Isolation and Excision of Murine Aorta; A Versatile Technique in the Study of Cardiovascular Disease

Summary

Pathology of the aorta can lead to severe morbidity and mortality, therefore research of disease progression and potential therapies is warranted. Here, we present a protocol to isolate and excise the murine aorta to aid researchers in their investigation of cardiovascular disease.

Abstract

Cardiovascular disease is a broad term describing disease of the heart and/or blood vessels. The main blood vessel supplying the body with oxygenated blood is the aorta. The aorta may become affected in diseases such as atherosclerosis and aneurysm. Researchers investigating these diseases would benefit from direct observation of the aorta to characterize disease progression as well as to evaluate efficacy of potential therapeutics. The goal of this protocol is to describe proper isolation and excision of the aorta to aid investigators researching cardiovascular disease. Isolation and excision of the aorta allows investigators to look at gross morphometric changes as wells as allowing them to preserve and stain the tissue to look at histologic changes if desired. The aorta may be used for molecular studies to evaluate protein and gene expression to discover targets of interest and mechanisms of action. This technique is superior to imaging modalities as they have inherent limitations in technology and cost. Additionally, primary isolated cells from a freshly isolated and excised aorta can allowing researchers to perform further in situ and in vitro assays. The isolation and excision of the aorta has the limitation of having to sacrifice the animal however, in this case the benefits outweigh the harm as it is the most versatile technique in the study of aortic disease.

Introduction

The aorta plays a pivotal role in cardiovascular function supplying the body with oxygenated blood and similar to others portions of the body, is susceptible to disease. Common aortic diseases include atherosclerosis and aneurysm, which are the results of genetic and environmental factors including diet, smoking and sedentary lifestyle¹. Atherosclerosis is the deposition of a calcium- and lipid-based plaque to the aortic wall typically found in patients with chronic hyperlipidemia². Aneurysms are characterized by degradation of the structural components of the aorta and thinning of the vessel wall, followed by an increased diameter which could ultimately lead to rupture³.

Animal models are important tools used to study the mechanism of disease and efficacy of potential treatments. Common animal models used in cardiovascular research, specifically research investigating vascular and metabolic disorders include genetically modified mice to alter lipid levels such as apolipoprotein E gene knockout and low density lipoprotein receptor gene knockout mice⁴. The majority of methods to evaluate mechanisms of disease and efficacy of therapy would include the isolation and excision of the aorta.

Once the aorta is localized and isolated, morphometric analysis can be determined, such as presence of aneurysm, typically defined as a greater than 50% increase in diameter⁵. After necessary in situ analysis is complete, the aorta can be excised for further analysis. An excised aorta can be flash frozen to conduct molecular studies such as protein and/or gene expression assays or fixed using 4% paraformaldehyde and later embedded, sectioned and stained for histological analysis. Histological analysis of the aorta can demonstrate common features of aortic disease such as structural degradation, plaque formation, and infiltration of leukocytes^6,7. Additionally, an excised aorta can be used to isolate primary cell lines including endothelial and smooth muscle cells which can subsequently be used for a variety of in vitro studies⁷.

Currently, there are no other methods to provide this in-depth characterization of aortic disease as well as provide researchers with tools to further study cardiovascular disease. Imaging modalities such as magnetic resonance imaging, computed tomography and ultrasonography are the closest methods to morphologically evaluate the aorta, however this is difficult in small animals and obtaining a device with adequate technology is expensive⁸. Immortalized cell lines can be purchased to investigate potential mechanisms of disease and efficacy of therapies, however the artificial nature of these cells are limiting in studying the effects on the cell life cycle and apoptosis⁹.

The overall goal of this manuscript is to demonstrate the sterile isolation and excision of the murine aorta in the investigation of cardiovascular disease.

Access restricted. Please log in or start a trial to view this content.

Protocol

All animal procedures were performed with the approval of the Institutional Animal Care and Use Committee of the University of Cincinnati and in accordance with the Guide for the Care and Use of Laboratory Animals from the National Institutes of Health (NIH Publication No. 85-23, Revised 1996).

1. Preparing the Mouse

1. Euthanize by exposing the animal to a supratherapeutic dose of anesthetic, isoflurane inhaled to effect. Verify primary euthanasia via toe pinch as a noxious stimulus. Secondary method of euthanasia, diaphragm cutting, will occur in an upcoming step. Alternative methods may be used granted euthanasia is obtained.
2. Sanitizie the external surface of the mouse by spraying the fur along the abdominal region, where the initial cuts will be made, with 70% ethanol to the point of moisture so that the fur is wet with ethanol and any loose/dry hairs do not enter the region.
3. Lay the mouse out on a surgical board in the supine position with upper and lower appendages extended outward.
4. Secure appendages to the board using surgical tape.

2. Isolation of the Heart and Aorta

1. After proper positioning of the mouse, use forceps to locate and isolate abdominal skin just inferior to the xiphoid process of the sternum.
2. Create tension by lifting the skin straight up and use scissors to remove the superficial skin, exposing the superior portion of the peritoneum and inferior portion of the thoracic cavity.
3. Enter the peritoneal cavity by lifting the xiphoid process and making lateral incisions just inferior to the process along the subcostal margins.
4. Dissect up into the thoracic cavity, going through the diaphragm, being sure not to lacerate the heart or any major blood vessels.
5. Extend the lateral incisions made in step 2.3 cranially to remove the anterior portion of the ribcage. If necessary, free the heart from the anterior chest wall using blunt dissection.
6. Clean the chest cavity of extraneous blood and fluid by using sterile gauze to absorb material. Once the area is more visible, remove the lungs to better expose the heart and aorta.

3. Perfusion of Heart and Aorta

NOTE: To obtain blood via cardiac puncture, do so just prior to this step.

1. Fill a 10 cc syringe with 10 ml of sterile ice cold 1x phosphate buffer solution (PBS), and attach a 25 gauge needle to the syringe.
2. Gently insert the needle into the left ventricle of the heart.
3. Cut the right atrium to alleviate pressure buildup from perfusion. Perfuse the contents of the syringe into the mouse over 2 - 3 min.
4. Use sterile gauze at the opening in the right atrium to absorb perfusion fluid.

4. Isolation and Excision of the Aorta

1. Upon completion of perfusion, use sterile gauze to absorb any remaining fluid clouding the field of view within the thoracic cavity.
2. Expose the gastrointestinal contents by cutting caudally through the abdominal wall, extending the incision to the suprapubic area. Extend the incision further towards the lower limbs bilaterally to create skin flaps which can be pinned down or excised.
3. Remove the lobes of the liver, pancreas, stomach, spleen, and intestines to better visualize the aorta. Take care when dissecting near the perirenal region, as the aorta is superficial at the branches of the renal arteries.
   NOTE: Perform this step in a precise and matriculate manner as the gastrointestinal tract is rich with bacteria which increases the propensity for contamination.
4. Rinse the area with 1x PBS and remove all fluid by absorption with a sterile gauze.
5. Using sterile microscissors and microforceps, separate the aorta from the spine dorsally and the esophagus ventrally. It is best to use blunt dissection and utilizing a dissection microscope for this.
   NOTE: In isolating the aorta, start caudally at the iliac bifurcation and move cranially cleaning and separating the aorta from the dorsal surface of the cavity or start cranially at the carotids and brachiocephalic arteries dissecting caudally. Either method is appropriate and is up to the researchers comfort.
6. Remove the perivascular adipose tissue using fine microscissors being sure not to remove a portion of the aortic wall. This is essential to minimize the potential for fibroblast contamination when culturing aortic smooth muscle cells.

Access restricted. Please log in or start a trial to view this content.

Results

Upon completion of the procedure, there will be an intact aorta originating from the heart, descending into the thoracic and abdominal cavities with the renal arteries still attached (Figure 1A). From here, the aorta can be imaged in situ to quantify morphometric changes which are diagnostic in the study of abdominal aortic aneurysms (Figure 1B and 1C). Subsequently, the aorta can be removed, fixed and stained to look at histological changes. A general and commo...

Access restricted. Please log in or start a trial to view this content.

Discussion

Aortic disease can lead to significant systemic pathology and possibly death in severe cases. Treatment options are currently limited therefore continued research in the field is necessary¹⁰. Murine models are ideal to further study disease progression and potentially therapeutic options⁴. Therefore, the successful completion of the method described in this manuscript will provide investigators with the tools to measure disease progression and drug efficacy.

This techniq...

Access restricted. Please log in or start a trial to view this content.

Materials

Name	Company	Catalog Number	Comments
Isoflurane	Med-Vet International	#RXISO-250
70% ethanol	Fisher	07-678-001
Phosphate buffered saline	Sigma Aldrich	P5368-10PAK
Surgical tape	3M	1527-1
Sterile gauze	Dukal Corporations	1312
25 gauge needle	BD	305122
10 ml syringe	BD	309604