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Drug Microinjection with Electrophysiological Recording in a Rat Brain

Published: October 31, 2024

Abstract

Source: Lai, J., et al. Simultaneous electrophysiological recording and micro-injections of inhibitory agents in the rodent brain. J. Vis. Exp. (2015)

This protocol outlines the assembly and use of an injectrode for precise drug delivery into targeted brain regions of an anesthetized rat, followed by monitoring of neuronal activity through recorded electrical signals.

Protocol

All procedures involving animal models have been reviewed by the local institutional animal care committee and the JoVE veterinary review board.            

1. Assembly of the Recording-injection Pipette

  1. Pull an approximately 7 cm long glass capillary (1 mm outer diameter) using a pipette puller.
  2. Break the capillary tip and check the aperture under a light microscope. Confirm that the inner diameter is between 30 µm to 40 µm.
  3. Insert a 7 cm long silver wire into the glass capillary with approximately 1 cm protruding from the non-tapered end of the glass pipette.
  4. Bend the excess filament orthogonally to the glass capillary.
  5. Apply a droplet of flexible plastic adhesive on the shaft of a 30 G hypodermic needle.
  6. Insert a 30 G hypodermic needle in the glass pipette according to the schematics presented in Figure 1.
  7. Add a second glue coating to ensure a proper seal from the junction between the glass pipette and the hypodermic needle.
  8. Leave the pipette to dry with the tip facing upward for about 12 hr to ensure proper glue curing. The finished result is shown in Figure 2.

NOTE: This procedure is done in acute experiments, and sterilization of the pipette tip is not required.

2. Animal Preparation

  1. Place the rat in an anesthesia box.
  2. Induce anesthesia using 4% isoflurane for 5 to 10 min.
  3. Place the animal on a stereotaxic table with a heating pad and rectal probe to maintain a body temperature of 37 °C. Use a nose cone with 2% isoflurane to maintain anesthesia. Secure the rat's head using ear bars and a teeth holder.
  4. Apply ophthalmic ointment or eye drops, including 1% Atropine drops, to aid in pupil dilation. To prevent dryness, apply lubricating drops approximately every 30 minutes.
  5. Shave the head and clean it with 10% povidone-iodine.
  6. For local anesthesia, inject 0.5 ml of 2% lidocaine under the scalp in 2-3 locations by lifting the skin and inserting the tip of the needle.
  7. Confirm an adequate level of anesthesia by performing a toe pinch and observing the lack of movement. In addition, the heart rate must be monitored to ensure it is within normal values (300 to 400 beats/min).
  8. Incise the scalp in a straight line along the median with a #10 scalpel blade to expose both the coronal and sagittal sutures.
  9. Reveal the Lambda and Bregma points by pushing aside the tissue covering the cranium with a surgical spatula.
  10. Level the cranium so Bregma and Lambda positions are on the same plane.
  11. To set the reference point, use a stereotaxic device with a mounted glass tube to set it right above Bregma. This will be the "zero" for the anteroposterior and medial-lateral measurement coordinates.
  12. Set the point of interest by moving the stereotaxic mount to the required coordinates, note the stereotaxic coordinates, and draw a square around the target area that marks where the craniotomy will be performed.
  13. Use a surgical drill with a sterilized drill along the marked square slowly without pressure to remove the bone material. Be careful not to drill too long in the same area, as it will produce heat and cause lesions on the cortex.
  14. When the bone delimiting the craniotomy has become sufficiently thin, carefully remove the cranial section with tweezers to expose the cortex.
  15. Frequently irrigate the exposed cortex with artificial cerebral spinal fluid to prevent tissue desiccation.
    NOTE: Dura mater removal is unnecessary on the rat as the tip of the injectrode is sturdy enough to penetrate.

3. Filling and Mounting of the Injection System

  1. Fill the 5-10 µl microsyringe by aspiration with mineral oil.
  2. Fill the hypodermic needle with the fixed glass pipette with a solution of 0.5% Chicago Sky Blue (CSB) and 300 µM γ-aminobutyric acid (GABA) or a solution of 2% lidocaine with 0.5% CSB 9. Dilute all solutions with saline.
    1. In the case of an abundant substance, fill using a regular syringe and use the usual preventive techniques to avoid the formation of air bubbles.
    2. In the case of more expensive substances, mineral oil can be used to fill the injectrode, and the chemical agent can then be introduced by aspiration. The density difference between mineral oil and water is relatively high, so this substance is a good candidate for injecting aqueous solutions.
      NOTE: A dye can be added to confirm the separation between both liquids.
  3. To fill the injection pipette, aspirate a 1 ml syringe with the solution and slowly inject it into the pipette.
  4. Pay careful attention to leaks in regions indicated in Figure 1 by swabbing these areas clean and observing leakages by injecting the solution slowly with the syringe.
  5. Remove the 1 ml syringe. When doing so, keep light pressure on the plunger so that the vacuum does not remove the solution from the injection pipette.
  6. Aspirate the microsyringe with mineral oil and attach it firmly to the filled injection pipette. Then, carefully wipe away any excess solution from the assembled injectrode with gauze.
  7. Inject a very small volume, enough to see a small drop form at the tip of the glass pipette, to verify that the tip is not blocked.
  8. Mount the injectrode on the micropump system and ensure it is well fixed.
  9. Carefully position the injectrode tip at the target coordinates and lower the tip to the surface of the cortex.
  10. Slowly lower the injectrode using the stereotaxic apparatus to the target structure (superior colliculus) using the appropriate anatomical coordinates.
  11. Cover the exposed cortex with warm agar to prevent tissue desiccation.

4. Injection and Reversible Inactivation

  1. Set the microinjection pump to inject 400 to 800 nl at 40 nl/min and press Run to start the injection. Note that the spike rate will show a reduction during the injection.
    NOTE: In the experimental setup, neural activity recovered within an hour after the end of GABA delivery. Any calibrated mechanical device can be used to apply pressure to the microinjection syringe and conduct the injection.
  2. After acquiring the electrophysiological data, euthanize using a method approved by the local Animal Ethics Community.

Representative Results

Figure 1
Figure 1: Schematic representation of the injectrode assembly. A microsyringe (A) is attached to the recording-injection pipette, which consists of a 30 G hypodermic needle (B) adhered to a silver wire (C) inside a glass pipette (D). Regions circled (E-F) highlight areas that may be susceptible to leaks.

Figure 2
Figure 2: A photo of the constructed pipette using a 30 G needle (B), waterproof adhesive glue (F), silver wire (C), and a glass pipette (D).

Disclosures

The authors have nothing to disclose.

Materials

Injection pump (UltraMicroPump III) WPI #UMP3
Injection console (Micro4 Controller) WPI #SYS-MICRO4
Hamilton syringe Hamliton (80301) 701LT 10 µL SYR Syringes between 5 and 10 μL used
Gel cyanoacrylate adhesive Krazy Glue KG86648R The gel form is easier to apply on the shaft of the 30G hypodermic needle
Glass pipettes WPI #TW100F-4 Thin wall, 1mm OD, 0.75mm ID with filament pipettes used
720 Needle Pipette Puller Kopf 720
Silver wire A-M Systems, Inc. 782500 Bare 0.010"
Agar 
Capillary tubes
Hypodermic needle
Chicago Sky Blue (CSB)
γ-aminobutyric acid (GABA)
lidocaine 
Atropine drops
 Isoflurane
Heating pad
Stereotaxic table
#10 scalpel blade
mineral oil 

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Cite This Article
Drug Microinjection with Electrophysiological Recording in a Rat Brain. J. Vis. Exp. (Pending Publication), e22711, doi: (2024).

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