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Reperfusion injury

Reperfusion injury, also known as ischemia-reperfusion injury (IRI), refers to the paradoxical exacerbation of cellular dysfunction and death that occurs when flow is restored to ischemic tissues, following a period of inadequate oxygen and nutrient supply. This phenomenon arises because the restoration of triggers a cascade of harmful biochemical events that amplify the initial ischemic damage, rather than solely promoting recovery. The pathophysiology of reperfusion injury involves two main phases: the ischemic phase, characterized by ATP depletion, ionic imbalances, and activation of stress-response pathways such as hypoxia-inducible factor-1 (HIF-1) and ; and the reperfusion phase, marked by a burst of production, including and hydroxyl radicals, from sources like and mitochondria. Additional mechanisms include inflammatory responses driven by cytokines (e.g., tumor necrosis factor-alpha [TNF-α] and interleukin-6 [IL-6]), neutrophil-endothelial interactions, complement activation, and calcium overload, which collectively lead to , , and . These processes not only cause local tissue destruction but can also trigger systemic effects, such as multi-organ failure in severe cases. Clinically, reperfusion injury is a significant contributor to outcomes in various conditions, including myocardial infarction (where it accounts for up to 50% of final infarct size), stroke, organ transplantation, and trauma-related vascular interventions like angioplasty or thrombolysis. It manifests in organs such as the heart, brain, kidneys, lungs, gut, and skeletal muscle, often complicating emergency reperfusion therapies despite their life-saving intent. Preventive strategies under investigation include ischemic preconditioning, antioxidants like allopurinol, anti-inflammatory agents, and controlled reperfusion techniques, though no universally approved therapies specifically target IRI yet.

Definition and Overview

Definition

Reperfusion injury refers to the tissue damage that occurs when blood flow is restored to an area of the body that has experienced ischemia, paradoxically exacerbating the injury beyond what was caused by the ischemia alone. This phenomenon involves the conversion of potentially reversible ischemic damage into irreversible cell death upon reoxygenation, primarily observed in organs such as the heart, brain, and kidneys. Ischemia, a prerequisite for reperfusion injury, is characterized by a restriction in blood supply to tissues, resulting in oxygen and nutrient deprivation that leads to cellular energy failure through depleted stores and . The restoration of , intended to salvage ischemic , instead triggers additional harm due to factors such as the sudden reintroduction of oxygen. The concept of reperfusion injury was first described in the through studies on myocardial models, where Jennings and colleagues observed that reperfusion following coronary artery occlusion in canine hearts accelerated cellular compared to prolonged ischemia alone. A key historical insight came with the "oxygen paradox," proposed by Hearse et al. in 1978, highlighting how reoxygenation of hypoxic tissues induces rapid damage, possibly involving , though the full mechanisms were later elucidated.

Clinical Importance

Reperfusion injury significantly exacerbates tissue damage in clinical settings where restoring blood flow is essential for salvage, yet paradoxically amplifies beyond the initial ischemic insult. In acute myocardial infarction (AMI), it contributes 10-50% to the final infarct size following reperfusion therapies such as or (PCI), leading to larger areas of myocardial despite timely intervention. In ischemic stroke, reperfusion injury accounts for up to 30% of the additional brain damage after treatments like intravenous tissue plasminogen activator (tPA) or mechanical thrombectomy, often resulting in worse neurological outcomes despite successful recanalization rates exceeding 90%. These contributions highlight its role in limiting the benefits of reperfusion, particularly in time-sensitive emergencies. The condition is prevalent across multiple disease contexts, including AMI post-revascularization, where it complicates up to 50% of cases with restored epicardial flow but impaired microvascular perfusion. In ischemic stroke following tPA or , it affects approximately 50% of patients with poor functional recovery despite vessel reopening. , such as kidney and liver procedures, frequently involves reperfusion injury due to cold ischemia during preservation, with incidence rates of reaching 12-80% post-liver transplant and contributing to delayed graft function in up to 50% of renal transplants. Limb ischemia-reperfusion, as seen in or trauma, similarly imposes risks during surgical revascularization, amplifying local tissue loss. Clinically, reperfusion injury heightens morbidity and mortality through mechanisms like the no-reflow phenomenon in the , which impairs microvascular flow and predisposes patients to ventricular arrhythmias and . In the , it promotes hemorrhagic transformation, where blood-brain barrier breakdown leads to intracranial bleeding in 10-40% of reperfused cases, worsening disability and increasing mortality risk by up to 2-fold. These consequences extend recovery timelines, necessitate intensive care, and drive the need for adjunctive therapies to mitigate microvascular obstruction. The economic and clinical burden is substantial, with reperfusion injury delaying patient discharge by weeks and escalating healthcare costs through prolonged hospitalizations and secondary interventions; for instance, AMI-related complications alone contribute to annual U.S. expenditures exceeding $100 billion, partly attributable to suboptimal reperfusion outcomes. Recent 2023-2025 reviews indicate a rising incidence linked to aging populations, where cardiovascular and cerebrovascular events increase by 20-30% in those over 65, amplifying the global market for related therapeutics to over $2 billion by 2029 due to heightened demand for cardioprotective and neuroprotective strategies.

Pathophysiology

Ischemia-Reperfusion Sequence

The ischemic phase of reperfusion injury begins with the interruption of blood flow to tissues, leading to oxygen and deprivation. This rapidly results in ATP depletion as mitochondrial halts, forcing cells to rely on for energy production. Anaerobic metabolism generates as a byproduct, causing intracellular and a significant drop in , which impairs enzymatic functions and exacerbates cellular stress. Concurrently, ion homeostasis is disrupted; the failure of ATP-dependent pumps, such as Na+/K+-ATPase and Ca2+-ATPase, leads to sodium and calcium overload within cells, promoting osmotic swelling and membrane depolarization. These changes collectively prime tissues for further damage upon restoration of . Upon reperfusion, the abrupt reintroduction of oxygenated , nutrients, and circulating cells paradoxically amplifies rather than solely alleviating it. This triggers a cascade of harmful events starting within minutes, including the normalization of through dilution of accumulated acids, but also the rapid washout of accumulated metabolites like and , which can provoke arrhythmias and further ion dysregulation in susceptible tissues. The influx of oxygen and inflammatory cells, such as neutrophils, sets off additional pathophysiological processes that extend over hours, with the sudden availability of substrates fueling bursts of activity in damaged cellular components. This phase highlights how the benefits of are counterbalanced by these acute perturbations. The overall sequence exhibits a biphasic pattern of injury progression, with an early phase focused on microvascular dysfunction—such as endothelial barrier breakdown and no-reflow phenomena—occurring shortly after reperfusion onset, followed by a later phase of cellular damage peaking between 1 and 24 hours post-reperfusion. This timeline underscores the dynamic evolution from ischemic preconditioning to reperfusion-exacerbated harm, where initial metabolic recovery gives way to sustained tissue insult. While restoration aids in stabilizing cellular processes, the washout of protective metabolites often intensifies vulnerability, contributing to the sequence's deleterious outcome and paving the way for downstream events like generation.

Organ-Specific Aspects

Reperfusion injury exhibits distinct manifestations across organs due to variations in tissue architecture, metabolic demands, and vascular , influencing the severity and type of damage observed upon restoration of blood flow. , reperfusion injury commonly leads to the no-reflow phenomenon, characterized by microvascular obstruction from , distal , and capillary plugging by neutrophils and debris, which impairs myocardial despite epicardial artery recanalization. This obstruction contributes to —a reversible contractile dysfunction—and potentially fatal arrhythmias, as reperfusion triggers calcium overload and oxidative bursts in cardiomyocytes. Recent 2024 analyses highlight the prominence of , an iron-dependent pathway involving , in diabetic hearts, where exacerbates iron accumulation and sensitizes cardiomyocytes to reperfusion-induced ferroptotic damage. Cerebral reperfusion injury is amplified by the brain's high metabolic rate and limited collateral circulation, resulting in rapid energy depletion during ischemia and severe secondary damage upon reflow. Key features include breakdown, driven by activation and disruption, which allows plasma proteins and immune cells to infiltrate the , exacerbating and neuronal loss. from glutamate release further propagates damage by overstimulating NMDA receptors, leading to calcium influx and mitochondrial failure. Post-thrombectomy, hemorrhagic conversion occurs in up to 20-30% of cases due to fragile reperfused vessels, with early BBB permeability predicting this complication and worsening functional outcomes. Renal reperfusion injury often presents as following transplantation, where ischemia-reperfusion triggers through ATP depletion and backleak of glomerular filtrate across damaged epithelium. Proximal tubules are particularly vulnerable due to their high oxygen demand and reabsorptive workload, leading to cast formation, , and delayed graft function in 20-50% of cases. In the liver, the dual blood supply from the and hepatic artery provides partial protection during ischemia, mitigating the severity compared to singly perfused organs, though reperfusion still induces sinusoidal endothelial cell activation and Kupffer cell-mediated . This modifies injury patterns, with less pronounced but increased and risk post-transplant. Intestinal reperfusion injury extends beyond local mucosal sloughing and barrier disruption to systemic effects, including translocation of bacteria and endotoxins that precipitate via widespread and storms. In limbs, such as after acute lower extremity ischemia, reperfusion causes endothelial swelling and shedding in capillaries, promoting no-reflow, , and that can lead to remote organ failure. Organ-specific variations in oxygen sensitivity underscore these differences, with the brain exhibiting the highest vulnerability due to its dependence on continuous aerobic metabolism, followed by the heart and then the kidney, which benefits from medullary hypoxia tolerance. Recent 2023-2025 comparisons between acute myocardial infarction (AMI) and ischemic stroke reveal divergent reperfusion dynamics: AMI involves more pronounced microvascular obstruction and stunning from coronary microembolism, while stroke features greater BBB permeability and excitotoxic cascades, influencing tailored therapeutic windows and outcomes.

Mechanisms

Oxidative Stress and Reactive Oxygen Species

Reperfusion injury is characterized by a surge in primarily driven by the overproduction of (ROS) upon reintroduction of oxygen to ischemic tissues, leading to cellular damage that exacerbates tissue injury beyond that caused by ischemia alone. This phenomenon, known as the oxygen paradox, arises because during ischemia, hypoxanthine accumulates from ATP breakdown, and xanthine dehydrogenase is converted to ; upon reoxygenation, the oxidase uses accumulated hypoxanthine and oxygen to generate radicals, initiating a cascade of oxidative damage. Major enzymatic sources of ROS during reperfusion include , which predominates in organs like the intestine and liver, producing from hypoxanthine and oxygen. , activated in endothelial cells and neutrophils, contributes significantly by transferring s from NADPH to oxygen, forming , particularly in vascular and inflammatory contexts. Additionally, endothelial (eNOS) becomes uncoupled under oxidative conditions due to depletion, shifting from production to generation. Mitochondria also release ROS via reverse at complex I, amplifying the oxidative burden. The primary ROS generated include superoxide anion (O₂⁻), which dismutates to hydrogen peroxide (H₂O₂), and the highly reactive hydroxyl radical (•OH) formed via Fenton reactions; (RNS) such as (ONOO⁻) arise from reacting with . These species inflict damage through of cell s, leading to loss of membrane integrity; protein , which alters function and signaling; and , exemplified by the formation of (8-oxo-dG), a marker of genomic instability. Such oxidative modifications contribute to by impairing and promoting permeability. The ROS burst peaks within the first 5-10 minutes of reperfusion, reflecting the rapid activation of these sources and setting the stage for acute tissue damage. Recent analyses highlight ROS's role in initiating , an iron-dependent form of involving unchecked , which amplifies injury in post-ischemic tissues. This interacts with mitochondrial pathways to further promote permeability transition pore opening, worsening cellular demise.

Mitochondrial Dysfunction

During reperfusion, excessive calcium (Ca²⁺) influx occurs into cells, for example in cardiomyocytes partly through the reversal of the sodium-calcium exchanger (NCX) during early reperfusion phases when intracellular sodium levels are elevated. This leads to mitochondrial Ca²⁺ overload, which sensitizes and triggers the opening of the (mPTP). The is a non-selective pore in the regulated by D, a matrix peptidyl-prolyl isomerase that binds to and activates the pore complex under stress conditions. Its opening during reperfusion causes mitochondrial matrix swelling, rupture of the outer membrane, and release of pro-apoptotic factors such as into the . This event uncouples , halting efficient ATP synthesis despite the restoration of oxygen supply. Mitochondrial are profoundly disrupted in reperfusion injury, with inhibition of the () complexes due to accumulated succinate from ischemia driving reverse (RET) at complex I upon reoxygenation. RET generates a burst of , exacerbated by mitochondrial uncoupling that dissipates the proton gradient and further impairs ATP production. Mitochondria account for approximately 90% of cellular (ROS) production under physiological conditions, and this fraction surges during reperfusion primarily through RET-mediated mechanisms at the . These changes result in a paradoxical resumption of ATP synthesis that is inefficient due to futile proton leak cycles across the inner membrane, leading to sustained energy depletion. Additionally, impairment of mitophagy—the selective of damaged mitochondria—via dysregulation of the /Parkin pathway hinders clearance of dysfunctional organelles, amplifying injury as noted in 2023 reviews on ischemia-reperfusion contexts. This mitochondrial dysfunction ultimately contributes to through release, linking it to broader pathways.

Inflammatory Responses

Upon reperfusion, a cascade of inflammatory events is initiated in response to damage-associated molecular patterns (DAMPs) released from ischemic tissues, leading to sterile that exacerbates beyond the initial ischemic insult. This process involves the and activation of immune cells, release of pro-inflammatory mediators, and activation of key signaling pathways, distinct from direct oxidative damage but often triggered by (ROS) generated early in reperfusion. Key cellular players include neutrophils, which rapidly adhere to activated via adhesion molecules such as and , facilitating their transmigration into tissues and contributing to local damage through enzyme release. In the , serve as resident immune cells that polarize toward a pro-inflammatory upon reperfusion, amplifying . Macrophages, recruited later, also undergo , with types dominating the acute phase to promote , while M2 shifts occur in resolution. Major mediators encompass cytokines like tumor necrosis factor-alpha (TNF-α), interleukin-1 beta (IL-1β), and interleukin-6 (IL-6), which are upregulated within minutes to hours and drive further immune cell activation. such as signal through receptors to recruit monocytes and macrophages, enhancing infiltration. The plays a central role by sensing DAMPs and activating caspase-1, leading to IL-1β maturation and release, as highlighted in recent studies on sterile inflammation in ischemia-reperfusion models. Critical pathways include nuclear factor-kappa B (NF-κB) signaling, which translocates to the upon reperfusion to induce transcription of pro-inflammatory genes encoding cytokines and adhesion molecules. The amplifies this response through activation of the alternative pathway, generating anaphylatoxins C3a and C5a that promote and leukocyte . The inflammatory timeline begins early with platelet activation and endothelial expression of P-selectin within minutes, progressing to peak and infiltration over hours, as seen in 2024 analyses of sterile dynamics in cardiac and cerebral models. Consequences include of the no-reflow due to microvascular plugging by leukocytes, and in the , disruption of the blood-brain barrier () integrity, allowing further influx of inflammatory cells and formation.

Cell Death Pathways

Reperfusion injury triggers multiple forms of regulated in affected tissues, contributing to tissue damage beyond the initial ischemic insult. These pathways include both programmed mechanisms like and non-programmed ones like , with emerging modes such as necroptosis, , , and panoptosis playing significant roles. The balance among these pathways varies by region, with predominating in the ischemic core due to severe energy depletion, while is more prevalent in the penumbra where cells experience milder stress and retain some metabolic capacity. Apoptosis, a caspase-dependent programmed cell death, is activated in reperfusion injury through intrinsic and extrinsic pathways. In the intrinsic pathway, mitochondrial outer membrane permeabilization occurs via Bax/Bak pore formation, leading to release and assembly, which activates and subsequently effector caspases-3/7 for DNA fragmentation and cell shrinkage. This process is often exacerbated by (mPTP) opening during reperfusion. The extrinsic pathway involves death receptor ligation, such as TNF-α binding to TNFR1, recruiting and to amplify the cascade. Anti-apoptotic Bcl-2 family members like inhibit Bax/Bak oligomerization, providing a regulatory checkpoint. Necrosis and necroptosis represent lytic forms of characterized by plasma membrane rupture and release of damage-associated molecular patterns (DAMPs). Classical in reperfusion arises from uncontrolled ATP depletion and calcium overload, causing swelling and cell lysis without specific enzymatic execution. Necroptosis, a regulated variant, proceeds via the /RIPK3/MLKL pathway: and RIPK3 form the necrosome complex upon TNF-α stimulation when is inhibited, phosphorylating MLKL to form amyloid-like pores in the membrane. This pathway is prominent in cardiomyocytes during myocardial ischemia-reperfusion, amplifying through DAMP release. Pyroptosis involves inflammatory activation and gasdermin-mediated lysis, triggered in reperfused tissues by assembly. The canonical pathway features recruitment of ASC and -1, which cleaves gasdermin D (GSDMD) to generate N-terminal fragments that form 10-20 nm pores in the plasma membrane, allowing IL-1β and IL-18 alongside osmotic swelling and rupture. Non-canonical routes via -11/4 further process GSDMD in response to cytosolic . Pyroptosis contributes to cardiomyocyte loss in ischemia-reperfusion by promoting a pro-inflammatory milieu. Ferroptosis is an iron-dependent regulated driven by , particularly relevant in diabetic myocardium during reperfusion. It arises from 4 (GPX4) inhibition or depletion, preventing reduction of phospholipid hydroperoxides and leading to Fenton reaction-mediated reactive oxygen propagation on polyunsaturated fatty acids. Key regulators include system xc- cystine/glutamate (SLC7A11) for synthesis and ACSL4 for lipid substrate provision; suppresses SLC7A11 to promote . In diabetic contexts, exacerbates via impaired GPX4 activity and elevated iron accumulation, worsening post-reperfusion damage in the heart. Panoptosis integrates features of , , and necroptosis through the PANoptosome complex, offering a unified inflammatory mode in reperfusion injury. ZBP1 senses cytosolic DNA or damage signals to assemble a complex with RIPK3, , and , enabling concurrent and activation for mixed execution: GSDMD pores, MLKL oligomerization, and cleavage. This amplifies tissue injury in myocardial and cerebral reperfusion models. Non-coding RNAs modulate these pathways, with microRNAs like miR-124 exerting anti-apoptotic effects in ischemia-reperfusion. miR-124 targets pro-apoptotic factors or activates protective regulators such as mitochondrial calcium uniporter regulator 1 (MCUR1), reducing caspase activation and cytochrome c release in cardiomyocytes. Overexpression of miR-124 attenuates apoptosis in myocardial models, highlighting its therapeutic potential. No single death mode dominates; instead, a spectrum from necrotic core lysis to apoptotic penumbral clearance determines overall injury extent, influenced by reperfusion timing and tissue type.

Therapeutic Strategies

Ischemic Conditioning Techniques

Ischemic preconditioning () involves applying brief cycles of ischemia and reperfusion to the target organ prior to a prolonged ischemic event, thereby conferring protection against subsequent reperfusion injury. This technique, first demonstrated in myocardium, delays lethal cell injury by reducing infarct size through endogenous adaptive mechanisms. activates key signaling pathways, including the reperfusion injury salvage () pathway via phosphatidylinositol 3- (PI3K)/Akt and extracellular signal-regulated 1/2 (ERK1/2), as well as the survivor activating enhancement () pathway, which collectively inhibit opening and limit cell death. These pathways help mitigate and inflammatory responses during reperfusion. Ischemic postconditioning (IPost), introduced as a clinical counterpart to preconditioning, applies similar brief ischemia-reperfusion cycles at the onset of reperfusion following prolonged ischemia, rather than beforehand. This approach attenuates reperfusion injury by interrupting the initial burst of and stabilizing mitochondrial function in the early minutes of reflow. In experimental myocardial models, IPost has been shown to reduce infarct size by approximately 30-40% compared to standard reperfusion, with comparable efficacy to in protecting against and . Remote ischemic conditioning (RIC) extends these principles systemically by inducing brief ischemia in a distant organ or limb, such as through intermittent cuff inflation on the upper arm, to protect the target organ like the heart or brain. This non-invasive method triggers humoral factors, including adenosine and bradykinin, which circulate to activate cardioprotective signals in the remote tissue. RIC engages similar RISK and SAFE pathways, leading to endothelial nitric oxide synthase (eNOS) phosphorylation and improved microvascular perfusion. Clinical trials have substantiated RIC's benefits, particularly in patients undergoing (PCI) for ST-elevation (STEMI). A 2024 study demonstrated that RIC suppresses excessive cardiac sympathetic nerve activity in non-culprit lesions during STEMI, potentially reducing risk and enhancing outcomes. Mechanisms such as eNOS activation contribute to smaller infarct sizes and better myocardial salvage in these settings. Pharmacological mimics of ischemic conditioning, such as , replicate these effects by stimulating delta-opioid receptors, which trigger RISK pathway activation and reduce infarct size similarly to mechanical preconditioning in animal models. These variants offer potential adjuncts when direct ischemic maneuvers are impractical.

Antioxidant and ROS-Targeted Therapies

Antioxidant therapies targeting reactive oxygen species (ROS) represent a cornerstone approach to mitigating reperfusion injury by scavenging excess radicals or enhancing endogenous defense mechanisms. These interventions aim to counteract the oxidative burst that occurs upon reoxygenation of ischemic tissues, thereby reducing cellular damage in organs such as the heart, brain, and kidneys. Preclinical studies, including those with polyethylene glycol-conjugated SOD mimics, have demonstrated modest reductions in infarct size, typically by 10-20%, in myocardial and cerebral reperfusion models. Clinical trials have shown limited translation to humans due to delivery challenges. Edaravone, a potent free radical scavenger, inhibits and formation, offering in acute ischemic with reperfusion. Approved in Japan since 2001 for treating acute ischemic , edaravone has shown efficacy in reducing neurological deficits when administered intravenously within 24 hours of symptom onset. A 2023 phase III evaluating the edaravone-dexborneol combination in over 1,200 patients with acute ischemic reported improved 90-day functional outcomes, with a relative improvement of approximately 35% in scores compared to edaravone alone, highlighting its enhanced ROS-scavenging synergy. Other agents, such as , replenish stores to bolster capacity, while activates the Nrf2 pathway to upregulate enzymes, both demonstrating reduced oxidative damage and improved tissue viability in preclinical models of hepatic and cerebral reperfusion injury. Riboflavin, as a precursor to (FMN) and (FAD), supports mitochondrial function, preserving complex I activity and attenuating ROS production during brain and renal reperfusion. Mechanistically, these therapies often converge on upregulating glutathione peroxidase 4 (), which utilizes to reduce lipid hydroperoxides and prevent —a form of iron-dependent exacerbated by reperfusion-induced . By inhibiting , antioxidants like and preserve membrane integrity and limit propagation of oxidative damage in ischemic tissues. A 2024 review underscores how Nrf2-mediated induction by such agents effectively curbs in myocardial and cerebral ischemia-reperfusion injury, providing a molecular basis for their cytoprotective effects. However, these therapies face significant limitations, including short half-lives (e.g., minutes for mimics) that necessitate targeted delivery systems, and critical timing requirements, with optimal administration ideally preceding or coinciding with reperfusion to intercept the initial ROS surge within the first 3 hours.

Mitochondrial and Calcium Modulators

(mPTP) opening during reperfusion contributes to cell death by disrupting mitochondrial integrity and exacerbating calcium overload, making modulators of these processes key therapeutic targets in ischemia-reperfusion injury (IRI). (CsA), a inhibitor, targets cyclophilin D to prevent opening, thereby stabilizing mitochondrial membranes and reducing infarct size in preclinical models of myocardial IRI. In the CIRCUS trial, a phase III study involving 970 patients with acute ST-elevation undergoing (PCI), intravenous CsA administered prior to reperfusion showed no significant reduction in overall infarct size or clinical outcomes, attributed to factors like patient heterogeneity and timing. However, a 2016 of randomized controlled trials indicated that CsA may confer benefits in reducing reperfusion injury specifically in low-risk PCI settings, with improved myocardial salvage index and lower release, though larger confirmatory studies are needed. TRO40303, a mitochondria-targeted compound structurally derived from a cholesterol-like scaffold, inhibits mPTP opening by binding to the mitochondrial translocator protein and mitigating cardiolipin oxidation, which preserves mitochondrial function during oxidative stress in IRI models. In preclinical rat models of myocardial infarction, TRO40303 reduced infarct size by approximately 30% and inhibited apoptosis-inducing factor release from mitochondria. The phase II MITOCARE trial, a multicenter randomized placebo-controlled study in 380 patients with anterior ST-elevation myocardial infarction undergoing primary PCI, demonstrated that intravenous TRO40303 was safe, with no increase in serious adverse events compared to placebo, though it did not significantly reduce final infarct size as measured by cardiac magnetic resonance imaging. Metformin, a widely used antidiabetic agent, activates (AMPK), which modulates calcium by enhancing calcium uptake and reducing cytosolic calcium overload during reperfusion. Through AMPK-dependent pathways, metformin also promotes mitophagy, the selective degradation of damaged mitochondria, thereby improving and function in preclinical models of diabetic IRI. In diabetic models of renal and cardiac IRI, metformin pretreatment (doses of 100-300 mg/kg) attenuated tubular injury and myocardial dysfunction by restoring autophagic flux and limiting production downstream of mitochondrial stabilization. Hydrogen sulfide (H2S) donors, such as (NaHS), protect against IRI by preserving mitochondrial integrity through S-sulfhydration, a that regulates protein function in complexes and inhibits opening. In rat models of myocardial IRI, NaHS administration (100-300 μmol/kg) during reperfusion reduced infarct size by 25-40% and maintained mitochondrial by enhancing S-sulfhydration of key proteins like , which suppresses pathways. This mechanism also attenuates calcium dysregulation by modulating mitochondrial calcium uniporters, contributing to overall cardioprotection in preclinical studies. Calcium chelators, such as (EDTA), have shown potential in preclinical IRI models by binding excess cytosolic calcium to prevent activation and mitochondrial calcium overload. However, their clinical use remains limited due to significant side effects, including hypocalcemia-induced arrhythmias, , and renal , as observed in early trials for heavy metal and extrapolated to IRI contexts. Intracoronary EDTA in swine IRI models reduced infarct size by 20-30% without immediate adverse events, but translation has been hindered by these risks and lack of large-scale efficacy data.

Anti-Inflammatory and Immunomodulatory Approaches

Anti-inflammatory and immunomodulatory approaches target the excessive immune activation and storms that exacerbate reperfusion injury following ischemia, building on the role of inflammatory responses in tissue damage. These strategies aim to mitigate infiltration, release, and complement activation without directly addressing or mitochondrial pathways. Cannabinoids, particularly (CBD) and CB2 receptor agonists, have shown promise in preclinical models by reducing recruitment and inflammation in ischemic tissues. For instance, CB2 agonists like HU-910 attenuate hepatic ischemia/reperfusion injury by suppressing and inflammatory , thereby limiting tissue damage. Similarly, acute administration of reduces infarct size by up to 66% in myocardial ischemia/reperfusion models and suppresses arrhythmias by modulating inflammatory pathways. These effects are mediated through CB2 receptor activation, which inhibits infiltration and pro-inflammatory signaling. Anti-cytokine therapies focus on blocking key mediators like interleukin-1β (IL-1β) to curb the inflammatory cascade. The IL-1 anakinra, when administered intravenously prior to reperfusion, significantly reduces infarct size in experimental myocardial ischemia/reperfusion injury models. High-dose anakinra also improves outcomes in models of moderate by mitigating IL-1β-driven inflammation. For the , a central regulator of IL-1β release, inhibitors such as dapansutrile (OLT1177) limit inflammatory injury and preserve myocardial function in preclinical ischemia/reperfusion models, with early-phase clinical trials exploring their safety in related cardiovascular conditions. Therapeutic hypothermia, typically maintained at 32-34°C, reduces metabolic demand and release, providing in reperfusion scenarios. In survivors of , mild therapeutic decreases cerebral inflammatory mediators post-resuscitation, attenuating secondary brain injury from ischemia/reperfusion. This approach is standard in management and has demonstrated neuroprotective effects in models by limiting storms and immune activation. Pre-treatment with leverages their pleiotropic effects, including inhibition, to attenuate myocardial reperfusion injury. Chronic use prior to in acute coronary syndromes reduces in-hospital mortality and inflammatory responses via pathway suppression. Recent data from 2023 highlight ' role in modulating and signaling, enhancing endothelial protection during periprocedural ischemia/reperfusion. Complement inhibitors targeting C5a, a potent anaphylatoxin, have protective effects in experimental models. Small-molecule C5a receptor antagonists reduce renal ischemia/reperfusion injury by blocking inflammatory signaling and activation in rat models. Similarly, C5 inhibition prior to reperfusion protects against myocardial injury in mice, confirming C5a's role in amplifying immune-mediated damage.

Emerging Biological Therapies

Emerging biological therapies for reperfusion injury encompass regenerative approaches such as stem cell transplantation, exosome-based interventions, gene editing, and non-coding RNA modulation, which target multiple underlying mechanisms including inflammation and cell death to promote tissue repair. These therapies leverage the body's endogenous repair processes, offering potential beyond traditional pharmacological agents by addressing both acute damage and long-term remodeling following ischemia-reperfusion events in organs like the heart and brain. Stem cell therapy, particularly using bone marrow-derived mesenchymal stem cells (BM-MSCs) and adipose-derived stem cells (ADSCs), has shown promise in mitigating reperfusion injury through paracrine effects that secrete anti-apoptotic factors, reducing cardiomyocyte and neuronal death. BM-MSCs and ADSCs exhibit similar immunophenotypes and multipotency, enabling them to modulate local and without significant engraftment. A 2024 meta-analysis of clinical trials in acute (AMI) patients demonstrated that improved left ventricular (LVEF) by approximately 2-5% at follow-up periods from 6 to 36 months, indicating enhanced cardiac function post-reperfusion. Preclinical studies further support their role in models, where ADSCs improve neurological outcomes by limiting infarct expansion. Exosomes, as cell-free derivatives of stem cells, carry (miRNA) cargo such as miR-133a to exert protective effects against reperfusion injury by inhibiting and . In cardiac models, BMSC-derived exosomes enriched with miR-133a-3p target pathways like DAPK2/Akt, alleviating ischemia-reperfusion damage and improving post-infarct remodeling. For cerebral applications, (NSC)-derived exosomes cross the blood-brain barrier to deliver neuroprotective miRNAs, with elevated exosomal miR-133 levels observed in acute patients correlating with injury severity. Ongoing 2025 clinical trials are evaluating exosome infusions for , focusing on their ability to reduce infarct volume and enhance recovery through targeted miRNA modulation. Gene therapy strategies, including Nrf2 overexpression, aim to bolster antioxidant defenses during reperfusion to counteract oxidative stress and mitochondrial dysfunction. Overexpression of Nrf2 via viral vectors activates downstream genes that mitigate liver and cardiac ischemia-reperfusion injury by enhancing cellular resilience to reactive oxygen species. In preclinical cardiac models, Nrf2 activation has been linked to reduced necrosis and improved hemodynamic recovery post-reperfusion. Complementing this, CRISPR-Cas9-mediated knockdown of NLRP3, a key inflammasome component, suppresses pyroptosis and inflammatory cascades in myocardial ischemia-reperfusion models, demonstrating feasibility in rodent studies for targeted gene editing. Non-coding RNA (ncRNA) therapies, such as antisense targeting long ncRNA MALAT1, inhibit pro-inflammatory signaling to protect against cerebral ischemia-reperfusion injury. Silencing MALAT1 reduces aquaporin-4 dysregulation and formation by competitively binding miR-145, thereby limiting neuronal damage in preclinical models. Similarly, nanoparticle-delivered miR-124 mimics promote and reduce infarct size in ischemic by downregulating pro-apoptotic targets, with RVG29-modified carriers enhancing penetration and therapeutic efficacy. These ncRNA approaches highlight the potential for sequence-specific modulation of networks disrupted during reperfusion. Despite these advances, challenges in emerging biological therapies include optimizing timing of administration to align with reperfusion windows and precise dosing to avoid off-target effects, as suboptimal delivery can exacerbate . Between 2023 and 2025, nanomaterial-based systems have progressed to enable targeted release of biologics, such as polymeric nanoparticles for exosome encapsulation and metal-organic frameworks for miRNA transport, improving and crossing physiological barriers like the blood-brain barrier in models. These innovations address key hurdles in translation, paving the way for more effective clinical integration.

Natural and Comparative Protection

Mechanisms in Hibernating Animals

Hibernating mammals, including 13-lined ground squirrels (Ictidomys tridecemlineatus) and brown bears (Ursus arctos), serve as natural models for tolerance to ischemia-reperfusion injury, enduring prolonged periods of low oxygen and blood flow without substantial tissue damage. During torpor, their core body temperature falls to 4–10°C, drastically lowering metabolic rate and energy demands, which minimizes ischemic stress and subsequent reperfusion harm. This state allows organs like the heart and brain to withstand cycles of hypoperfusion and reflow that would be lethal in non-hibernators. Key endogenous protections involve enhanced antioxidant systems, where enzymes such as (SOD) and (GPX) are upregulated to counteract (ROS). In Daurian ground squirrels (Spermophilus dauricus), and protein levels rise by up to 65% in skeletal muscles during interbout arousal and post-hibernation, while GPX1 increases by 25–82% across torpor phases, driven by Nrf2/Keap1 pathway activation. These adaptations prevent oxidative damage during reperfusion-like arousals from torpor. Mitochondrial modifications further bolster resilience, including a shift toward and ketone body oxidation to maintain acid-base balance and avoid lactate accumulation, alongside reversible phosphorylation of complexes that suppresses respiration without impairing recovery. Hibernator mitochondria also exhibit reduced sensitivity to (mPTP) opening, limiting calcium overload and during stress. Inflammation is markedly attenuated, with hibernators showing suppressed responses post-ischemia. Arctic ground squirrels (Urocitellus parryii) display no elevation in pro-inflammatory cytokines like IL-6 or TNF-α after global ischemia-reperfusion, in contrast to rats, due to innate immune modulation and metabolic stability. Recent studies on 13-lined ground squirrels highlight this protection in cardiac tissue, where hearts subjected to ischemia-reperfusion exhibit no significant ROS burst, preserving function through combined antioxidant and mitochondrial safeguards. These traits stem from genetic and epigenetic differences, including hibernation-specific proteins like HP-20, which form complexes (e.g., HP20c) that signal entry and enable profound metabolic suppression. Such mechanisms share parallels with therapeutic , which similarly curbs reperfusion injury by lowering and .

Lessons for Human Therapy

Insights from the protective mechanisms observed in hibernating animals have inspired several translational strategies aimed at mitigating reperfusion injury in humans. These approaches seek to replicate the hypometabolic state and cellular safeguards of to enhance organ resilience during ischemia-reperfusion events, such as or . Key translational targets include pharmacological agents that mimic . (H2S) donors induce a hypometabolic state similar to , reducing oxygen demand and protecting against ischemia-reperfusion injury in cardiac, renal, and cerebral tissues by inhibiting and . agonists, such as N6-cyclohexyladenosine (CHA), promote torpor-like , attenuating and reperfusion damage in preclinical models. Additionally, exercise preconditioning upregulates antioxidant genes like those encoding and , conferring resistance to during reperfusion. Clinical applications draw directly from hibernator models. Delta-opioid agonists, inspired by opioid-like hibernation induction triggers (HIT) isolated from , provide cardioprotection by mimicking pharmacologic , reducing infarct size in ischemia-reperfusion models through delta-2 receptor activation. Recent studies on , including a 2024 example, have targeted mitochondrial permeability transition pore (mPTP) resistance, with engineered nanozymes inhibiting opening to limit cardiomyocyte death post-reperfusion. Exercise training emerges as a non-invasive mimic of hibernator adaptations, preconditioning the heart to reduce and improve outcomes in myocardial ischemia-reperfusion injury (MIRI) models. A 2025 review highlights how regular enhances mitochondrial function and antioxidant defenses in preclinical studies. Despite these advances, significant limitations hinder translation to therapy. Species differences in metabolic regulation and complicate direct application of hibernator strategies, as responses to hypometabolism may differ profoundly. Ethical concerns and challenges in conducting human trials, including risks of inducing torpor-like states, further impede progress. Looking to the future, biomimicry approaches using offer promise for sustained protection. Engineered biomimetic nanodelivery systems target reperfusion sites to release antioxidants and agents, potentially extending cardioprotection in clinical settings. Additional developments, such as multicarrier nanoplatforms for mitochondrial targeting and ionizable protein nanocages, further support these natural-inspired strategies.

References

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