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W tym Artykule

  • Podsumowanie
  • Streszczenie
  • Wprowadzenie
  • Protokół
  • Wyniki
  • Dyskusje
  • Ujawnienia
  • Podziękowania
  • Materiały
  • Odniesienia
  • Przedruki i uprawnienia

Podsumowanie

This paper provides a detailed description of how to build an animal model of the anhepatic phase (liver ischemia) in rats to facilitate basic research into ischemia-reperfusion injury after liver transplantation.

Streszczenie

Orthotopic liver transplantation (OLT) in rats is a tried and proven animal model used for preoperative, intraoperative, and postoperative studies, including ischemia-reperfusion injury (IRI) of extrahepatic organs. This model requires numerous experiments and devices. The duration of anhepatic phase is closely related to the time to develop IRI after transplantation. In this experiment, we used hemodynamic changes to induce extrahepatic organ damage in rats and determined the maximum tolerance time. The time until the most severe organ injury varied for different organs. This method can easily be replicated and can also be used to study IRI of the extrahepatic organs after liver transplantation.

Wprowadzenie

Ischemia-reperfusion injury (IRI) is a common complication after liver transplantation. Hepatic IRI is a pathological process involving ischemia-mediated cell damage and abnormal deterioration of liver reperfusion. Hepatic IRI and the local innate immune response can be divided into hot and cold IRI, according to differences in the clinical environment1. Hot IRI is induced by stem cell injury, usually as a result of liver transplantation, shock, and trauma2. Cold IRI is a complication of liver transplantation caused by endothelial cells and peripheral circulation3. Clinical reports have shown that hepatic IRI is associated with 10% of early organ failures and may increase the incidence of acute and chronic rejection4,5. In addition, hepatic IRI may also induce multiple organ dysfunction syndromes or systemic inflammatory response syndrome, with high mortality6. Patients with extrahepatic organ involvement tend to stay longer in the hospital, spend more money, and have a worse prognosis7. The development of complications is closely related to the length of the anhepatic phase of liver transplantation8.

Orthotopic liver transplantation (OLT) in rats was first reported by the American professor Lee in 1973. The experimental operation simulated the steps of clinical liver transplantation and the anastomosis of blood vessels and the common bile duct (CBD) using the suture method. The procedure is difficult and time-consuming with a low rate of success9. In 1979, Kamada et al. made a significant improvement to OLT in rats by creatively using the 'two-cuff method' for anastomosis of the portal vein to control the anhepatic phase within 26 minutes10. In the same year, Zimmermann proposed the 'single biliary stent method.' On the basis of Lee's work, Zimmermann used polyethylene tubes to directly anastomose the CBD of the donor and recipient, simplified the reconstruction of CBD, and preserved the function of the sphincter, and this method became the standard for biliary reconstruction of OLT models11. In 1980, Miyata et al. proposed the 'three-cuff method' where the portal vein (PV), suprahepatic vena cava (SVC), and intrahepatic vena cava (IVC) were anastomosed by the cuff method. However, there is a risk of distortion of the cannula with this method, which can lead to the obstruction of inferior vena cava reflux12. In 1983, the 'two-cuff method' was proposed using the cuff method for anastomosis of the PV and IVC, but adopting the suture method for the SVC13. This method was adopted by scholars globally to establish OLT models. Since then, the cuff anastomosis steps have been improved to shorten the anhepatic phase and improve the survival rate of the rats14. Similarly, improved methods are used in clinical practice to shorten the anhepatic phase15. However, basic research into IRI after liver transplantation has shown that the survival rate is inversely related to the degree of injury to extrahepatic organs. Therefore, further research is required, and a simple and reproducible animal model is needed to simulate IRI after liver transplantation.

Based on the definition of the anhepatic phase, we simulated the hemodynamic changes in liver transplantation resulting in IRI of extrahepatic organs in rats. Herein, we provide a detailed description of how to build an animal model of the anhepatic phase (liver ischemia) in rats to facilitate basic research into IRI after liver transplantation.

Protokół

The Animal Ethics Committee approved the experiment of Guangxi Medical University (No20190920). All animals were supplied by the Animal Experiment Center of Guangxi Medical University. We used SPF male Sprague Dawley rats (200-250 g, 10-12 weeks), kept under the room temperature of 25 ± 2°C and humidity of 50 ± 10%. Feeding was stopped 24 hours before operation; however, water was provided.

NOTE: One operator can perform all operations without a microsurgery basis or surgical microscope.

1. Operation

  1. After weighing, anesthetize the rats with isoflurane (5%) using an animal anesthesia machine.
  2. After 1-2 minutes, gently clamp the toes of the rat with tweezers. If the rat does not respond after pinching, it has entered a state of anesthesia. Use vet ointment on the eyes to prevent dryness. Use animal heating lamps to keep the rats' body temperature at 37-38 °C.
  3. Following abdominal disinfection (povidone iodine solution), fix the rat on the animal dissection table. Make a median incision of 3 cm below the xiphoid process using forceps and scissors.
  4. Open the abdominal cavity, expose the liver using a retractor, and mobilize the hepatogastric ligament. Use cotton swabs to flip the middle lobe of the liver gently and turn it upward to expose the porta hepatis. Identify the CBD, PV, and HA.
  5. Push the small intestine toward the left lower abdominal cavity using cotton swabs, cover it with wet gauze, and move the intrahepatic vena cava to the right renal vein.
  6. Isolate the portal vein, hepatic artery, and the inferior vena cava above the right renal vein with an intraocular lens and forceps marked with 3-0 silk thread, each with a slip knot.
  7. Cut open the left and right lower extremity skin and expose the femoral vein using ophthalmic forceps. Slowly inject low molecular weight heparin 625 IU/kg through the femoral vein to heparinize the whole body.
  8. Ligate the portal vein, hepatic artery, and inferior vena cava above the right renal vein with No. 3-0 sutures, lasting 45 minutes (Figure 1). Replace the small intestine in the abdominal cavity and cover it with gauze. Reduce inhalation anesthesia during these periods.
  9. After 45 minutes, release the portal vein, hepatic artery, and the inferior vena cava above the right renal vein.
  10. Suture the muscle and skin, layer by layer, and terminate the inhalational anesthesia. Provide postoperative analgesia using subcutaneous morphine of 5 mg/kg every 4 hours.
  11. Observe the rat until it is awake and feed under a temperature of 25 ± 2 °C and humidity of 50 ± 10%. Animal heating lamps are necessary.

Wyniki

Rats' tolerance to liver ischemia
In this animal model, the sites at which blood vessels were ligated during operating are shown in Figure 1. The rats were randomly divided into 5 groups for ischemia for 15 minutes (I15 group), 30 minutes (I30 group), 45 minutes (I45 group), 60 minutes (I60), and sham group, with 10 rats in each group. The survival rate of each group was observed 14 days after the operation. All rats survived in the I15 group, I30 group, and sham g...

Dyskusje

OLT in rats is an ideal model for studying organ preservation in liver transplantation, IRI, transplant rejection, immune tolerance, transplantation pathology and pharmacology, homotransplantation, and xenotransplantation. At present, it is widely used in the experimental research of liver transplantation.

During pilot studies we first administered pentobarbital sodium intraperitoneal anesthesia and found that this led to high postoperative mortality and short tolerance to hemodynamic changes....

Ujawnienia

The authors of this manuscript have no conflicts of interest to disclose.

Podziękowania

We would like to acknowledge the useful suggestions given by Dr. Wen-tao Li and Dr. Ji-hua Wu of the Second Affiliated Hospital of Guangxi Medical University. The authors would like to thank our team-mates for useful comments and discussions. The authors would also like to thank the anonymous reviewers and editors of JoVE for their comments. Special thanks should go to Dr Yuan's parents for their continuous support and encouragement. The work was supported by Ningbo Natural Science Foundation (2014A610248).

Materiały

NameCompanyCatalog NumberComments
4% paraformaldehyde solutionShanghai Macklin Biochemical Co.,LtdP804536
air drying ovenShanghai Binglin Electronic Technology Co., Ltd.BPG
Alanine aminotransferase (ALT)KitElabscience Biotechnology Co.,LtdE-BC-K235-S
ammoniaSinopharm Chemical Reagents Co. Ltd10002118
amylase KitElabscience Biotechnology Co.,LtdE-BC-K005-M
anhydrous ethanolSinopharm Chemical Reagents Co. Ltd100092183
Animal anesthesia machineShenzhen Ruiwode Life Technology Co. LtdR640
aspartate aminotransferase (AST)kitRayto Life and Analytical Sciences Co., Ltd.S03040
automatic biochemical analyzer.SIEMENS AG FWB:SIE, NYSE:SI Co., Ltd.2400
Biosystems (when nessary)Chengdu Taimeng Electronics Co., Ltd.BL-420F
CentrifugeBaiyang Medical Instrument Co., Ltd.BY-600A
cover glassJiangsu Shitai Experimental Equipment Co. Ltd10212432C
creatinine KitRayto Life and Analytical Sciences Co., Ltd.S03076
dewatering machineHungary 3DHISTECH Co.,LtdDonatello Series 2
embedding machineHubei Xiaogan Kuohai Medical Technology Co., Ltd.KH-BL1
frozen machineWuhan Junjie Electronics Co., LtdJB-L5
hematoxylin-eosin dye solutionWuhan Saiwell Biotechnology Co., LtdG1005
high-efficiency paraffin waxShanghai huayong paraffin wax co., LtdQ/YSQN40-91
hydrochloric acidSinopharm Chemical Reagents Co. Ltd10011018
intraocular lens (IOL)forcepsGuangzhou Guangmei Medical Equipment Co., Ltd.JTZRN
IsofluraneShenzhen Ruiwode Life Technology Co. Ltd
micro Scissors(when nessary)Shanghai Surgical Instrument FactoryWA1010
needle holdersShanghai Surgical Instrument FactoryJ32010
neutral gumShanghai Huashen Healing Equipment Co.,Ltd.
normal optical microscopeNikon Instrument Shanghai Co., LtdNikon Eclipse CI
ophthalmic forcepsShanghai Surgical Instrument FactoryJ3CO30straight
ophthalmic forcepsShanghai Surgical Instrument FactoryJD1060bending
ophthalmic ScissorsShanghai Surgical Instrument FactoryJ1E0
pathological slicerShanghai Leica Instrument Co., LtdRM2016
pipettesDragon Laboratory Instruments Co., Ltd.7010101008
retractorsBeijing Jinuotai Technology Development Co.,Ltd.JNT-KXQ
scannerHungary 3DHISTECH Co.,LtdPannoramic 250
slideWuhan Saiwell Biotechnology Co., LtdG6004
xyleneSinopharm Chemical Reagents Co. Ltd1330-20-7

Odniesienia

  1. Dar, W. A., Sullivan, E., Byon, J. S., Eltzschig, H., Ju, C. Ischaemia reperfusion injury in liver transplantation: Cellular and molecular mechanisms. Liver International. 39 (5), 788-801 (2019).
  2. Qiao, P. F., Yao, L., Zhang, X. C., Li, G. D., Wu, D. Q. Heat shock pretreatment improves stem cell repair following ischemia-reperfusion injury via autophagy. World Journal of Gastroenterology. 21 (45), 12822-12834 (2015).
  3. Liu, Y., et al. Activation of YAP attenuates hepatic damage and fibrosis in liver ischemia-reperfusion injury. Journal of Hepatology. 71 (4), 719-730 (2019).
  4. Hirao, H., Dery, K. J., Kageyama, S., Nakamura, K., Kupiec-Weglinski, J. W. Heme Oxygenase-1 in liver transplant ischemia-reperfusion injury: From bench-to-bedside. Free Radical Biology and Medicine. 157, 75-82 (2020).
  5. Motiño, O., et al. Protective role of hepatocyte cyclooxygenase-2 expression against liver ischemia-reperfusion injury in mice. Hepatology. 70 (2), 650-665 (2019).
  6. Guo, W. A. The search for a magic bullet to fight multiple organ failure secondary to ischemia/reperfusion injury and abdominal compartment syndrome. Journal of Surgical Research. 184 (2), 792-793 (2013).
  7. Elham, M., Mahmoudi, M., Nassiri-Toosi, M., Baghfalaki, T., Zeraati, H. Post liver transplantation survival and related prognostic factors among adult recipients in tehran liver transplant center; 2002-2019. Archives of Iranian Medicine. 1 (23), 326-334 (2020).
  8. Kim, E. H., Ko, J. S., Gwak, M. S., Lee, S. K., Kim, G. S. Incidence and clinical significance of hyperfibrinolysis during living donor liver transplantation. Blood Coagulation and Fibrinolysis. 29 (3), 322-326 (2018).
  9. Czigány, Z. Improving research practice in rat orthotopic and partial orthotopic liver transplantation: a review, recommendation, and publication guide. European Surgical Research. 55 (1-2), 119-138 (2015).
  10. Kamada, N., Calne, R. Y. Orthotopic liver transplantation in the rat. Technique using cuff for portal vein anastomosis and biliary drainage. Transplantation. 28 (1), 47-50 (1979).
  11. Zimmermann, F. A., et al. Techniques for orthotopic liver transplantation in the rat and some studies of the immunologic responses to fully allogeneic liver grafts. Transplantation Proceedings. 11 (1), 571-577 (1979).
  12. Miyata, M., Fischer, J. H., Fuhs, M., Isselhard, W., Kasai, Y. A simple method for orthotopic liver transplantation in the rat. Cuff technique for three vascular anastomoses. Transplantation. 30 (5), 335-338 (1980).
  13. Kamada, N. A., Calne, R. Y. Surgical experience with five hundred thirty liver transplants in the rat. Surgery. 93 (1), 64-69 (1983).
  14. Yang, L. F., et al. A rat model of orthotopic liver transplantation using a novel magnetic anastomosis technique for suprahepatic vena cava reconstruction. Journal of Visualized Experiments. 19 (133), e56933 (2018).
  15. Liu, L. X., He, C., Huang, T., Gu, J. Development of a new technique for reconstruction of hepatic artery during liver transplantation in sprague-dawley rat. PLoS One. 10 (12), 0145662 (2015).
  16. Paller, M. S., Hoidal, J. R., Ferris, T. F. Oxygen free radicals in ischemic acute renal failure In the rat. Journal of Clinical Investigation. 74 (4), 1156-1164 (1984).
  17. Schmidt, J., Lewandrowsi, K., Warshaw, A. L., Compton, C. C., Rattner, D. W. Morphometric characteristics and homogeneity of a new model of acute pancreatitis in the rat. International Journal of Pancreatology. 12 (1), 41-51 (1992).
  18. Chui, C. J., McArdle, A. H., Brown, R., Scott, H. J., Gurd, F. N. Intestinal mucosal lesion in low-flow states. I. A morphological, hemodynamic, and metabolic reappraisal. Archives of Surgery. 101 (4), 478-483 (1970).
  19. Kozian, A., et al. One-lung ventilation induces hyperfusion and alveolar damage in the ventilated lung:an experimental study. British Journal of Anaesthesia. 100 (4), 549-559 (2008).
  20. Shimada, S., et al. Heavy water (D2O) containing preservation solution reduces hepatic cold preservation and reperfusion injury in an isolated perfused rat liver (IPRL) model. Journal of Clinical Medicine. 8 (11), 1818 (2019).
  21. Nakamura, K. Sirtuin 1 attenuates inflammation and hepatocellular damage in liver transplant ischemia/reperfusion: from mouse to human. Liver Transplantation. 23 (10), 1282-1293 (2017).
  22. Blaire, A., et al. Surgical Considerations of Hilar Cholangiocarcinoma. Surgical Oncology Clinics of North America. 28 (4), 601-617 (2019).

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Ischemia reperfusion InjuryHemodynamic ChangesRat Liver Transplant ModelLiver TransplantationAnhepatic PhaseExtrahepatic Organ InvolvementSurgical TechniquesAnimal ModelSurvival RateDr Yuan YuanSurgical InstrumentsAnesthesiaPathological AnalysisBiochemical AssaysHepatogastric LigamentPorta Hepatis

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