Safety Precautions and Operating Procedures in an (A)BSL-4 Laboratory: 4. Medical Imaging Procedures

Summary

Here, we present an overview of the preparation and animal handling procedures required to safely perform medical imaging in an animal biosafety level 4 laboratory. Computed tomography of a mock-infected guinea pig illustrates these procedures that may be used to evaluate the disease caused by a high consequence pathogen.

Abstract

Medical imaging using animal models for human diseases has been utilized for decades; however, until recently, medical imaging of diseases induced by high-consequence pathogens has not been possible. In 2014, the National Institutes of Health, National Institute of Allergy and Infectious Diseases, Integrated Research Facility at Fort Detrick opened an Animal Biosafety Level 4 (ABSL-4) facility to assess the clinical course and pathology of infectious diseases in experimentally infected animals. Multiple imaging modalities including computed tomography (CT), magnetic resonance imaging, positron emission tomography, and single photon emission computed tomography are available to researchers for these evaluations. The focus of this article is to describe the workflow for safely obtaining a CT image of a live guinea pig in an ABSL-4 facility. These procedures include animal handling, anesthesia, and preparing and monitoring the animal until recovery from sedation. We will also discuss preparing the imaging equipment, performing quality checks, communication methods from "hot side" (containing pathogens) to "cold side," and moving the animal from the holding room to the imaging suite.

Introduction

The mission of the National Institute of Allergy and Infectious Diseases (NIAID) Integrated Research Facility at Fort Detrick in Frederick MD (IRF-Frederick) is to perform emerging infectious disease research to understand the clinical disease processes that correlate with the severity of microbial-induced disease. The IRF-Frederick has a unique capability to perform medical imaging in animal models of high-consequence pathogens in an ABSL-4 laboratory¹. The imaging modalities available to investigators include: computed tomography (CT), magnetic resonance imaging (MRI), positron emission tomography (PET), single photon computed tomography (SPECT), ultrasound, X-ray, and fluoroscopy. Researchers use available imaging capabilities to monitor disease progression and evaluate efficacy of interventions, such as drug treatment and vaccination, in longitudinal studies.

The imaging modalities at the IRF-Frederick were specifically designed to keep the core components of the equipment outside of high containment^2,3 and accessible for maintenance and repair. This design separates the imaging suite into "hot" (containing pathogen) and "cold sides." To achieve this separation, specially designed tubes were constructed to extend high-containment space into the bores of each imaging modality (Figure 1). In addition to providing biological containment, these tubes protect the imaging equipment from gases and chemicals used to decontaminate the high-containment laboratory. Imaging scientists and technologists operate the scanners from the "cold side" while Comparative Medicine (CM) staff handle and monitor animals on the "hot side". Since the CM staff must work closely with imaging scientists to coordinate these experiments, this separation can result in communication challenges.

After evaluating options available, CM staff were outfitted with Bluetooth ear pieces that transmit short-wavelength ultra-high frequency radio waves to phones used to call the imaging staff outside of containment. Due to the design of the facility, wireless access points had to be installed in each of the rooms to overcome signal interference caused by the layers of cement and steel between the "hot" and "cold sides". Thus, communication between CM staff wearing noisy positive-pressure suits and imaging staff outside high-containment is now reliable. Cameras have also been installed on the hot side of the imaging rooms for imaging staff to see activity on the "hot side". With the cameras, the imaging staff can guide CM technicians with animal positioning or any last minute changes to the imaging protocol.

All work in the IRF-Frederick ABSL-4 suit laboratory requires staff to wear positive-pressure encapsulating suits⁴. Wearing these suits reduces mobility, and the heavy latex gloves attached to the suit plus up to three additional layers of gloves compromises dexterity. The result is that procedures take longer to complete and tasks that require fine motor skill are much more difficult. As the biosafety level increases, animal handling and manipulations become more challenging and time consuming, particularly with small animals. Procedures in an ABSL-4 laboratory can take up to 2-3 times longer than an ABSL-2 laboratory.

The purpose of this article is to visually demonstrate the challenges associated with imaging animal models in an ABSL-4 environment using CT scan procedure of a guinea pig as an example.

Protocol

This protocol adheres to the following animal care guidelines. Animals were housed in a facility accredited by the Association for Assessment and Accreditation of Laboratory Animal Care International. All experimental procedures were approved by the National Institute of Allergy and Infectious Diseases, Division of Clinical Research, Animal Care and Use Committee and were in compliance with the Animal Welfare Act regulations, Public Health Service policy, and the Guide for the Care and Use of Laboratory Animals recommendations.

1. Prepare CT Scanner (on "Cold Side")

1. Condition the X-Ray Tube
   1. Verify that no staff member is in the scan room and the subject table is empty.
   2. Run the tube conditioning procedure in accordance with the scanner manufacturer's specifications.
2. Perform Air Calibration
   1. Make sure that no objects are in the scanning field.
   2. Perform the air calibration procedure in accordance with the scanner manufacturer's specifications. On many platforms, this calibration is auto- or semi-automatic.
3. Perform Quality Control Scan (on "Hot Side")
   1. Complete the ABSL-4 suit laboratory entry procedures (outlined in detail in reference⁵) with the addition of an extra step. If procedures involve exposure to radioactive materials, clip a dosimeter to the scrubs under the protective suit. Turn in the dosimeter every 2 months for calculation of the radiation exposure.
   2. Place the CT head and body phantom, which is made out of air, water and Teflon, in the appropriate holder on the scanning table.
4. Perform Quality Control Scan (on "Cold Side")
   1. From the cold side, advance the phantom into the center of the bore⁶.
   2. Acquire a scan using laboratory standardized quality control (QC) parameters to ensure the scanner is within manufacturer's specifications.
   3. Perform QC computerized analysis of images to calculate mean and standard deviations of signal intensity within regions of interest centered over each material type (air, water or Teflon) according to manufacturer's protocol.
   4. Notify CM staff that the CT scanner is ready for use.
   5. Verify the animal information (identification number, weight, date of birth) with the CM staff.
5. Register Subject Information into the Patient Database.
   1. At the CT scanner console (on the "cold side"), access the scanner's Radiology Information System (RIS). Check that the RIS is populated with the details of the scanning schedule.
   2. Select the current subject and demographics such as identification number, age, date of birth, and exam date; then, the exam type should automatically populate.
   3. Manually enter subject weight.
   4. Select correct subject orientation in CT gantry (e.g., head first, feet first, prone, supine).

2. Prepare Work Areas in the ABSL-4 Suit Laboratory

1. Prepare the Class II Biosafety Cabinet (BSC) or Downdraft Table in the Animal Procedure Room. Turn on BSC (or Downdraft Table) at Least 10 Min Prior to Use.
   1. Clean and disinfect interior surfaces of the BSC or the top surface of the downdraft table using an approved disinfectant such as 5% dual quaternary ammonium (n-alkyl- dimethyl benzyl ammonium chloride, n-alkyl dimethyl ethyl benzyl ammonium chloride) disinfectant solution. Spray interior surfaces of the BSC or the top surface of the downdraft table and wipe surfaces dry after 10 min of contact time. Spray and wipe surfaces with 70% ethanol to remove residual disinfectant.
   2. Place equipment and supplies needed in the BSC or downdraft table, including the anesthesia induction box and animal handling gloves.
2. Prepare the CT Scanner Bed.
   1. Set-up the animal holding device on the CT bed.
   2. Set-up the vital signs monitor to detect heart rate and oxygen saturation. If scanning session is longer than 10 min, monitor temperature.
3. Prepare the Anesthesia Machine.
   1. Check the isoflurane volume in the vaporizer and add more isoflurane if needed.
   2. Perform a leak test by pressurizing the anesthetic breathing circuit with oxygen, checking for escaped gas, and visually inspecting the anesthesia machine for leaks¹.
      1. If a leak is detected, determine the source, correct the problem, and perform a follow-up leak test to verify corrections were properly implemented.
   3. Weigh the disposable scavenging canister that captures waste anesthetic gas. If the canister is ≥50 g over the initial weight of the canister, replace canister⁷.

3. Animal Transport from Animal Procedure Room and Preparation of Anesthesia Induction in CT Scanner Room (on "Hot Side")

1. Transfer the Cage Housing the Guinea Pig from One of the Rodent Holding Rooms Adjacent to the Imaging Suite into the Class II BSC.
   1. Verify the animal ID.
   2. Remove the cage card and keep with the animal.
2. Open the lid to the cage and don animal protective leather gloves over the positive-pressure suit gloves. Gently pick up the guinea pig, place animal in the anesthesia induction box, and cover the box with the lid.
3. Remove the anesthesia induction box containing the animal from the Class II BSC and place it on a transport cart.
4. Using the cart, take the animal to the CT scanner room.
5. In the CT scanner room, immediately connect the scavenging canister and anesthesia machine to the induction box. Turn on the oxygen gas to the induction box and set the vaporizer to deliver 4% isoflurane for initial induction of anesthesia⁸.
6. Monitor the animal during anesthesia induction for adequate depth of anesthesia (e.g., unresponsive to external stimuli, muscular tone, stable respiratory and heart rates)⁸.
7. Turn off the anesthesia to the induction box when the guinea pig is fully anesthetized.

4. Arrange Subject on Imaging Bed in the CT Scanner (on "Hot side")

1. Remove the Anesthetized Guinea Pig from the Induction Box and Place on the Imaging Bed.
   1. Place the guinea pig on the holding cushion in a prone position.
   2. Apply ophthalmic ointment in both eyes to protect the corneal epithelium from drying out.
2. Administer Maintenance Isoflurane Anesthesia.
   1. Place the nose cone on the guinea pig and turn on gas to deliver 1 L/min of oxygen to the nose cone⁸.
   2. Set the vaporizer to deliver 2-3% of isoflurane to the guinea pig via the nose cone.
   3. Once the subject has reached the desired plane of anesthesia (no movement, ~60 breaths per min), reduce the vaporizer setting to deliver 1.0-1.5% of isoflurane for maintenance of anesthesia.
   4. Monitor vital signs including body temperature, heart rate, and respiratory rate. If respiratory rate begins to accelerate or slow down, increase or decrease the percent of isoflurane, respectively⁹.
3. Provide an additional heat source to maintain guinea pig body temperature between 37 and 39 °C, if necessary, depending on the expected length of data acquisition and depth of anesthesia maintained^8,9.
4. Secure a plastic cover over the top of the holding cushion.
5. Advance imaging bed into containment tube.

5. Setting the Image Field of View

1. Activate the laser system (imaging staff) on the "cold side" of the CT scanner room to position the guinea pig for CT scanning. Use the table "in" and "out" buttons to cover the anatomy of interest under the laser crosshairs.
2. To set the field of view, use the laser button to set the starting point over the anatomy of interest.
3. Contact CM staff on "hot side" to place a lead shield between themselves and the CT scanner.

6. Acquire Images

1. Acquire survey scan for slice placement for CT study images according to manufacturer's protocol.
2. Prescribe slice placement for CT study images on survey images.
3. Coordinate with "hot-side" personnel if contrast injection is to be used.
4. Acquire study scan according to manufacturer's protocol.
5. Reconstruct CT images at the scanner console according to manufacturer's protocol.
6. Send images to a picture archiving and communication system. Perform further qualitative and quantitative analyses from this archiving system according to manufacturer's protocol.

7. Post-scan Recovery

1. Transfer guinea pig from scanner bed to a clean microisolator cage with food and treats.
2. Using the cart, transport the cage with animal back to its housing area.
3. Monitor the animal until fully recovered from anesthesia.
4. Once fully recovered, return the cage to the high-efficiency particulate air (HEPA)-filtered ventilated racks.

8. Disinfection of Scanner Bay and Equipment

1. Disinfect the scanner bay area (e.g., surfaces that were in direct contact with the animal, scanner bed, scanner room floor, door handles) with a 5% dual quaternary ammonium solution for a contact time of 10 min.
2. Rinse surfaces with a 70% ethanol solution after a 10 min exposure to dual quaternary ammonium solution.
3. Wipe items that cannot be sprayed directly with dual quaternary ammonium solution (sensitive electronic equipment) with a dual-quaternary-ammonium-saturated cloth followed by a ethanol-saturated cloth.

Results

Strict adherence to all safety procedures and standard operating procedures for animal handling is essential for working safely in an ABSL-4 laboratory. Transferring infected animals within the induction box from the animal procedure room to the imaging suite minimizes the risk of contamination of common corridors. By following the procedures required, no laboratory-acquired infections or cross-contamination of animal subjects has been recorded while conducting ABSL-4 research at the IRF-...

Discussion

Previous articles in this series have emphasized the extensive training, attention to detail, safety procedures, and additional engineering controls required to work safely in a maximum containment laboratory^12,13. Performing work safely is the highest priority in these laboratories. This philosophy is even more important when working with live animals due to additional hazards such as the potential for infected animals to inflict bites or scratches or to generate aerosols⁷. These procedures emphasi...

Materials

Name	Company	Catalog Number	Comments
Micro-Chem Plus	National Chemical Laboratories	255
CT scanner	Philips Healthcare
CT phantom	Philips Healthcare
Isovue-300 (CT contrast reagent)	Bracco Diagnostics	NDC 0270-1315-30
Ventilated rack	Lab Products
Micro-isolator cage	Lab Products
Biosafety cabinet	Nuaire
Anesthesia machine	SurgiVet	WWV9000
Anesthesia induction box	VetEquip
Anesthesia mask	Henry Schein
Isoflurane	Henry Schein
Waste gas scavenging canister	Fisher	F/AIR
Holding cushion
Ophthalmic ointment
Vital signs monitor	Bionet	BM3Vet
Mobile phone	Spectralink	8440
Blue Tooth ear piece
Wireless access points
Sperian positive-pressure suit	Honeywell Safety Products	BSL 4-2
Outer suit gloves (latex, Ansell Canners and Handlers)	Fisher	19-019-601
Outer suit gloves (nitrile/rubber, MAPA)	Fisher	2MYU1
Scrubs	Cintas	60975/60976
Socks	Cintas	944
Duct tape	Pack-N-Tape	51131069695
Towels	Cintas	2720
Zip lube	Amazon	B000GKBEJA