This article presents an efficient method to perform myocardial ischemia and subsequent chronic reperfusion in rats using a minimally invasive approach. In addition, left ventricular hemodynamic function of rats is assessed by echocardiography and isolated working heart methods.
Myocardial infarction (MI) remains the main contributor to morbidity and mortality worldwide. Therefore, research on this topic is mandatory. An easily and highly reproducible MI induction procedure is required to obtain further insight and better understanding of the underlying pathological changes. This procedure can also be used to evaluate the effects or potency of new and promising treatments (as drugs or interventions) in acute MI, subsequent remodeling and heart failure (HF). After intubation and pre-operative preparation of the animal, an anesthetic protocol with isoflurane was performed, and the surgical procedure was conducted quickly. Using a minimally invasive approach, the left anterior descending artery (LAD) was located and occluded by a ligature. The occlusion can be performed acutely for subsequent reperfusion (ischemia/reperfusion injury). Alternatively, the vessel can be ligated permanently to investigate the development of chronic MI, remodeling or HF. Despite common pitfalls, the drop-out rates are minimal. Various treatments such as remote ischemic conditioning can be examined for their cardioprotective potential pre-, peri- and post-operatively. The post-operative recovery was quick as the anesthesia was precisely controlled and the duration of the operation was short. Post-operative analgesia was administered for three days. The minimally invasive procedure reduces the risk of infection and inflammation. Furthermore, it facilitates rapid recovery. The “working heart” measurements were performed ex vivo and enabled precise control of preload, afterload and flow. This procedure requires specific equipment and training for adequate performance. This manuscript provides a detailed step-by-step introduction for conducting these measurements.
Although incidence is continuously decreasing, acute myocardial infarction (MI) is still the major contributor to morbidity and mortality worldwide1. There are restrictions on evaluating the efficacy of potential treatments as drugs or surgical procedures which prevent and treat acute MI. Before their effects can be examined in humans, these treatments must be tested for risks in advance, including in vivo examinations in animals. There is no better opportunity to study a pathology than under in vivo conditions. Therefore, MI induction in rats or mice and even large animal models (pigs or sheep) permits the investigation of short- (acute) and long-term (chronic) changes due to ischemia in the coronary arteries and the surrounding myocardium, as well as systemic changes due to impaired cardiac function. Infarct size was previously the main objective, but more recently subsequent cardiac remodelling processes in acute MI or ischemia/reperfusion injury as well as in consecutive heart failure (HF) have become of great interest. Therefore, a comparable and easily reproducible method is required to reach consistent outcomes.
While the use of cryo-ablation to gain MI has been reported2, our method builds on other studies in which investigators occlude the left anterior descending artery (LAD) by a single stitch ligation. In comparison to (hemi-)sternotomy procedures, the minimally invasive approach which will be presented in this article, permits a faster post-operative recovery and markedly reduces the operation time. A common step of other surgical procedures is the lift-out of the heart from the thorax to perform the heart stitch3. The approach of this method renders this step unnecessary. Depending on the protocol, two different procedures can be performed: a temporary occlusion using a tourniquet to induce ischemia/reperfusion over a defined time; or a permanent occlusion of the artery by fixing the ligature. The success of occlusion can be evaluated with electrocardiogram (ECG) and the macroscopic changes in the left ventricle (LV) as well as its paling.
Another important step prior to the surgery is intubation. While in most cases, intubation is performed via tracheotomy or via oral insertion of the tube under vision by a skin incision at the throat, this protocol describes the endotracheal intubation of the anesthetized animal which reduces breathing difficulties or infections post-operatively4,5. To avoid post-operative complications, air is removed from the thorax via a syringe before closing the chest.
The second task of this article is the evaluation of hemodynamic function via an isolated working heart experimental model, how it is used in other projects within our institute6,7. While echocardiography, cardiac magnetic resonance imaging (MRI) and invasive quantification of pressure-volume loops are well-known and widely used methods to assess cardiac function in vivo, they are known to have some limitations. Invasive approaches, such as the use of catheters to examine the global function or specific parameters of the heart, are commonly used and represent the gold standard of cardiac measurements. In contrast, the ex vivo working heart apparatus is rarely used because of its complexity and cost. There are many important aspects, from the mixture of the perfusate to the adequate cannulation of the heart, which are crucial for successful evaluation. The isolated working heart apparatus was firstly described by Oskar Langendorff in 18978 and has been modified over the recent decades9. Today, there are two models used: the Langendorff (LD) mode and the working heart (WH) mode. In our study, the LD mode is used to acclimatize the heart to its new environment (about 15 min). In this mode, the heart is cannulated via the aorta and the coronary arteries are perfused anterogradely, adequately supplying the myocardium. In the LD mode, the heart is not performing any pressure-volume work. By contrast, in the WH mode, the left atrium is cannulated via a pulmonary vein, through which the perfusate enters the left atrium. The heart then pumps this perfusate physiologically against a predefined afterload. By increasing the afterload over time, cardiac function can be continuously measured. Parameters such as coronary flow, cardiac output (CO), stroke volume (SV) and work, atrial flow and LV systolic and diastolic pressures can be measured. The impact of various treatments directly and solely on the heart can be investigated6,10. A review by Liao and Podesser9 presented the widespread use of this method in the evaluation of pharmacological effects on cardiac function and metabolism as well as in the exploration of various diseases such as MI, HF, obesity and diabetes.
In summary, this protocol presents a reproducible method to perform MI or myocardial ischemia/reperfusion (MIR) injury in vivo. In addition, it permits the characterization of LV (dys-)function on an isolated rat heart after MI. This protocol presents a unique combination of treatment and analysis.
The experimental protocol which delivered the results described in this article has been approved by the regional Ethics Committee for Laboratory Animal Experiments at the Medical University of Vienna and the Austrian Federal Ministry of Education, Science and Research (BMWFW-66.009/0023-WF/V/3b/2016). All experiments conform with the Guide for the Care and Use of Laboratory Animals, published by the US National Institutes of Health (NIH Publication No. 85-23, revised 1996).
NOTE: 10−12-week-old male Sprague Dawley rats of 250−300 g body weight (BW) are used. As the following procedures and treatments are performed in a sterile environment of an operating room (OR), wear scrubs, gloves, facemasks and hoods when handling animals. Before entering the OR, ensure that hands are washed and disinfected. If the intention is to operate on several animals in a surgical session, either wash and disinfect, or autoclave the instruments in between operations. These hygienic guidelines are valid for all procedures presented in the protocol section.
1. Preoperative preparation and anaesthesia
2. Surgical procedure―induction of myocardial ischemia
3. Postoperative treatment and exclusion criteria
Examination | Observation | Score |
Body weight | stable | 0 |
10% loss | 4 | |
15% loss for 48 h | 7 | |
18% loss | 7 | |
normal (coat flat and shiny) | 0 | |
External appearance | piloerection | 1 |
haematoma | 2 | |
skin wounds/cuts/bite marks | 2 | |
severely reduced grooming | 4 | |
(orifices unclean/clotted or moist) | 7 | |
severe skin irritations or wounds | 7 | |
hunched posture >2 h | 7 | |
significant abdominal distension (ascites) | 7 | |
Comportamiento | normal (sleeping, curious, social contacts, reaction when touched) | 0 |
unusual behaviour, e.g. impaired activity | 2 | |
self-isolation, pronounced hyperactivity or stereotypia | 4 | |
lethargia for <6 h | 4 | |
lethargia for 6 h to 8 h | 7 | |
apathia >8 h | 7 | |
stereotypia uninterrupted for >10 min. and still persisting after 2 h | 7 | |
signs of pain when touched | 7 | |
automutilation | 7 | |
Digestion | normal | 0 |
diarrhea (soft feces) | 3 | |
diarrhea for 72 h or watery | 7 | |
bloody stool | 7 |
Table 1: Checklist and exclusion criteria. This table contains the examinations that must be observed and the corresponding score. Accordingly, the post-operative treatment of the animal must be adapted, or a veterinarian must be consulted.
4. Echocardiography measurements
NOTE: Echocardiography is usually performed twice, prior to the induction of MI and before the organs are harvested.
5. Organ harvesting (without working heart)
6. Ex vivo hemodynamic measurements via a working heart system
NOTE: The general setup and the components of the apparatus has been previously described11. The following protocol describes the handling of the animal’s heart and the necessary steps to evaluate LV function.
The following results have been published by Pilz et al.6. With this precise surgical procedure, the cardioprotective effect of remote ischemic perconditioning (RIPerc) can be investigated. This is a potential new treatment for patients suffering from acute MI or MIR and subsequent ventricular remodeling, which in many cases leads to consecutive HF. Mimicking the pathophysiological changes of MI/MIR is an obligatory step in the evaluation of treatments as in vitro or ex vivo studies do not provide the physiological environment. In this protocol, the animals were subjected to 30 min of LAD occlusion followed by reperfusion (i.e., MIR).
To prove the reproducibility of the procedure, histological cuts and stains were performed (Figure 4A). It was clear that the fibrotic scar in MIR+RIPerc treated animals was comparable with the scar formation of the Sham animals while the comparison of fibrosis between Sham and MIR groups was significant (Figure 4B). Additionally, MIR+RIPerc treated animals showed significantly reduced fibrosis compared to MIR-treated animals. However, the representative histological images clarify the potency of this surgical procedure as the infarction is explicitly sustained in the MIR group (Figure 4A). Using in vivo echography, ejection fraction, LV end-diastolic and end-systolic diameters (LVEDD and LVESD) were measured and showed significantly reduced cardiac function due to MIR treatment while hemodynamic parameters were preserved by RIPerc (Figure 4C−F). Ex vivo hemodynamic data exhibited the effectiveness of the procedure as the MIR group showed significant decreases in LVSP, cardiac output (CO), stroke volume (SV) as well as external heart work (EHW) (Figure 5A−G).
A literature search about this surgical procedure reported no negative or unsatisfying comments and results when it was adequately performed. Nevertheless, pitfalls mentioned in the introduction and the discussion need to be prevented and training is mandatory to acquire a stable level of performance and to obtain comparable results.
Figure 1: Preoperative preparation and surgical procedure. (A) Intubation of the animal using a 14 G tube. (B) Supine positioning and disinfection of the surgical field. (C) Skin incision (2 mm parasternal on the left thorax at the level of the 3rd intercostal space). The incision must reach the anterior axillary line at the level of the 5th intercostal space. (D) Displace the muscles to make the ribs visible. (E) Opening of the thorax. (F) Permanent occlusion of LAD using 6−7 knots. (G) Transient occlusion of LAD using a tourniquet. (H) Closure of the chest after myocardial ischemia and reperfusion by placing three single-knot sutures around the ribs. (I) Proper closing of the thorax. Use a 10 mL syringe to remove any residual air from the thorax before fixing the last knot tightly. This is integral to prevent a pneumothorax. (J) Skin suture. Please click here to view a larger version of this figure.
Figure 2: Organ harvesting. (A) Open the chest with sub-xiphoidal cuts and extend them to both mid-axillary lines. Further cuts through the ribs are performed to facilitate lifting of the sternum. (B) Excision of the heart. Please click here to view a larger version of this figure.
Figure 3: Isolated heart apparatus. (A) Langendorff mode. The heart is mounted to the WH apparatus via cannulation of the aorta. (B) Working heart mode. The system can be switched to the WH model to evaluate cardiac function by cannulating the left atrium. Please click here to view a larger version of this figure.
Figure 4: Effect of remote ischemic conditioning on scar formation, left ventricular function and remodeling. (A) Histological LV slices harvested on day 14 post-myocardial reperfusion. (B) Quantified results of fibrosis in bar graphs. (C) Representative M-mode echocardiograms. (D) Ejection fraction (EF) quantified in bar graphs. (E) LV end-systolic diameter (LVESD) quantified in bar graphs. (F) LV end-diastolic diameter (LVEDD) quantified in bar graphs. MIR, myocardial ischemia-reperfusion; RIPerc, remote ischemic perconditioning. Data are expressed as mean ± SEM. *p < 0.05; **p < 0.01; ***p < 0.001. Reprinted from Pilz et al.6 with permission from Elsevier. Please click here to view a larger version of this figure.
Figure 5: Effect of RIPerc on LV hemodynamic function. (A) LV systolic pressure (LVSP), (B) cardiac output (CO), and (C) stroke volume (SV) results were obtained from the isolated working heart on day 14 post-myocardial reperfusion. (D) CO is depicted as a function of afterload; (F) external heart-work as function of afterload, quantified results in bar graph (E and G). Data is expressed as mean ± SEM and n = 4–7 per group. *p < 0.05; **p < 0.01; ***p < 0.001. MIR, myocardial ischemia/reperfusion; RIPerc, remote ischemic preconditioning; EHW, external heart work; SV, stroke volume; AUC, area under the curve. Reprinted from Pilz et al.6 with permission from Elsevier. Please click here to view a larger version of this figure.
Adverse remodeling post-MI is considered to be a key mechanism in the development of heart failure. Therefore, to ensure the continuity of cardiovascular research, experimental procedures and techniques should be reproducible. A comprehensible and clearly defined experimental protocol is a fundamental element of reproducibility. Reproducibility refers to results that can be repeated by multiple scientists and are validated across laboratories. This study aimed to present a semi-minimally invasive method to induce chronic or re-perfused MI and assess the cardiac hemodynamic function in rats.
These results and further published data show the high potency of this surgical method and its importance in research on MI, remodeling and HF. While ischemia/reperfusion injury can be used to understand the changes in MI with subsequent reperfusion, permanent occlusion allows further understanding of the short- and long-term remodeling processes of the myocardium. Other surgical approaches cause more tissue damage and animals show higher risks of developing infections and pneumothorax, resulting in higher drop-out rates. In contrast, this procedure is aimed to reduce mortality by specific improvements in the setup and handling. Additionally, they show variations in fibrotic scar expansion due to unstable LAD occlusion.
Our protocol provides an easy method for intubation, which is one of the most critical steps of the whole procedure. In contrast to several other publications12, tracheotomy is not performed in our procedure. This enhances awakening and rehabilitation of the animals post-operatively, leading to the development of the pathophysiological changes which are intended by this surgical procedure before the animals undergo post-operative measurements. Obviously, if it is a non-survival protocol, tracheotomy is performed under vision and is thus easier to perform. Additionally, closing of the tracheotomy in a survival-protocol is not applicable. If the thorax is opened, it is mandatory to ventilate the lung to prevent collapse. Therefore, the rats are intubated prior to the surgical procedure. The minimally invasive approach does not cut the ribs or sternum thus maintaining the compactness and stability of the thorax. Consequently, the animals’ recovery is improved, and the risk of spontaneous pneumothorax or bleeding is relatively low.
As aforementioned, while the intubation is of clear advantage, it is difficult to perform and may cause a higher drop-out rate at the beginning of the experiments. This problem can be mitigated with training and some anatomical knowledge. It is important to insert the tube at the right angle and stretch the animal’s body until the light shines through the vocal lips after which the tube can be gently pushed forward. Take care to not harm the vocal lips as this can cause swelling, subsequent occlusion of the glottis and suffocation.
It is also important that the LAD is ligated correctly. The small surgical window, fast beating heart, and ventilated lung (avoid touching it as much as possible as every contact may result in bleeding in the lung) render the vessel not clearly visible. Therefore, anatomical knowledge is indispensable. The left auricle is indispensable to help standardize both the area at risk and to position the ligation around the LAD. The stitch needs to be performed intramurally, not transmurally in the LV as this may cause a reduction of the LV chamber diameter and volume which is not due to the pathological processes. Successful occlusion is associated with cyanosis of the myocardial area at risk and elevation of ST-segment on ECG. The main limitation of this procedure is the correct positioning of the suture. To achieve comparable results, the stitches must be at the same level and need to use similar amounts of tissue. This requires a high level of training and the different weights of the animals must be considered. Another point to consider is the adequate removal of the pneumothorax prior to closure of the intercostal space. If this is not precisely performed, the animals will exhibit difficulties in breathing as inflation of the left lung will be hindered by a pneumothorax. As aforementioned, this can be mitigated by using a syringe to remove any residual air from the thorax.
Currently, this MI procedure is a commonly used method which guarantees comparable results and a high survival rate if the critical steps are performed with high precision. Future projects on various treatments, devices or drugs in MI, HF or cardiac remodeling can be evaluated by performing this minimally invasive technique.
The WH measurements are, as aforementioned, not commonly used as its maintenance and handling requires specific equipment and knowledge. To acquire representative and comparable data, pitfalls must be avoided. The most critical steps are the mounting of the heart and switching from the D model to the WH mode. If the heart is not excised adequately, the mounting may be difficult as sufficient aortic tissue length is required to fix the heart to the apparatus. Soon after connecting to the LD mode, the heart frequency may decrease due to the washing in cold buffer, the disconnection of its physiological stimuli in the body or the reperfusion with blood from another species by the apparatus. In such cases, a pacemaker must be applied to both restore and preserve the physiological frequency. This ensures comparable results in all animals. As the blood volume within the apparatus is a multiple of the physiological volume in rats, bovine red blood cells in a Krebs-Henseleit buffer-based suspension are used.
The switch from the LD mode to the WH mode is synonymous to a switch from passive to active heart work. The LD mode is used to accustom the heart to its new environment. In the WH mode, the heart must perform its physiological ejection functions. Therefore, a short adaption phase to the new circumstances is required before the evaluation by increasing the afterload.
Another critical step which is commonly forgotten is the adequate preparation and maintenance of the apparatus and the perfusate. The precise volume of each compound must be mixed and the temperature within the system must be controlled and adjusted. Nevertheless, the WH is an elegant method to assess cardiac output, stroke volume, left ventricular systolic pressure and coronary flow simultaneously.
This highly reproducible procedure to induce MI and the representing data acquired by the WH apparatus are proving their capability themselves. The semi-minimally invasive approach, the level of LAD occlusion and intubation method facilitate fast recovery and low variability in infarct size. Additionally, cardiac function analysis in isolated working hearts provide valuable hemodynamic results.
The authors have nothing to disclose.
The authors thank the operation theater team and technicians of the Center for Biomedical Research for their contribution, technical assistance, valuable input and advice. The projects are funded by the Ludwig Boltzmann Institute, Cluster for Cardiovascular Research (REM project).
ANAESTHESIA & ANALGESIA | |||
Isoflurane | Zoetis | TU061219 / 8-00487 | |
Ketamine | Dr. E. Gräub AG | 100 mg/kg of bodyweight | |
Piritramide | Hameln-Pharma Plus GmbH | 2 ampulles with 30 ml of Glucose 5% in 250ml water | |
Xylazine | Bayer | 4 mg/kg of bodyweight | |
INTUBATION | |||
Air | |||
Oxygen (pure) | |||
Ventilation machine | Hugo Sachs Electronics | UGO Basile S.R.L. | Respirator |
14-gauge tube | Dickinson and Company | BD Venflon | |
PREPARATION | |||
Anti-septic povidine iodine solution | Mundipharma | Betaisodona solution | |
Eye ointment | Fresenius Kabi Austria | Oleovital with Vitamin A + Dexpanthenol | |
Shaver | |||
SURGICAL INSTRUMENTS | |||
Anatomical forceps | Martin | 12-272-15 | |
Anatomical forceps small | Martin | 24-386-16 | |
Anatomical forceps thin | Odelga | RU4042-15 | |
Cautery Fine Tip | High Temp | bvi-Accu-Temp | |
Cup (small, for liquids) | Martin | 56-231/11 | |
Mensur | MTI | 29-260/25 | |
Mosquito clamps | MTI | 05-055/12 | |
Needleholder short | Martin | 20-658-14 | |
Needleholder thin | Martin | ||
Round hook | BT-190 | ||
Scalpell size 3 | Swann Morton | No.10, 0301 | |
Scissors for tissue preparation | Aesculap | BC259R | |
Sharp scissors | MTI | 01-010/10 | |
Small retractor | Alm | AM.416.10 | |
Surcigal forceps | Martin | 12-321-13 | |
Surgical scissors | |||
SUTURES | |||
PermaHand Silk 4-0 | Johnson & Johnson Medical Products GmbH | K891H | |
Vicryl 4-0 | Johnson & Johnson Medical Products GmbH | JV2024 | single monofil suture |
Vicryl 6-0 | Johnson & Johnson Medical Products GmbH | V301G | polyethylene suture |
COMPUTER PROGRAMS & APPARATUS | |||
Labchart 7 Pro | ADInstruments | v7.3.2 | Labchart Software |
PowerLab System | ADInstruments | Powerlab 8/30 | |
EX VIVO HEMODYNAMICS | |||
Flowmeter Narcomatic RT-500 | Narco Bio-Systems | flow probe | |
Isolated heart apparatus | Hugo Sachs Electronics | ||
Labchart 7 Pro | ADInstruments GmbH | v7.3.2 | Labchart Software |
Millar SPR-407 | Millar Instruments Inc. | 840-4079 | high-fidelity MicroTip catheter |
Needle electrodes via Animal bio Amp | ADInstruments GmbH | MLA1203 | |
Physiological Pressure Transducer (MLT844) with Clip-on BP Domes | ADInstruments GmbH | MLT844 | |
PowerLab System | ADInstruments GmbH | Powerlab 8/30 |