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In This Article

  • Summary
  • Abstract
  • Introduction
  • Protocol
  • Results
  • Discussion
  • Disclosures
  • Acknowledgements
  • Materials
  • References
  • Reprints and Permissions

Summary

The goal of this article is to describe a refined method of intubation of the laboratory mouse. The method is noninvasive and, therefore, ideal for studies that require serial monitoring of respiratory function and/or instillation of treatments into the lung.

Abstract

The literature describes several methods for mouse intubation that either require visualization of the glottis through the oral cavity or incision in the ventral neck for direct confirmation of cannula placement in the trachea. The relative difficulty or the tissue trauma induced to the subject by such procedures can be an impediment to an investigator’s ability to perform longitudinal studies. This article illustrates a technique in which physical manipulation of the mouse following the use of a depilatory to remove hair from the ventral neck permits transcutaneous visualization of the trachea for orotracheal intubation regardless of degree of skin pigmentation. This method is innocuous to the subject and easily achieved with a limited understanding of murine anatomy. This refined approach facilitates repeated intubation, which may be necessary for monitoring progression of disease or instillation of treatments. Using this method may result in a reduction of the number of animals and technical skill required to measure lung function in mouse models of respiratory disease.

Introduction

The laboratory mouse is a common animal model for human respiratory disease. Thus, there are several published methods for mouse intubation for the purpose of both instillation of treatments and measurement of respiratory mechanics. Most of the described procedures require visualization of the glottis through the oral cavity with specialized equipment such as a laryngoscope or fiber-optic light source1,2,3,4,5,6,7. However, this can be difficult when a relatively large cannula is required, as it can obscure the view of the researcher. Limjunyawong et al.8 have addressed this concern with a method of intubation in which a small cutaneous incision is made along the midline of the ventral neck allowing for visualization of the trachea. Following the procedure, the incision is closed with tissue adhesive.

For studies requiring frequent repeated intubations, successive incising and closure of this site requires debridement of the skin margins and tissue trauma to the ventral neck. The purpose of the transcutaneous tracheal visualization approach to oral intubation is to provide a refined, noninvasive technique specifically suitable for repeated intubation studies as well as single intubation events in mice.

Protocol

All animal activities described here have been approved by the Institutional Animal Care and Use Committee (IACUC) of The Ohio State University and were conducted in AAALAC-accredited facilities.

1. Procedure Preparation

  1. Construct the intubation platform. To achieve the appropriate platform slope, use a three-inch (7.6 cm) 3-ring binder. Fold a 15−20 cm length of 3-0 silk or other thread material in half and adhere the ends of the thread to the top of the inclined platform with tape to create a suspension loop (Figure 1).
  2. Select a cannula of the appropriate size and length.
    NOTE: For a 20−30 g mouse, a 1−1.5 inch (2.5−3.8 cm) long catheter up to 18 G can be used. For this study, 18 week-old female BALB/c and 10-week-old C57BL/6 mice (n = 3 of each strain) were used. An opaque white catheter sheath provides the best transcutaneous visualization.
  3. Cut a bevel at the distal tip of the catheter and smooth the cut surface with abrasive paper to create a rounded bevel tip. Gently create a slight bend in the cannula approximately 1 cm from the bevel (Figure 2).
    NOTE: A new catheter should be used for each mouse.
  4. Anesthetize the mouse with ketamine (5.4 mg/g body weight) and xylazine (16 µg/g body weight) administered intraperitoneally.  Apply sterile ophthalimic ointment to the eyes.
    NOTE: Proper anesthetic depth is achieved by lack of response of the mouse to a firm toe pinch.
  5. Suspend the mouse in a supine position on the intubation platform by hooking the upper incisors around the silk thread at the top of the angled surface (Figure 3). Once the mouse is squarely positioned in dorsal recumbency, gently grasp the base of the tail and retract the tail towards the table. Place a piece of tape over the base of tail to secure the mouse.
  6. Apply depilatory cream (Table of Materials) to the ventral cervical region for 30−45 s then remove all depilatory cream from the cervical region using a dry gauze. Repeat application process if needed. Thoroughly rinse the skin with saline or distilled water to remove any residue then wipe dry.

2. Intubation Procedure

  1. Use straight, flat forceps in the nondominant hand to gently retract the tongue in a manner that sufficiently opens the mouth for introduction of the cannula.
    NOTE: Rat tooth forceps should not be used as this will damage the tongue.
  2. With the dominant hand, advance the cannula into the mouth such that the end that is distal to the slight bend is against the roof of the subject’s mouth.
  3. Release the tongue and slide the flat edge of the closed forceps caudally along the ventral neck until the manubrium is reached. This motion laterally displaces the salivary glands and flattens the muscle covering the trachea. The trachea appears transcutaneously as a white line (Figure 3A). If necessary, rotate the forceps in a craniodorsal direction while maintaining tension on the skin in a caudal direction to cause the laterally displaced salivary glands to peak. This maneuver creates more contrast around the trachea (Figure 3B).
    NOTE: Avoid excessive force on the ventral neck as it can collapse the trachea and impair breathing.
  4. Advance the cannula while simultaneously angling the distal tip of the cannula ventrally by supination of the dominant hand with simultaneous flexion of the wrist.
  5. The proper placement of the cannula is indicated by visualization of the opaque cannula in the trachea (Figure 4B,D). If the cannula has been advanced past the level of the origin of the masseter muscle and visualization of the cannula in the trachea has not been confirmed, retract the cannula and reattempt the maneuver.
  6. Confirm proper cannula placement by connecting a lung inflation bulb to the cannula and observing thoracic expansion with concurrent depression of the device.
  7. Without displacing the cannula, carefully unhook the incisors of the mouse from the intubation platform. Move the mouse to a horizontal platform (Table of Materials) and insert the cannula to the adaptor on the ventilator. Following the deep inflation, ventilate the mouse for 60 s then measure respiratory resistance.

3. Recovery

  1. Once the procedure is complete, move the mouse to a warmed platform. Provide constant stimulation via light toe or tail pinches to encourage spontaneous respiration.
  2. Extubation can occur when the mouse just begins to chew. Grasp the cannula at the level of the hub and gently pull the tube cranially and away from the mouse until the cannula is completely removed from the subject’s mouth.
    NOTE: It is preferable to provide airway support with the rigid cannula for as long as possible during the recovery process.
  3. Once extubated, transfer the mouse to a clean recovery cage with heat support. Continuously monitor the mouse until it is fully ambulatory, and recovery is complete.

Results

Serial monitoring of baseline pulmonary function
Eighteen-week-old female BALB/c and 10-week-old C57BL/6 mice (n = 3 of each strain) were intubated using the described method on day 0, 3, 10, and 17. Following intubation on each day, the subject was connected to a mechanical ventilator supplied with 100% oxygen (Table of Materials). Respiratory resistance (Rrs) was measured using the forced oscillation technique for 60 s following a deep inflation to 25 cm H2O held for 5...

Discussion

Intubation using the transcutaneous tracheal visualization technique offers a refined approach to the standard skin incision method. With special attention to several key steps, intubation can be easily and quickly achieved. The animal must be placed squarely in dorsal recumbency on the intubation platform with the mouse secured in gentle retraction. This will extend the animal into vertical alignment and proper positioning for intubation. In addition, the depilatory cream should not remain in contact with the animalR...

Disclosures

The authors have nothing to disclose.

Acknowledgements

The authors thank Lucia Rosas, Lauren Doolittle, Lisa Joseph and Lindsey Ferguson for their technical assistance and the University Laboratory Animal Resources for their animal care support. This work is funded by NIH T35OD010977 and R01-HL102469.

Materials

NameCompanyCatalog NumberComments
18Gx1 1/4" intravenous catheter, SafeletFisher Scientific#14-841-14Cannula for intubation
70% ethanol, 10LFisher Scientific25467025Cleaning cannula
Abrasive paper (sandpaper)Porter-Cable74001201Cannula preparation
AnaSed (xylazine sterile solution) injection (100 mg/ml)Akorn Animal HealthNDC# 59399-111-50Anesthesia
Blue labeling tape (0.5 in x 14 yds)Fisher Scientific15966Restraint on intubation platform
Braided silk suture without needle, nonsterile, (3-0)Henry ScheinItem #1007842Intubation platform
Deltaphase Isothermal PadBraintree Scientific39DPMouse thermoregulation and recovery
Deltaphase Operating BoardBraintree Scientific39OPMouse recovery (prior to extubation)
Distilled waterThermoFisher15230253Cleaning mouse following depilation
Eye Scissors, angled, sharp/sharpHarvard Apparatus72-8437Cannula preparation
FlexiVent (FX Module 2)ScireqN/ARecord lung function data (not required to perform procedure, used in this study to validate procedure)
Gauze spongesFisher scientific13-761-52Hair removal
Heavy-Duty 3" 3-Ring View BindersStaples24690CTIntubation platform
Instat SoftwareGraphpadN/AStatistical analysis software
Insulin syringe (0.5 cc, U100)Fisher Scientific329461Anesthesia administration
Ketamine HCl Injection, USP (100 mg/ml)Llyod LaoratoriesList No. 4871Anesthesia
Lung inflation bulbHarvard Apparatus72-9083Confirm cannula placement
Micro Forceps, Curved, SmoothHarvard Apparatus72-0445Retract tongue and create tension on neck for cannula visualization
Nair (hair removal lotion), 9 oz bottleChurch & Dwight42010440Hair removal
Sterile saline (0.9%), 10 mlFisher ScientificNC9054335Anesthesia, cleaning skin following hair removal

References

  1. Spoelstra, E. N., et al. A novel and simple method for endotracheal intubation of mice. Laboratory Animals. 41 (1), 128-135 (2007).
  2. Rivera, B., Miller, S. R., Brown, E. M., Price, R. E. A Novel Method for Endotracheal Intubation of Mice and Rats Used in Imaging Studies. Contemporary Topics in Laboratory Animal Science. 44 (2), 52-55 (2005).
  3. Sparrowe, J., Jimenez, M., Rullas, J., Martinez, A. E., Ferrer, S. Refined Intratracheal Intubation Technique in the Mouse, Complete Protocol Description for Lower Airway Models. Global Journal of Animal Scientific Research. 3 (2), 363-369 (2015).
  4. Deyo, D. J., Wei, J. A Novel Method of Intubation and Ventilation in Mice. Anesthesia & Analgesia. 88 (2), 179 (1999).
  5. Vergari, A., et al. A new method of orotracheal intubation in mice. European Review for Medical and Pharmacological Sciences. 8 (3), 103-106 (2004).
  6. Brown, R. H., Walters, D. M., Greenberg, R. S., Mitzner, W. A method of endotracheal intubation and pulmonary functional assessment for repeated studies in mice. Journal of Applied Physiology. 87 (6), 2362-2365 (1999).
  7. Das, S., MacDonald, K., Chang, H. S., Mitzner, W. A Simple Method of Mouse Lung Intubation. Journal of Visualized Experiments. (73), e50318 (2013).
  8. Limjunyawong, N., Mock, J., Mitzner, W. Instillation and Fixation Methods Useful in Mouse Lung Cancer Research. Journal of Visualized Experiments. (102), e52964 (2015).
  9. Qin, W., Baran, U., Wang, W. Lymphatic response to depilation-induced inflammation assessed with label-free optical lymphangiography. Lasers in Surgery and Medicine. 47 (8), 669-676 (2015).
  10. McGovern, T. K., Robichaud, A., Fereydoonzad, L., Schuessler, T. F., Martin, J. G. Evaluation of Respiratory System Mechanics in Mice using the Forced Oscillation Technique. Journal of Visualized Experiments. (75), e50107 (2013).

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