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In this paper, we have provided a detailed procedure on the renal IRI model, subsequently highlighting that it is a robust model for the progression of AKI and AKI to CKD. In addition, we demonstrate the impact of the two main criteria of kidney injury, including kidney histology and function.
Several key points in surgical procedures need to be emphasized for a repeatable and reliable model. For abdominal surgery, a midline incision is recommended to expose the kidney to minimize trauma associated with the surgery. It is hard to dissect the renal pedicle entirely owing to the retroperitoneal fat, so, peel the renal pedicle from the fat with a pair of forceps via the kidney back and forth. Moreover, it is recommended to apply the same vascular clamp to maintain the stability of the surgical process and pay attention to whether there is wear on the vascular clamp during the procedure. In addition, it is also important to prevent dehydration of mice by giving saline supplementation, owing to the fluid loss that would contribute to kidney injury during surgery.
Several important troubleshooting methods need to be emphasized in the surgical procedures of IRI. First, it is difficult to troubleshoot kidney bleeding while separating the kidney and its pedicle. Most of the bleeding could be controlled by compressing the oozing point adequately, while bleeding volume > 0.5 mL may induce hemorrhagic shock. In this case, euthanize and exclude the mouse from research. Second, incomplete ischemia of the kidney is another aspect to pay attention to. Firstly, incomplete separation of the renal pedicle would lead to lesser ischemic injury. If the renal pedicle is not entirely isolated, the vascular clamp may cause incomplete occlusion, and the operator could change the vascular clamp to confirm complete ischemia of the kidney. Using the same vascular clamp during the procedure and renewing the worn clamp is recommended. Third, renal reperfusion disorder after vascular clamp removal may be due to vascular lesions or blood clot formation, euthanize and exclude such mice from research.
Several critical variables influence the severity of kidney injury in the IRI model. Ischemia time and body temperature are the main determinants of kidney injury. As previous studies reported, tubular injury have been found to be progressive after bilateral kidney ischemia for 25-30 min. Tubular injury aggravates significantly as the ischemic duration increases every 2 min, and an ischemic duration of more than 60 min may result in acute tubular necrosis16. Additionally, core body temperature significantly impacts the outcome in the IRI model. Unsurprisingly, mice with higher body temperatures (36-37 °C) have a more pronounced effect, while no obvious changes have been observed in mice with lower temperatures (33-35 °C) during ischemia8,17. The effect of body temperature on the severity of AKI is connected to metabolism: (1) increasing body temperature results in the damage of cell membranes and the decrease of intracellular energy stores during ischemia; (2) increasing inosine and hypoxanthine levels with higher body temperature produces an increased production of free radicals upon reperfusion18,19. Besides the duration of ischemia and body temperature, several factors should be taken into account for a consistent IRI model of AKI, such as mouse strain, age, gender, body weight, dehydration status, anesthesia, surgery time, and so on20,21. The above variable factors should be considered consistent in the experimental setup.
There are a few limitations in the current IRI-AKI model. First, a well-trained and skillful operator is essential to establish a consistent and reliable model of ischemic AKI, and systematic surgical training should be utilized for technical issues. Further, the severity of kidney injury on histological analysis in mouse IRI model is rarely observed in human AKI22; further exploration of this model is needed to match the state of human AKI. Moreover, mouse strain also affects susceptibility to AKI in the IRI model; it's important to establish IRI-AKI conditions for individual mouse lines.
In conclusion, the bilateral IRI-AKI model is a relative and consistent model for pathogenic investigation and therapeutic approaches. Notably, several critical points in surgical procedures are provided to ensure the transferability of this IRI model. Finally, we highlight that ischemia time and body temperature are the main determinants, and we also mention some additional factors that influence variation within the IRI model.