Restoring blood flow and the reoxygenation of the cardiac tissue following myocardial ischemia generates excessive quantities of ROS. The accumulation of ROS damages cellular components (such as proteins, lipid and DNA oxidation), increases the susceptibility of mitochondria and cells, and accelerates aging and cell death (3,12,21,23). For example, toxic ROS can damage mitochondrial respiratory complex I via the oxidation of thiols, which in turn results in the production of excess ROS during reperfusion (6). The phospholipid cardiolipin, which is required for the mitochondrial inner membrane, and the activities of complexes III and IV in the respiratory chain, contains a high percentage of unsaturated fatty acids and is sensitive to peroxidation by ROS (24). Cardiolipin is also essential in the biochemical functions of several mitochondrial proteins, such as mitochondrial creatine kinase (mitCK) (24). mitCK plays an important role in the creatine-phosphocreatine energy transferring system (25). The mitCK system has been shown to be damaged by cardiac ischemia and oxidative stress (26). The burst of ROS from mitochondria during IR not only causes direct acute damage in cells or tissues, but also initiates the long-term inflammatory response following reperfusion or persistent pathologies such as in chronic heart diseases (7,27).

During IR, activated acyl-CoA accumulates in the mitochondrial matrix due to a defective β-oxidation pathway. The non-enzymatic acylation of lysine residues by acyl-CoA causes matrix protein dysfunction and aggregation (28-30).

A damaged mitochondrial respiratory chain also causes the depletion of NAD⁺. Since NAD⁺ is required for ATP synthesis and also for the deacylation of Lys by sirtuins, NAD⁺ depletion disrupts the pathways for bioenergetics and also the pathways altered by carbon stress (30,31).

Mitochondria generate ATP through OXPHOS within the electron transport chain at the mitochondrial inner membrane. The lack of oxygen and respiratory substrates impairs OXPHOS during ischemia (3). IR injury markedly increases mitochondrial permeability, and dissipates electron and proton gradients. Furthermore, mitochondrial electron transport chain subunits lose their integrity and are degraded under conditions of IR. OXPHOS is markedly diminished in the abnormal mitochondria, leading to bioenergetic insufficiency during MI (23).

mPTP is a large conductance channel in the inner membrane, which is activated by Ca²⁺ accumulation (32,33). Ischemic oxidative damage results in the marked reduction of mitochondrial membrane potential (∆Ψm), mitochondrial Ca²⁺ bursts and the opening of the non-selective mPTP in the inner membrane. Accompanied by the release of matrix proteins and mtDNA into the cytosol, mPTP opening increases colloid-osmotic pressure in the matrix, induces the innate immune response, and initiates the activation of proteases and lipases, leading to mitochondrial swelling and cardiomyocyte death through necrosis (34,35). The excessive activation of the mitochondrial fission protein, dynamin-related protein 1 (Drp1), also facilitates mPTP opening and accelerates cell death. The genetic or pharmacological inhibition of Drp1 has been shown to decrease the frequency of transient opening of mPTP during cardiac IR and reduce the infarct size following MI (8,36,37).

During ischemia, ATP depletion and acidosis caused by the increasing lactate levels drive cytosolic Na⁺ accumulation through the plasma membrane Na⁺/H⁺ exchanger, which, in turn leads to an excessive exchange of Ca²⁺ via the Na⁺/Ca²⁺ exchanger (15). The transport of Ca²⁺ between sarcoplasmic/endoplasmic reticulum and mitochondria enables cardiac excitation-contraction coupling (38). However, Ca²⁺ uptake by the sarcoplasmic reticulum Ca²⁺-ATPase is inhibited due to ATP depletion during ischemia. The rapid restoration of the ∆Ψm by the subsequent reperfusion drives the uptake of Ca²⁺ into the mitochondria via the mitochondrial calcium uniporter (15). Therefore, Ca²⁺ overload in the mitochondria is one of the hallmarks of IR injury of the heart (39). During the reperfusion phase, the accumulation of cytosolic Ca²⁺ activates calcineurin (CaN) to dephosphorylate Drp1 at Ser⁶³⁷, initiating mitochondrial fission and cardiomyocyte apoptosis (40).

There are a large number of transcription factors and regulatory proteins to enhance mitochondrial biogenesis, such as nuclear respiratory factors 1 and 2, transcription factor A mitochondrial, peroxisome proliferator-activated receptors (PPARs), estrogen-related receptors, cAMP response element-binding proteins and Forkhead box-O. Transcription factors can be regulated by coactivators and corepressors, such as PPARγ coactivator-1α (PGC-1α) and nuclear receptor corepressor 1. PGC-1α can be activated by post translational modifications, such as through phosphorylation by AMP-activated protein kinase (AMPK) and deacetylation by Sirtuin 1 (Sirt1) (41). Under oxygen insufficiency, an energetic stress results in the downregulation of mitochondrial biogenesis by the hypoxia-inducible factor-mediated suppression of PGC-1α (42).

Continuous mitochondrial fission and fusion enables a dynamic distribution of mitochondrial proteins and mtDNA through the cellular mitochondrial network (23). Mitochondrial fission involves division into two daughter mitochondria, one with a markedly higher mitochondrial membrane potential (∆Ψm) and fusion affinity than the other one. Subsequently, the active mitochondrion is further regenerated and the defective one is targeted for degradation via mitophagy to maintain mitochondrial homeostasis (3,8,43). Fission and fusion proteins impact mitochondrial morphology and respiration, therefore, a balanced dynamic is essential to adjust mitochondrial metabolism to meet the energy demands in cardiomyocytes (8,44,45). The alteration of proteins involved in mitochondrial fission and fusion is tightly associated with the pathophysiology of several cardiac diseases, such as IR stress and heart failure (10,46).

The mitochondrial fission protein, Drp1, regulates mitochondrial dynamics on the mitochondrial outer membrane (47). Drp1 acts with Bcl-2 family proteins (such as the pro-apoptotic proteins Bax and Bak) to accelerate mitochondrial fragmentation and apoptosis (48). The phosphorylation at Ser⁶³⁷ residue of Drp1 by protein kinase A (PKA) inhibits its GTPase activity and its translocation to the mitochondria (49). Drp1 is enriched in the heart and its inhibition exhibits protective effects during myocardial IR by preventing excessive fission at the beginning of reperfusion (36,40). The overexpression of the cardiac proto-oncogene Ser/Thr kinase, Pim-1, causes the downregulation of Drp1 and an increase in the levels of Ser⁶³⁷ phosphorylation, and also protects against cardiomyocyte ischemia (37). Drp1 can be reactivated via the dephosphorylation of Ser⁶³⁷ by the calmodulin-dependent kinase CaN (50). Under normoxic conditions, the actions of PKA and CaN on Drp1 are well regulated by mitochondrial scaffolding protein the A-kinase anchoring protein 1 (AKAP1) (50). However, in ischemic myocytes, AKAP1 is ubiquitinated by the hypoxia-induced E3-ubiquitin ligase Siah2 and rapidly degraded via the ubiquitin-proteasome system, which impairs PKA-mediated Drp1 inhibition and initiates mitochondrial fission and cardiomyocyte apoptosis (39,50). In addition, cardiac IR injury may be reduced when the transient suppression of Drp1 has been achieved by small molecular disruptors or by shRNA/siRNA-mediated knockdown (36,40,51). Chronic Drp1 deficiency, such as the heterozygous knockout (Drp1^+/−), results in enlarged infarct sizes after IR stress (52).

The mitochondrial fission factor (Mff) is important for Drp1 recruitment in mitochondria during the process of fission (53). The inhibition of Mff has been shown to enhance mitochondrial membrane potential (∆Ψm) and decrease apoptosis under hypoxia/reoxygenation (54).

The dynamin-related GTPases mitofusin (Mfn) 1 and 2 are responsible for the fusion of the mitochondrial outer membrane between two mitochondria (19), whereas, the optic atrophy protein 1 (OPA1) mediates mitochondrial inner membrane fusion via regulation of the cristae structure (8,19). The down-regulation of Mfn1 under conditions of ROS-induced stress during IR disturbs mitochondrial fusion and induces cardiomyocyte apoptosis (55). Conversely, Mfn2 is upregulated in response to the ROS burst during IR and induces the apoptosis of cardiomyocytes by inhibiting Akt (also known as protein kinase B) and activating caspase-9 (39). In the heart, Mfn2 is involved in the regulation of mitophagy, altering mitochondrial morphology and forming the ER/SR-mitochondrial contact sites (8). OPA1 plays a protective role in IR injury. Opa1^+/− mice showed larger infarct sizes compared with wild type, and Opa1 overexpression results in decreased damage in cardiac function (17). Bax not only directly interacts with Mfn2 to physiologically regulate its assembly and distribution in the normal heart, but also co-localizes with Drp1 to facilitate mitochondrial fission during early apoptosis (39). The Bcl-2 family proteins, Bax, Bak and Bcl2-interacting protein 3 (BNIP3), promote OPA1 cleavage and mitochondrial cristae remodeling following reperfusion, which in turn exacerbate IR injury (39,56).

Mitochondrial dynamics facilitate mitochondrial quality control, which targets aberrant mitochondrial proteins or entirely damaged mitochondria for degradation to maintain myocardial mitochondrial homeostasis (57). The ubiquitin-proteasome system (UPS) and the autophagy-lysosomal system, termed mitophagy, are the major proteolytic pathways (58). The clearance of misfolded proteins usually occurs via UPS, whereas the entire damaged mitochondrion is degraded selectively by mitophagy (59). There are interactions and crosstalk between UPS and mitophagy in several regards, for example, the inhibition of proteasome induces the activation of mitophagy (58,60).

Defective mitochondrial proteins are labeled with ubiquitin proteins by a series of E1, E2 and E3 enzymes and targeted into the proteasome for elimination (61). Impaired UPS proteolytic function has been observed in the heart tissue of patients with cardiomyopathy and heart failure (62); however, the enhancement of proteasome-dependent degradation plays a cardioprotective role against proteinopathy and IR injury in mouse models (63). However, the effects of proteasome inhibitors remain controversial, which could be both beneficial and detrimental on cardiac function during myocardial ischemia and reperfusion (64).

Autophagy is induced by the deprivation of oxygen and nutrition, and refers to the lysosomal degradation of unnecessary cellular components, such as protein aggregates, waste lipids and dysfunctional organelles (4). During selective mitochondrial autophagy (mitophagy), the dysfunctional mitochondria are tagged with polyubiquitin, embedded into autophagosomes and delivered to the lysosome for degradation (23,65).

Kinase PINK1 is a Ser/Thr protein kinase that phosphorylates ubiquitin, Parkin and the mitochondrial outer membrane protein Mfn2. The phosphorylation events activate Parkin to translocate from the cytosol to the mitochondria (4,66). Parkin is an E3 ubiquitin ligase that polyubiquitinates the phosphorylated Mfn2 (67), in-turn promoting the binding of mitophagy proteins (sequestosome protein p62/SQSTM1 and autophagy-related protein 8 mammalian homologue LC3) and the cargo sequestration within the autophagosome for the subsequent degradation in lysosomes (4,66).

The loss of PINK1 has been shown to increase the myocar-dial infarct size and generate excess ROS during stimulated IR injury, whereas the overexpression of PINK1 reduces cardiac cell death following stimulated IR injury (68). On the one hand, Parkin-deficiency in the hearts of mice reduces mitophagy, resulting in the accumulation of dysfunctional mitochondria and enlarged infarcts following MI (69). However, excessive Parkin-mediated mitophagy also initiates the induction of apoptotic pathways in cardiac microcirculation endothelial cells and exacerbates microvascular injury, as well as cardiac reperfusion injury (70).

The mitophagy receptors, such as BNIP3, Nip3-like protein X (NIX) (also known as Bcl2-interacting protein 3 like) and FUN14 domain containing 1 (FUNDC1), localize to the mitochondrial outer membrane and serve a role in acute IR injury by regulating mitophagy (4,23,62,65,66). For example, BNIP3 binds to stabilized PINK1, which facilitates the recruitment of Parkin on the mitochondrial outer membrane (71). NIX is ubiquitinated by Parkin, enhancing the recruitment of the autophagy receptor NBR1 and LC3-coated vesicles to the mitochondria (66). Under hypoxic conditions, the heart-enriched FUNDC1 interacts with LC3 to recruit autophagosomes to mitochondria and enhances mitophagy (72). The phosphorylation at Ser¹³ of FUNDC1 by casein kinase 2 (CK2) inhibits the interaction between FUNDC1 and Drp1, ultimately decreasing mitophagy (66). CK2α has been reported to be upregulated during IR stress. As a consequence, FUNDC1 is deactivated and suppresses FUNDC1-mediated mitophagy (4). Ischemic preconditioning has been reported to induce extensive FUNCD1- or Parkin-mediated mitophagy in platelets and reduces secondary ischemic injury (22). In preclinical studies, myocardial conditioning interventions, including ischemic pre-, post-conditioning or remote pre-/per-conditioning, are widely used strategies to reduce infarct sizes following sustained IR. Several signaling pathways activated in response to conditioning stimuli end with the preservation of mitochondrial function (17).

BAG3 is highly expressed in cardiac muscles and functions as a chaperone to target misfolded proteins for lysosomal-mediated degradation (73). BAG3-Pro209Leu mutation causes the dysregulation of autophagy, which is associated with the rapid progression of restrictive cardiomyopathy in myofibrillary myopathies (74).

In neonatal cardiomyocytes, the mitochondria are distributed throughout the cytosol; however, in the adult cardiac cells, the mitochondria are small, round, hypodynamic and relatively static. In particular, they are heterogeneous and are clustered into subsarcolemmal mitochondria (SSM), inter-myofibril mitochondria (IFM) and perinuclear mitochondria subsets with distinct morphologies, localizations and functions (8,17,75). These three mitochondrial subpopulations also possess different sensitivities to pathological processes, such as IR injury. For example, SSM exhibit greater oxidative damage and increased reduction in complex I-mediated respiration than IFM, whereas IFM consume less oxygen than SSM in complex II following IR (17,76). Therefore, the mitochondrial defects in ischemic cells are in a heterogeneously distributed manner amongst distinct subpopulations (76,77). A significant heterogeneity of redox states, Ca²⁺ and ∆Ψm has also been shown in myocardial cells following IR injury (76).

Malonate is a competitive inhibitor of SDH, reducing succinate accumulation and oxidation during myocardial IR injury. Dimethyl malonate is a cell membrane-permeable form of malonate and its protective effect against IR injury have been investigated in purified mitochondria, mouse hearts, and in murine and rabbit models of stroke (14,79,80).

Chloramphenicol succinate (CAPS) is a prodrug of chloramphenicol (CAP), which is already approved for clinical use as a human antibiotic, but with a risk of hemotoxicity, including reversible and irreversible anemia. CAP-induced reversible anemia with reticulocytopenia, often in conjunction with leucopenia and thrombocytopenia, develops with the increasing dose of CAP during treatment. Daily dose levels of CAPS between 500-3,500 mg/kg have been observed to induce significant reversible myelotoxicity in different mouse strains. CAP-induced irreversible anemia is a non-dose-related aplastic anemia with a severe pancytopenia, which is fatal and unpredictable with an incidence of 20-40 cases per million following therapies (81). CAPS can be hydrolyzed by esterase or oxidized by SDH into succinate and CAP, indicating that CAPS may be a competitive substrate of SDH. The active metabolite, CAP, in turn inhibits SDH reductive function, underlying the potential myelotoxicity induced by CAPS (82). The cardioprotective effect of CAPS has been shown in a pig model of MI, where reduced infarct sizes were observed following pre-ischemic in vivo administration of CAPS, as well as in the delayed treatment, where CAPS was administered prior to reperfusion. CAPS may also induce autophagy, indicated by the upregulated specific autophagy markers Beclin-1 and microtubule-associated protein light chain (LC3-II). However, the specific molecular mechanisms underlying its action remain unclear (83).

MitoSNO is a mitochondria-targeted S-nitrosating agent, temporarily inhibiting complex I by reversible S-nitrosation of ND3 Cys³⁹ residue during ischemia. The capability of MitoSNO as a potential drug has been assessed through incubation of mitochondria from rat and mouse hearts, ex vivo heart treatment and in vivo administration in mice models of MI (84).

Amobarbital is also a rapidly reversible inhibitor of complex I, which can improve mitochondrial function and protect cell survival during cardiac IR injury possibly via reducing the release of apoptosis inducing factor from the mitochondrial intermembrane space into cytosol. The protective effects of amobarbital against cardiac IR damage has been assessed in buffer perfused rats and Harlequin (Hq) mouse hearts (85).

Following high-throughput chemical screening and validation, performed by Brand et al (86), two families of the cell-permeant compounds synthesized from commercial companies were identified as effective and selective suppressors of ubiquinone (Q)-binding site of respiratory complex I (site I_Q). Suppressors of site I_Q electron leak (S1QELs), S1QELs 1.1-1.6 and S1QELs 2.2-2.4, can inhibit ROS production at complex I during reverse electron transport without altering basal respiration or the resting OXPHOS. S1QEL1.1 is an outstanding candidate, which strongly suppresses tunicamycin-triggered endoplasmic reticulum stress and caspase signaling pathways that leads to apoptosis in cardiomyocyte H9c2 cells and protects Langendorff-perfused mouse heart models of IR injury from endogenous oxidative damage, including enhancement of cardiac function in post-ischemic recovery and the decrease in infarct size. This highlights S1QEL1.1 as a novel therapeutic agent which can be used at the time of reperfusion. The suppression of ROS generation and oxidative stress signaling by S1QELs have also been assessed in isolated rat skeletal muscle mitochondria, 293 cells, primary astrocytes and live Drosophila melanogaster (86).

Coenzyme Q₁₀ (CoQ₁₀) is an endogenous lipid, with an oxidized-form (ubiquinone) and fully reduced-form (ubiquinol), which is the most common form of CoQ in humans. In addition to its primary role in electron- and proton-transport in mitochondria for production of ATP (87), CoQ₁₀ is also a mitochondria-permeable antioxidant (88). CoQ₁₀ deficiency is associated with several diseases, such as cardiovascular diseases, muscular dystrophy and neurodegenerative disorders (87). Administration of CoQ₁₀ as a supplement along with standard clinical therapy shows positive effects in patients with hypertension (87) and heart failure (89). Higher plasma CoQ₁₀ concentrations in patients with MI lead to improved left ventricular function. An intravenous CoQ₁₀ injection in rat models of coronary artery blockage has been shown to reduce cardiomyocyte necrosis and limit post-infarction hypertrophy of the left ventricle (87). A significant improvement in patients with chronic heart failure was shown in the Q-SYMBIO study (a randomized double-blind trial of 420 international patients) (90).

MitoQ is a bioactive ubiquinone covalent compound linked with a lipophilic cation triphenylphosphonium (TPP), which is reduced into the antioxidant ubiquinol in the mitochondria, and protects against oxidative injury. MitoQ is a promising mitochondria-targeted antioxidant, which has shown positive results in an intravenous and oral toxicity study in mice, in long-term oral administration studies in mice and rats, and in human Phase I and II trials (no significant difference in the NCT00329056 study and a potential benefit in the NCT00433108 study) (91,92).

10-(6′-Plastoquinonyl) decyltriphenyl-phosphonium (SkQ) is a lipophilic cation attached to a plastoquinone, which is a mitochondria-targeted antioxidant that protects cells from age-related diseases and ROS-burst-mediated acute diseases, such as IR. SkQ has not yet been approved by the US Food and Drug Administration as the safety and the clinical application of SkQ requires further study (88).

Bendavia (also known as SS31 and MTP-131) is a Szeto-Schiller (SS) peptide that can penetrate the mitochondria and ameliorate IR injury by interacting with the phospholipid cardiolipin and protecting mitochondrial cristae membranes (93). Positive results have been indicated in animal studies (93,94); however, Bendavia was unsuccessful in the EMBRACE STEMI study (Phase 2a trial). Therefore, MTP-131 is considered a potential pharmacological compound that protects mitochondria, but has not yet successfully translated into clinical use for the patients with ST-elevation MI (95).

MitoGSH is a group of synthetic forms of reduced glutathione (GSH) tagged with SS peptides or TPP ions that can target the mitochondria. MitoGSH is a class of novel drugs that may be highly valuable compounds for treatment of heart diseases by effectively restoring mitochondrial GSH levels. However, the limitations of TPP and SS peptides should be taken into consideration (96).

Euk-8 is a SOD/catalase mimetic antioxidant that is capable of potently scavenging oxyradicals. The positive cardiac-protective effects of Euk-8 include the reduction of both oxidative stress and pressure overload-triggered heart failure in the X-linked Hq mutant and WT mice (97).

α-lipoic acid is an important mitochondria-permeable antioxidant (88). α-lipoic acid is a natural dithiol that exerts protective effects against IR injury in several organs (98) and is used as a treatment of diabetic neuropathy and eye-disorders clinically, but has several side effects (88). CMX-2043 [N-((R)-1,2-dithiolane-3-pentanoyl)-L-glutamyl-L-alanine] is a novel analogue of α-lipoic acid, which has been shown to achieve efficacious reduction of infarct damage in a rat model of myocardial IR injury (98).

Nicotinamide riboside (NR) and nicotinamide mononucleotide (NMN) are the natural precursors of NAD⁺. The supplementation of NR or NMN can increase cellular NAD⁺ levels, without any noticeable side-effects (99,100). Bioactive NMN is synthesized from nicotinamide, a phosphate group and a ribonucleoside by nicotinamide phosphoribosyltransferase (100). Both NR and NMN have been shown to exert beneficial effects on cardio-vascular functions under IR conditions. The administration of NMN has been shown to exhibit timing-dependent patterns on the reduction of infarct size (before ischemia or before reperfusion) (100). Several clinical studies regarding the safety and effects of NR on human physiology are currently underway in Europe and the USA (NCT03432871, NCT03423342 and NCT02812238). NMN is available on the market as a dietary supplement. A Phase I human clinical study for NMN has commenced in Japan and has evaluated the safety and the bioavailability of NMN in humans, with the aim of developing NMN into an anti-aging nutraceutical (99,101).

Cyclosporine A (CsA) is widely used as an immunosuppressive drug following organ transplantation and autoimmune disorders clinically, due to its ability to suppress the transcription of cytokines in activated T cells via blocking the CaN/nuclear factor of activated T cells pathway (95,102). However, CsA is not only an inhibitor of cytosolic CaN, but also an inhibitor of mPTP, binding to mitochondrial cis-transprolyl isomerase cyclophilin D (CyD) (95). CyD is a positive regulator of mPTP with a chaperone localized in the mitochondrial matrix (3,8). The cardioprotective effects of CsA have been assessed in several species of animals using reperfused MI models, with inconsistent results in reduction of infarct size (95). Patients with ST-elevation MI (STEMI) administered CsA have exhibited promising results in a Phase II trial; however, CsA was unsuccessful in the Phase III CIRCUS and CYCLE trials (95,103,104).

NIM811 is a CsA derivative without immunosuppressive capabilities, which can also specifically inhibit mPTP opening in the mitochondria from the reperfused myocardium (95). Adult male New Zealand white rabbits injected with NIM811 at the time of reperfusion have been shown to exhibit preserved OXPHOS in the heart mitochondria, reduced infarct sizes and reduced myocardial damage (105).

Sanglifehrin A (SfA) is a specific inhibitor of cyclophilin D, similar to CsA, although it cannot suppress CaN activity. The specific inhibition of CyD by SfA protects against cardiac IR injury by limiting mPTP opening (3,106). The beneficial effects of SfA have been examined in MI female rat hearts. Significantly improved cardiac function was only shown in reperfused hearts treated with one intravenous bolus of SfA in the acute phase (2 days) of post-MI remodeling (106).

Fibrates have been discovered to activate PPARs, particularly PPARα, which regulate glucose and lipid metabolism in the heart. Fibrates have been widely used as a class of hypolipidemic drugs for treatment of heart attacks and strokes (107,108). Bezafibrate (marketed as Bezalip) is a fibrate drug widely used for the treatment of metabolic syndrome and hyperlipidemias. Bezafibrate is an agonist of PPARα and partially activates PPARγ and PPARδ, upregulating mitochondrial biogenesis by increasing PGC-1α expression (109). A small clinical trial including patients with acute STEMI and hyperfibrinogenemia showed bezafibrate treatment resulted in lower fibrinogen levels and lower frequency of major cardiovascular events compared with conventional therapy (110). The clinical trial Bezafibrate Infarction Prevention (BIP) study with 16 years of follow-up has shown that bezafibrate treatment reduces the risk of cardiac death and the non-fatal MI as well as mortality in patients with coronary arterial diseases (107).

Thiazolidinediones (TZDs) are structurally and pharmaco-logically similar to fibrates and more specifically act on PPARγ. TZD (also known as glitazone) is a class of hypoglycemic drugs used for treatment of type 2 diabetes clinically and protects against cardiovascular diseases. Pioglitazone and rosiglitazone are TZDs, which are also PPARγ agonists and are used as anti-diabetic drugs (108). With the risk of bias and uncertain adverse events, pioglitazone was shown to also reduce non-fatal MI and fatal or non-fatal stroke in four clinical studies (IRIS, NCT00091949; J-SPIRIT, UMIN000013499; Kernan et al (111); and PROactive, NCT00174993) (112). Rosiglitazone has exhibited opposite results in pre-clinical and clinical trials. Rosiglitazone administration to pig and rat with IR-affected hearts has been shown to significantly decrease the infarct size, but without improvement of cardiac mitochondrial function (113). From the data pooled from 42 clinical studies, a significant increase in MI and severe adverse cardiovascular causes were observed with the use of rosiglitazone for patients with type 2 diabetes (114). Only one phase II clinical trial (NCT00064727) has been completed to investigate the therapeutic efficiency of rosiglitazone in patients with congestive heart failure (107).

5-Aminoimidazole-4-carboxamide ribonucleotide (AICAR) is an AMPK agonist, activating PGC-1α by mimicking AMP (109). Serum-starved rat cardiomyocytes stimulated with AICAR have exhibited the full activation of AMPK downstream targets, such as Sirt1 and PGC-1α, which may contribute to mitochondrial homeostasis and cardioprotective effects against ischemic stress (115). Dogs treated with AICAR during cardiopulmonary bypass surgery followed by reperfusion have exhibited an improved recovery of myocardial glucose uptake and utilization (116).

Metformin is also an AMPK activator which exerts protective effects against cardiac ischemia, MI and heart failure. Additionally, metformin is a hypoglycemic drug widely used for the treatment of diabetes. Metformin has been proposed to reduce myocardial IR injury via increasing PGC-1α levels and mitochondrial biogenesis (117). Even though both preclinical and clinical studies (such as the DIGAMI 2 trial) have suggested the cardioprotective effects of metformin against IR injury (118-121), 4 months of metformin treatment in the GIPS-III trial did not result in improved left ventricular function in patients without diabetes presenting with STEMI. The 2-year follow-up results of the GIPS-III trail also revealed no beneficial long-term effects (122).

Resveratrol is a natural polyphenol (stilbenoid) found in red wine, that functions as a Sirt1 and PGC-1α activator, and an inhibitor of mitochondrial ATPase (109). The protective effects of resveratrol have been shown in animal models of cardiovascular, neurodegenerative and metabolic disorders. Five clinical trials of resveratrol for treatment of pre-diabetes and pulmonary diseases are currently in progress (NCT02502253; NCT02565979; NCT03762096; NCT02245932; NCT03819517). However, resveratrol has limitations in human therapeutic application due to its low potency and poor pharmacokinetics. Resveratrol and several other polyphenols are often used as dietary antioxidants (123).

Mitochondrial division inhibitor-1 (Mdivi-1) is a derivative of quinazolinone, which can inhibit mitochondrial fission by decreasing Drp1 activity, thereby reducing short term ischemic stress and myocardial IR injury. Mdivi-1 has been shown to exert cardioprotective effects in pre-treated cardiomyocytes (HL-1 cells), primary isolated neonatal mice ventricular myocytes, hearts from Langendorff perfusion in a rat model of IR, a murine coronary artery ligation model and a pressure overload mouse model with induced heart failure (40,124,125).

P110 is a small peptide (7-amino acids) which blocks the contact between Drp1 and mitochondrial fission 1 protein, ameliorating MI and long-term heart remodeling. P110 peptide has been demonstrated to inhibit excessive mitochondrial fission in primary neonatal rat cardiomyocytes, decreasing the infarct size and improving cardiac function in an ex vivo Langendorff rat heart model and an in vivo rat model of MI (51).

Rapamycin has been found to promote mitophagy by inhibiting the mammalian target of rapamycin (mTOR) pathway and reducing infarct size in MI and cardiomyocyte apoptosis. As an allosteric inhibitor of mTOR complex I (mTORC1), rapamycin plays a role in the suppression of cell growth and division, and has been used as an immunosuppressant drug, or for the treatment of cancer and in-stent restenosis in clinical practice. Rapamycin has also been shown to reduce cardiomyocyte hypertrophy in a mouse model of chronic ischemic injury and to inhibit cardiomyocyte apoptosis in vitro (angiotensin II-induced myocyte apoptosis model) and in vivo (MI-induced chronic heart failure rat model) (126).

miR-499 is an intronic miRNA identified to be involved in inhibiting apoptosis and MI induced by ischemia. miR-499 suppresses the expression of CaN and reduces cell apoptosis following cardiac ischemia, protecting against the MI. miR-499 transgenic mice were previously created, and when they were intravenously injected with the antagomir of miR-499 following IR induction via surgery, they were used for the in vivo evaluation of cardiac function, and hearts harvested from these mice were used for histological and western blot analysis (127).

Superoxide production driven by succinate oxidation upon reperfusion through RET at complex I in the mitochondrial respiratory chain is considered the major source of ROS in IR injury (5). In vivo experiments have indicated that the succinate accumulated during ischemia undergoes rapid oxidation and returns to normoxic levels within 5 min following reperfusion (14). Therefore, it could be an effective therapeutic strategy for the treatment of IR injury by inhibiting RET at complex I for at least 5 min, until the succinate is no longer functional as an electron sink (Fig. 2).

The electron transport chain complex I undergoes a structural change, which is termed 'active/deactive transition' during IR (128). Cys³⁹ in complex I is the critical switch of this conformational transition (Fig. 2), which is exposed in the deactive state of complex I under ischemic conditions and embeds in the reactivated complex I upon reperfusion (5,129). Several thiol-reactive agents can be used to lock complex I in the deactive state by thiol modification on Cys³⁹, including S-nitrosation (-SH into -SNO) by S-nitrosothiols (MitoSNO) or sodium nitrite (NaNO₂) (84,130), S-sulfenylation (-SH into -SOH) by H₂O₂ (131), S-glutathionylation (-SH into -SSG) by glutathione disulfide (GSSG) (132) and S-sulfhydration/persulfidation (-SH into -SSH) by hydrogen sulfide (H₂S) (133). These post-translational modifications can later be reversed by the internal mitochondrial GSH and thioredoxin systems (84).

However, the appropriate onset and duration of administration of thiol-reactive agents remains uncertain, otherwise this intervention based on the structural interconversion of complex I may be an ideal therapeutic method for preventing the burst of ROS production via RET and to return complex I activity in time.

A poor quality of mitochondrial network generates and accumulates excess ROS (35). The burst of mtROS results in a series of downstream oxidative damages in cardiomyocytes after acute MI or during cardiac senescence (134,135), which may lead to sudden cardiac death or heart failure (136).

Mitophagy plays an important role in maintaining mitochondrial quality control, particularly in adult cardio-myocytes (43,137). However, cardiac mitophagy plays both beneficial and detrimental roles in response to IR stress (22,66,138). On the one hand, the clearance of the defective mitochondria via mitophagy may reduce the risk of ROS release and cell apoptosis, which exerts protective effects by decreasing myocardial oxidative stress and infarct size following MI (23,137,138). During IR, additional mitochondrial mass causes excess oxygen consumption and ATP depletion, which exacerbates the energetic stress. When energy is insufficient, active mitophagy can enhance cell survival (19,23). However, excessive mitophagy causes a drastic loss of mitochondrial mass and ATP supply in cardio-myocytes, leading to cell death and heart failure (54,66). When mitophagy is insufficient, the accumulation of damaged mitochondria and mtROS weakens the adaptiveness of cardiomyocytes towards cellular stress and apoptosis (4,66). Therefore, intervention with properly modulated mitophagy can serve as an ideal, yet difficult to achieve, therapeutic method for cardiac IR stress and other diseases (19,66,138). Both mitophagy and mitochondrial biogenesis are upregulated following heart surgery (139). Thus, it is essential to maintain a balance between mitochondrial degradation and biogenesis to maintain mitochondrial homeostasis and myocardial protection under stress (138,140).

Attention must be paid to mitophagy, which is a complex process and intersects with several other cellular events. Some mediators in mitophagy signaling pathways, such as mTOR and AMPK, also play roles in mitochondrial biogenesis (19,66), intrinsic fatty acid metabolism (141), glucose-modulated amino acid sensing and utilization (142), endothelium-dependent vasodilation in vessels (143), vascular smooth muscle cell proliferation and migration (144), suggesting that the manipulation of these may cause a series of unexpected side-effects.

As discussed above in Chapter 5 entitled 'Current developments in mitochondria-targeted agents with cardioprotective effects against IR injury', even though several agents have shown promising cardioprotective effects in pre-clinical studies, notable clinical trials in the past have highlighted the limitations or translational failures. The administration of certain autacoids, such as adenosine, bradykinin and opioids, can mimic the cardioprotective state of ischemic pre-conditioning, triggering several signaling pathways and finally inhibiting the formation of mPTP. As adjunctive therapies, a common limitation of these pre-conditional mimetics is the prerequisite administration before lethal ischemia, which makes them suitable for the planned cardiac surgeries but not effective in the clinical practice of acute MI. Two large-scale clinical trials, AMISTAD I and II, which evaluated the effects of adenosine during acute STEMI therapy, exhibited restrictive infarct size-reduction and a number of adverse events, such as hypotension, bradycardia, heart block and ventricular tachycardia, especially in the adenosine patients with nonanterior MI (145).

Bradykinin, as the vasodilatory peptide, plays a role in decreasing blood pressure and increasing vascular permeability (146). Bradykinin signaling deficiency may be responsible for the vascular contraction and the high epithelial Na⁺ reabsorption observed in patients with hypertension and cardiovascular diseases. Bradykinin signaling has also been demonstrated to reduce inflammation and endothelial apoptosis in animal models of MI and cardiac IR injury (147). However, an increasing bradykinin concentration either inherited or acquired, which is a main mediator of hyper-permeability of capillaries and accumulation of local edema fluid, results in a rare disease termed bradykinin-mediated angioedema (146,148).

Opioids, such as morphine have been widely and frequently used as analgesics for the patients with STEMI (149). First of all, STEMI patients often have intense chest pain and anxiety in the acute phase of the treatment. As a traditional analgesia, opioids are effective in symptomatic relief. In addition, the reduction of pain and stress also results in vasodilation, an increase in blood flow, a decrease in arterial blood pressure and heart rate, equilibrating the supply and demand of oxygen and nutrients in cardiomyocytes (149,150). However, increased severe side-effects of opioids in STEMI patients have been revealed in recent clinical studies. For example, the low myocardial contractility, hypotension and fainting due to morphine-induced peripheral vasodilation are the main hemodynamic adverse effects for the patients with ventricular failure. A long-term use of opioids raises the risk for respiratory and gastrointestinal adverse effects, such as suppression of breathing, gut motility and absorption (150). Therefore, opioid administration may disrupt the absorption of certain essential oral medicaments, such as platelet inhibitors, and consequently delay the action of antiplatelet agents and prolong the platelet reactivity in the treatment of STEMI (149).

One of the major reasons for the limited clinical success is incomplete or insufficient pre-clinical investigation that does not offer accurate, reproducible and systematic examination of results from multiple animal models before large-scale clinical trials. The multicenter CAESAR (Consortium for PreclinicAl AssESsment of CARdioprotective Therapies) initiative supported by the National Heart Lung and Blood Institute was created to improve translation of cardioprotective therapies into clinical use (151). CAESAR promotes integrated, standardized, solid and rigorous preclinical evaluations to examine potential drugs or combined therapies in centralized laboratories.