image Search Results


    Left: Overview of the experimental setup showing perfusion inflow and outflow tubing, a low-magnification objective, a high-magnification water-immersion objective, and both white and infrared (IR)-LEDs mounted on a micromanipulator. The LEDs should be connected to an adjusted power supply unit and positioned so that their beams strike the plane of the experimental chamber at a 10–20° angle. Note that the LEDs must remain above the bath solution and should not be submerged. Right: Overview of spinal cord preparation in the experimental chamber. The ex vivo spinal cord preparation is affixed to a metal plate at an approximately 45° angle so that the dorsal horn is on top. The spared dorsal root is connected to a suction electrode and is slightly pulled to reveal the underlying dorsal horn. Modified from [17].

    Journal: Bio-protocol

    Article Title: Optogenetic Approach for Investigating Descending Control of Nociception in Ex Vivo Spinal Cord Preparation

    doi: 10.21769/BioProtoc.5483

    Figure Lengend Snippet: Left: Overview of the experimental setup showing perfusion inflow and outflow tubing, a low-magnification objective, a high-magnification water-immersion objective, and both white and infrared (IR)-LEDs mounted on a micromanipulator. The LEDs should be connected to an adjusted power supply unit and positioned so that their beams strike the plane of the experimental chamber at a 10–20° angle. Note that the LEDs must remain above the bath solution and should not be submerged. Right: Overview of spinal cord preparation in the experimental chamber. The ex vivo spinal cord preparation is affixed to a metal plate at an approximately 45° angle so that the dorsal horn is on top. The spared dorsal root is connected to a suction electrode and is slightly pulled to reveal the underlying dorsal horn. Modified from [17].

    Article Snippet: Patch clamp micromanipulator (Scientifica, model: PatchStar) 5.

    Techniques: Ex Vivo, Modification