OBJECTIVEA general review was made of studies involving: (1) The experimental evidence of remote ischemic preconditioning (RIPC) and relative clinical studies, (2) The experimental and clinical evidences of remote ischemic postconditioning (RIPOC), (3) The potential mechanistic pathways underlying their protective effects.

DATA SOURCESThe data used in this review were mainly from manuscripts listed in PubMed that were published in English from 1986 to 2010. The search terms were "myocardial ischemia reperfusion injury", "ischemia preconditioning", "ischemia postconditioning", "remote preconditioning" and "remote postconditioning".

STUDY SELECTION(1) Clinical and experimental evidence that both RIPC and RIPOC produce preservation of ischemia reperfusion injury (IRI) of myocardium and other organs, (2) Studies related to the potential mechanisms, by which remote ischemic conditioning protects myocardium against IRI.

RESULTSBoth RIPC and RIOPC have been shown to attenuate myocardial IRI in laboratory animals. Also, their cardioprotective effects have appeared in some clinical studies. Except the external, the detailed internal mechanisms of remote ischemic conditioning have been generally described. Through these descriptions better protocols can be developed to provide improved cardioprotective procedures.

CONCLUSIONSRemote ischemic conditioning is an endogenous cardioprotective mechanism from outside the heart that protects against myocardial IRI and represents a general form of inter-organ protection. Remote ischemic conditioning may have an immense impact on clinical practice in the near future.

Ischemic tolerance exists in many organs, among which the cerebral ischemic tolerance and its potential clinical applications are most notable. The discovery of new triggers of cerebral ischemic tolerance has brought more interesting insights into the molecular mechanisms. The remote ischemic preconditioning and pharmacological induction of cerebral ischemic tolerance have shown promising clinical safety and feasibility, and therefore may be important breakthroughs in the clinical application of cerebral ischemic tolerance.
Brain Ischemia ; physiopathology ; Erythropoietin ; therapeutic use ; Humans ; Ischemic Preconditioning ; methods

"Treatment for before sick" is a theory of TCM, reflecting preventing thought of "prevention being better than cure" and "nipping in the bud", while "moxibustion treatment for before sick" is highly praised by doctors of past ages. Moxibustion can activate human vital-qi and increase immunologic function of the organism, playing a preventive role for before sick, which is similar to the essence of "ischemic preconditioning" raised in recent years. Because of convenient manipulation, no adverse effect, it has very important position in the field of preventive medicine.
Acupuncture Points ; Humans ; Ischemic Preconditioning ; Moxibustion ; methods ; Preventive Medicine

The concept of "ischemic postconditioning" was first raised in 2002, and the following 5 year research shows that it can protect organs from reperfusion injury. Although the mechanism of ischemic postconditioning is similar to ischemic preconditioning in many ways, it still has its own characteristics. Reperfusion injury is an inevitable problem in organ transplantation. It may accelerate the function recovery of the transplants to lessen the reperfusion injury. So ischemic postconditioning may have a fine prospect in organ transplantation for its good controllability during reperfusion. This article is going to briefly introduce the distinct mechanisms of ischemic postconditioning to protect organs from reperfusion injury and approach the possibilities of its application in organ transplantation.
Animals ; Humans ; Ischemic Preconditioning ; Ischemic Preconditioning, Myocardial ; Myocardial Reperfusion Injury ; pathology ; prevention & control ; Organ Transplantation ; adverse effects ; methods ; Reperfusion Injury ; prevention & control

BACKGROUND: The aim of this study was to investigate the effects of remote ischemic conditioning on ischemia-reperfusion injury in rat muscle flaps histopathologically and biochemically. METHODS: Thirty albino rats were divided into 5 groups. No procedure was performed in the rats in group 1, and only blood samples were taken. A gracilis muscle flap was elevated in all the other groups. Microclamps were applied to the vascular pedicle for 4 hours in order to achieve tissue ischemia. In group 2, no additional procedure was performed. In groups 3, 4, and 5, the right hind limb was used and 3 cycles of ischemia-reperfusion for 5 minutes each (total, 30 minutes) was applied with a latex tourniquet (remote ischemic conditioning). In group 3, this procedure was performed before flap elevation (remote ischemic preconditoning). In group 4, the procedure was performed 4 hours after flap ischemia (remote ischemic postconditioning). In group 5, the procedure was performed after the flap was elevated, during the muscle flap ischemia episode (remote ischemic perconditioning). RESULTS: The histopathological damage score in all remote conditioning ischemia groups was lower than in the ischemic-reperfusion group. The lowest histopathological damage score was observed in group 5 (remote ischemic perconditioning). CONCLUSIONS: The nitric oxide levels were higher in the blood samples obtained from the remote ischemic perconditioning group. This study showed the effectiveness of remote ischemic conditioning procedures and compared their usefulness for preventing ischemia-reperfusion injury in muscle flaps.
Animals ; Extremities ; Ischemia ; Ischemic Preconditioning ; Latex ; Methods* ; Nitric Oxide ; Rats* ; Reperfusion Injury* ; Tourniquets

BACKGROUND: The aim of this study was to investigate the effects of remote ischemic conditioning on ischemia-reperfusion injury in rat muscle flaps histopathologically and biochemically. METHODS: Thirty albino rats were divided into 5 groups. No procedure was performed in the rats in group 1, and only blood samples were taken. A gracilis muscle flap was elevated in all the other groups. Microclamps were applied to the vascular pedicle for 4 hours in order to achieve tissue ischemia. In group 2, no additional procedure was performed. In groups 3, 4, and 5, the right hind limb was used and 3 cycles of ischemia-reperfusion for 5 minutes each (total, 30 minutes) was applied with a latex tourniquet (remote ischemic conditioning). In group 3, this procedure was performed before flap elevation (remote ischemic preconditoning). In group 4, the procedure was performed 4 hours after flap ischemia (remote ischemic postconditioning). In group 5, the procedure was performed after the flap was elevated, during the muscle flap ischemia episode (remote ischemic perconditioning). RESULTS: The histopathological damage score in all remote conditioning ischemia groups was lower than in the ischemic-reperfusion group. The lowest histopathological damage score was observed in group 5 (remote ischemic perconditioning). CONCLUSIONS: The nitric oxide levels were higher in the blood samples obtained from the remote ischemic perconditioning group. This study showed the effectiveness of remote ischemic conditioning procedures and compared their usefulness for preventing ischemia-reperfusion injury in muscle flaps.
Animals ; Extremities ; Ischemia ; Ischemic Preconditioning ; Latex ; Methods* ; Nitric Oxide ; Rats* ; Reperfusion Injury* ; Tourniquets

This study observed the protective effect of hypercapnic acidosis preconditioning on rabbit heart suffered from ischemia-reperfusion injury. Hypercapnic acidosis was established in animals with mechanical hypoventilation before ischemia-reperfusion. Thirty-two rabbits were randomly divided into 4 groups, with each having 8 animals in term of the degree of acidification: hypercapnic acidosis group A (group A), hypercapnic acidosis group B (group B), hypercapnic acidosis group C (group C), ischemia and reperfusion group (group IR). Animals in group IR were ventilated normally (tidal volume: 15 mL/kg, breathing rate 35 bpm). The PETCO(2) was maintained at the level of 40-50 mmHg for 30 min. Animals in groups A, B, C received low-frequency, low-volume ventilation to achieve hypercarbonic acidosis and the target levels of PETCO(2) were 75-85,65-75, 55-65 mmHg, respectively, with levels being maintained for 5 min. The animals then were ventilated normally to lower PETCO(2) to 40-50 mmHg. The left anterior branch artery of all the animals was ligated for 30 min and reperfused for 180 min. Then the infarct size was calculated. The cardiomyocytes were morphologically observed and ECG and hemodynamics were monitored on continuous basis. Acid-base balance was measured during procedure. Our results showed that the infarct size was (48.5+/-11.5)% of the risk area in the control group and (42.4+/-7.9)% in group C (P>0.05). Mean infarct size was significantly smaller in group B (34.5%+/-9.4%) (P<0.05 vs control group) and group A (31.0%+/-9.1%) (P<0.01 vs control group). It is concluded that HA-preconditioning can effectively protect the myocardium.
Acidosis, Respiratory/*physiopathology ; Hypercapnia/*physiopathology ; Ischemic Preconditioning, Myocardial/*methods ; Myocardial Reperfusion Injury/*prevention & control ; Random Allocation

Animals ; Disease Models, Animal ; Ischemic Preconditioning, Myocardial ; methods ; Myocardial Reperfusion Injury ; prevention & control ; Rats ; Rats, Wistar

Female ; Humans ; Ischemic Preconditioning, Myocardial ; methods ; Male ; Myocardial Reperfusion Injury ; prevention & control

Animals ; Humans ; Ischemic Preconditioning, Myocardial ; methods ; Myocardial Ischemia ; complications ; therapy ; Myocardial Reperfusion ; methods ; Myocardial Reperfusion Injury ; etiology ; prevention & control