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In This Article

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

Summary

We present a protocol for establishing a long-term awake extracorporeal membrane oxygenation (ECMO) model in sheep. Special attention is given to the management and evaluation of the coagulation system during the ECMO model.

Abstract

This study aimed to investigate the effects of long-term awake extracorporeal membrane oxygenation (ECMO) on the coagulation system in a sheep model. A total of ten healthy sheep were included in the study, with 5 sheep in each group. In the veno-arterial ECMO (V-A ECMO) group, cannulation was performed in the right carotid artery and the right external jugular vein. In the veno-venous ECMO (V-V ECMO) group, a dual-lumen catheter was utilized to insert into the right external jugular vein. After initiating ECMO, the sheep were recovered from anesthesia and remained awake for 7 days. The target activated clotting time (ACT) goal was set at 220-250 s. In both groups, the actual ACT fluctuated around 250 s with the dose of heparin gradually increasing, reaching almost 60 IU/kg/min at the end of the experiments. Moreover, the activated partial thromboplastin time (APTT) and thrombin time (TT) values were significantly higher in the V-A ECMO group compared to the V-V ECMO group, despite receiving the same doses of heparin. Although laboratory test results fluctuated within a normal and reasonable range, infarct foci in the kidneys were observed in both groups at the end of the study.

Introduction

Extracorporeal membrane oxygenation (ECMO) serves as a life-saving intervention, providing cardiopulmonary support for severely ill patients. It is classified into two primary forms: veno-arterial ECMO (V-A ECMO) and veno-venous ECMO (V-V ECMO)1,2. V-A ECMO is employed for patients experiencing circulatory failure, whereas V-V ECMO is preferred for those with respiratory failure but without severe cardiovascular dysfunction3,4.

Thrombosis and bleeding are prevalent complications in ECMO patients5. The ECMO circuit exposes blood to artificial surfaces, initiating complex coagulation responses6. These processes can lead to endothelial damage and microcirculation disorders, resulting in subsequent dysfunction in vital organs7,8. Consequently, effective systemic anticoagulation management is considered crucial for ECMO patients. Despite this, there remains a lack of evidence to guide anticoagulation strategies in various ECMO-related clinical settings.

The establishment of a stable ECMO animal model can provide insights into the impact of ECMO on the body, contributing significantly to the optimization of ECMO management strategies, reduction of ECMO-related complications, and improvement of patient outcomes in clinical practice. Large animals, such as sheep and pigs, are the primary choices for establishing ECMO models due to their physiological parameters closely resembling those of humans9,10. However, previous large animal ECMO models had a maintenance time of less than 24 h, making it challenging to comprehensively evaluate the impact of ECMO on the coagulation system11. Therefore, there is a need to establish long-term ECMO large animal models to thoroughly explore the pathophysiological mechanisms of ECMO. Utilizing long-term large animal models to investigate the effects of ECMO on the coagulation system can provide more robust evidence for clinical practice.

This study aims to establish a long-term (7 days) awake V-A and V-V ECMO model in healthy sheep. The central focus of the entire model establishment and evaluation is the management of anticoagulation.

Protocol

This experimental protocol received approval from the Institutional Animal Care and Use Committee of Fuwai Hospital (no. 0101-2-20-HX(X)). All procedures adhered to the guidelines outlined in the National Institutes of Health's Guide for the Use and Care of Laboratory Animals. The experiment took place at the Beijing Key Laboratory of Pre-clinical Research and Evaluation for Cardiovascular Implant Materials, Animal Experimental Center of Fuwai Hospital (registration no. CNAS LA0009). Healthy sheep that met the required quarantine standards at the Animal Experimental Center of Fuwai Hospital were utilized in the study. Furthermore, this research followed the Animal Research: Reporting of In Vivo Experiments guidelines. Male Small Tail Han sheep with a weight range of 50-65 kg and an age range of 12-24 months (see Table of Materials) were housed in a specific pathogen-free environment with free access to food and water for at least one week before the surgery. The sheep were randomly assigned to two groups, each consisting of 5 individuals: the Veno-Arterial ECMO (V-A ECMO) group and the Veno-Venous ECMO (V-V ECMO) group. The selection of healthy sheep was justified by the necessity to precisely assess the effects of ECMO support on the organism. The equipment and reagents used in the study are listed in the Table of Materials.

1. Animal preparation

  1. Before the surgical procedure, fast healthy adult sheep for 48 h and deprive them of water for 12 h.
  2. Sterilize the surgical instruments and ECMO parameters before the surgery. Ensure the provision of personal protective equipment for all members of the surgical team, including surgical caps, disposable facemasks, clean surgical attire, shoe covers, sterile operating clothes, and sterile gloves.
  3. Administer a propofol injection (5 mg/kg) through the auricular vein. As previously described, fix the blood pressure cuff on the thigh and place electrocardiogram leads on all four limbs. Connect the blood pressure cuff and ECG leads to the medical monitor for ECG and non-invasive blood pressure measurement12.
  4. Insert a single-lumen endotracheal tube into the trachea and connect the tube to the ventilator with volume-controlled mode. Set the parameters as follows: tidal volume: 8-10 mL/kg, respiratory rate: 12-20/min, initial fraction of inspiration oxygen (FiO2): 60%.
  5. Administer a combination of intravenous anesthesia (propofol, 8-10 mg/kg/h) and inhaled anesthesia (isoflurane 2%-3%) for anesthesia maintenance. Provide intermittent flurbiprofen (1-2 mg/kg) intravenously for intraoperative analgesia.
  6. Place the sheep on the operating table and secure their limbs with a flexible cloth belt. Proceed to isolate the left carotid artery and jugular vein and insert a single-lumen central venous catheter (18 Fr) and a triple-lumen central venous catheter (7 Fr), respectively. Connect the 18 G catheter on the left carotid artery to the medical monitor for hemodynamic monitoring. Connect the 7 Fr triple-lumen central venous catheter on the left jugular vein to the infusion pump and medical monitor for simultaneous intravenous fluid administration, drug injection, and central venous pressure monitoring. Make all connections using the three-way stopcocks. Withdraw venous or arterial blood samples via three-way stopcock.
    NOTE: After catheter insertion, ligate the catheter and vessel with 2-0 surgical sutures.
  7. Expose the right jugular artery and vein. Achieve systemic anticoagulation with a bolus of heparin (120 IU/kg) through the right jugular vein.
    NOTE: The target activated clotting time (ACT) for cannulation is above 250s.

2. Cannulation

  1. V-A ECMO circuit establishment: Insert an arterial catheter (18 Fr) through the right carotid artery to a depth of 10-15 cm and a venous catheter (24 Fr) through the right external jugular vein to the right atrium.
  2. V-V ECMO circuit establishment: Expose the right external jugular vein and insert a dual-lumen catheter (23 Fr) through the right external jugular vein.
    NOTE: During this procedure, maintain the blood pressure and heart rate of sheep within Β±20% of the baseline values. Keep the partial pressure of arterial carbon dioxide (PaCO2) between 35-40 mmHg. Ensure the partial pressure of end-tidal carbon dioxide (EtCO2) remains between 35-45 mmHg. Adjust the depth of anesthesia when encountering variations in blood pressure and heart rate in sheep. If this proves ineffective or in emergencies, consider using vasoactive drugs. Maintain PaCO2 and EtCO2 within normal values by adjusting ventilator parameters, with a primary focus on tidal volume and respiratory rate.
  3. In V-V ECMO, pass the catheter tip through the right atrium (RA) and position it within the inferior vena cava (IVC). Direct the outflow port of the dual-lumen catheter towards the tricuspid valve (confirm position with ultrasound assistance).
    NOTE: After catheter insertion, ligate the catheter and vessel with 2-0 surgical sutures. Close the skin incision using 4-0 surgical sutures.

3. Initiation of ECMO

  1. Connect all ECMO devices following the manufacturer's instructions (see Table of Materials). Ensure there are no leaks.
    NOTE: Follow aseptic principles during the connection.
  2. The priming solution consists of normal saline (1000 mL) with 2000 IU of heparin. After manually infusing the priming solution into the ECMO circuit and ensuring no air bubbles in the circuit, start the centrifugal pump for priming (1000-1500 rpm).
  3. After priming is complete, turn off the centrifugal pump. Connect the inflow catheter to the inlet of the centrifugal pump and connect the outflow catheter to the outlet of the oxygenator. Make all connections using the three-way stopcocks. Exhaust the air at the connection through the three-way stopcock. Attach the oxygen source to the ECMO system, ensuring correct oxygen flow. Then start the centrifugal pump for ECMO run. Set the initial pump flow at 2.0 L/min with a pump speed of 3000 rpm.
  4. Half-loop the ECMO circuit tube line around the sheep's neck to prevent displacement or kinking.

4. Postoperative management and monitoring

  1. Transfer the sheep to a metabolic cage and restrain the sheep appropriately after completing the operation.
    NOTE: Secure the head and shoulders of the sheep with particular emphasis on preventing displacement or kinking of the cannula. Gradually reduce the depth of anesthesia. Ensure personal protection for the members of the postoperative nursing team by wearing protective gear (sterile clothes, gloves, masks, and caps).
  2. When ensuring stable respiration and blood gas analysis results, remove the endotracheal tube.
  3. In the initial 24 h post-surgery, administer flurbiprofen (1-2 mg/kg) and dexmedetomidine (0.2-0.3 Β΅g/kgΒ·h) intravenously for sedation and pain relief.
    NOTE: After the first 24 h, consider sedative and analgesic drugs if there is agitation and blood pressure fluctuation in sheep due to postoperative pain.
  4. Inside the monitoring cage, ensure that the sheep move freely within a certain range and have unrestricted access to a suitable amount of feed and water.
  5. Keep a continuous real-time check on fundamental vital signs (heart rate and arterial blood pressure) along with ECMO hydraulic parameters (pump flow, pump speed, pre-pump pressure, post-pump pressure, and post-oxygenator pressure).
    NOTE: Set target parameters for ECMO management (pump flow: 2.0-2.5 L/min, pump speed: 3000-3500 rpm, oxygen flow rate: 1.0-1.5 L/min with an FiO2 of 50%-80%). Adjust the above parameters according to blood gas results.
  6. Measure blood gases and ACT every 6 h and monitor blood count, blood chemistry, and coagulation tests daily. Adjust anticoagulation strategy based on coagulation indicators.
    NOTE: The target ACT goal: 220-250 s.
  7. Adjust intravenous infusions based on fluid balance to maintain central venous pressure (CVP) between 5-12 cm H2O. Administer cefuroxime sodium (1.5 g, i.v., b.i.d.) daily for infection prevention. Conduct daily incision disinfection and closely monitor for signs of infection or bleeding.

5. Euthanasia

  1. After a 7-day experimental period, remove the ECMO circuit.
  2. Administer an intravenous injection of potassium chloride (100 mg/kg) for euthanasia under sedation with propofol (20 mg/kg).
    NOTE: After euthanasia, the main organs (heart, kidney, lung, liver, brain, and intestine) were collected and visually checked for the presence of infarcts, hemorrhages, or overt damage. All organ injuries were recorded in detail. Then, the organs were cut into small pieces and fixed in 4% formaldehyde, embedded with paraffin, and divided into 4 Β΅m sections for hematoxylin-eosin (HE) staining13. Conduct Histological examination for HE sections under a light microscope by at least two pathologists independently.

Results

A total of ten sheep were evaluated during the entire experiment, with five sheep in each group (Table 1). Following the initiation of ECMO, all sheep recovered from anesthesia and remained awake for 7 days. In both groups, ECMO flow exceeded 1.8 L/min. In the V-V ECMO group, the flow fluctuated around 1.8 L/min, while in the V-A ECMO group, it ranged from 2.3 L/min to 1.8 L/min (Figure 1A). The vital signs of each sheep remained stable. The blood lactic acid level was below...

Discussion

This study outlines the procedure for establishing robust, long-term survival models for V-V and V-A ECMO in sheep. All surviving animals exhibited stable vital signs, and no severe bleeding or coagulation events occurred. ECMO flow and oxygenation performance remained stable, with no major pathological injuries observed. The study provides detailed information on anticoagulation management.

Anticoagulation management plays a crucial role in ECMO perioperative care. Initially, based on previou...

Disclosures

The authors have nothing to disclose.

Acknowledgements

None.

Materials

NameCompanyCatalog NumberComments
ACT analyzerHemochron, USAJr Signature
Anaesthesia machineDrager, GermanyΒ Primus
Arterial catheterEdwards Lifescience, USA18-FrProvide return access into an artery for VA-EMCO
Blood chemistry analyzerIDEXX Laboratories, USAΒ Catalyst One
Blood gas analyzerAbbott, USAAbbott i-STAT1
Centrifugal pumpJiangsu STMed Technologies, ChinaSTM CP-24 I
Centrifugal pump drive and consoleJiangsu STMed Technologies, ChinaOASSIST STM001
Coagulation test analyzerBeijing Succeeder Technology, ChinaSF-8050
Complete blood count analyzerSiemens Healthcare, GermanyADVIA 2120i
Dual-channel micro-injection pumpZhejiang Smith Medical Instrument, ChinaWZS-50F6
Dual-lumen catheterMAQUET Avalon Elite, Germany23-FrProvide return and drainage accesses into the right external jugular vein for VV-ECMO
FlurbiprofenBeijing Tide Pharmaceutical Co., Ltd., China5ml: 50mg
GraphPad softwareGraphPad Software, USAGraphPad Prism v9.0Statistical analysis
HeparinΒ Shanghai Shangyao No.1 Biochemical Pharmaceutical Co., Ltd., China2ml: 12500IU
High-frequency electrosurgicalCOVIDIEN, USAForce F
Multi-parameter medical monitorPhilips, NetherlandsMP60
Oxygenator kitMedos, GermanyHilite 7000LT
Oxygenator kitMaquet, GermanyBE-PLS 2050
PropofolΒ Β Xi’an Libang Pharmaceutical Co. Ltd, China20ml: 0.2g
Single-lumen central venous catheterTuoRen, China18FrInsert in left carotid arteryΒ  for hemodynamic monitoring and blood sampling.
Small Tail Han sheepJinyutongfeng Commercial and Trade Co. Ltd, Chinaweight: 50-65 kg, age: 12-24 months
Triple-lumen central venous catheterTuoRen, China7FrInsert in left jugular vein for intravenous fluid administration, drug injection, and blood sampling.
Ultrasound machineGE, USAE9
Venous catheterEdwards Lifescience, USA24-FrProvide the drainage access into a vein for VA-ECMO
VentilatorDrager, GermanyΒ Savina

References

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