Myocardial mitochondrial injury induced by pulmonary exposure to particulate matter in rats.

Exposure to air pollution has been associated with acute myocardial ischemia, impaired myocardrial function, and ST-segment depression. Particulate matter (PM)-associated metals, especially vanadium and nickel, have been implicated in observed cardiovascular impairments. We aimed to assess the effect of single intratracheal pulmonary exposure to vanadium-rich respirable oil combustion PM (HP-10) on the intrinsic myocardial ischemic tolerance and mitochondrial integrity in rats. The authors subjected isolated heart tissue slices derived from saline or PM-exposed rats to low glucose low oxygen induced ischemia followed by oxygenated condition with glucose supplementation. Mitochondrial structural integrity was determined by TEM (transmission electron microscopy) and functionality by the 3-(4, 5 dimethylthiazol-2yl)-2, 5 diphenyltetrazolium bromide (MTT) assay. Rats exposed to PM exhibited no apparent inhibition of mitochondrial dehydrogenase activity in oxygenated conditions at 24 or 48 hr post-PM exposure. However, in conditions of simulated ischemia/reoxygenation, these heart slices showed a delayed but consistent and significant decrease in dehydrogenase activity compared to controls at 48 hr after exposure to PM. Electron microscopy revealed significant myocardial mitochondrial injury upon exposure to PM characterized by mitochondrial swelling and fusion. The authors conclude that exposure to soluble vanadium-rich PM induces mitochondrial functional impairment and structural abnormality, which compromises mitochondrial respiration and results in decreased tolerance to ischemia/reoxygenation in rats.

Successful restoration of function of frozen and thawed isolated rat hearts.

OBJECTIVE: Long-term organ preservation for transplantation may allow optimal donor-recipient matching with potential reduction in the incidence and severity of rejection. Complete cessation of metabolism may be obtained by freezing. Previous attempts to freeze intact mammalian hearts were limited to -3.6 degrees C, restricting tissue ice content to 34%. We hypothesized that our method will allow recovery of function of the intact rat heart after freezing to -8 degrees C, a temperature at which most of the tissue water is frozen. METHODS: Isolated rat hearts were attached to a Langendorff apparatus. After normothermic perfusion, cold cardioplegia was induced followed by perfusion with a cryoprotecting agent. Hearts were than frozen to -8 degrees C (45 +/- 8 minutes), thawed, and reperfused (60 minutes). RESULTS: All frozen and thawed hearts regained normal electric activity. At -8 degrees C, ice content was 64.36% +/- 13%. The use of 10% ethylene glycol for cryoprotection (n = 13) resulted in recovery (mean +/- standard deviation) of 49.7% +/- 21.8% of +dP/dt, 48.0% +/- 23.5% of -dP/dt, 65.2% +/- 30.8% of coronary flow, and 50.4% +/- 23.9% of left ventricular developed pressure. Hearts in this group (n = 4) maintained 81.3% +/- 10% viability compared with 69.3% +/- 14% (not significant) in control hearts kept at 0 degrees C for the same duration. Energy stores, represented by adenosine triphosphate and phosphocreatine, were depleted to 12.2 +/- 6.1 micromol/g dry weight and 22.5 +/- 6.4 micromol/g dry weight, respectively, compared with 19.0 +/- 2.5 micromol/g dry weight and 36.6 +/- 3.0 micromol/g dry weight, respectively (P < .05) in the control hearts. The integrity of muscle fibers and intracellular organelles after thawing and reperfusion was demonstrated by electron microscopy. CONCLUSION: We demonstrate for the first time the feasibility of functional recovery after freezing and thawing of the isolated rat heart while maintaining structural integrity and viability.

Occult cardiotoxicity: subtoxic dosage of Bis(2-chloroethoxy)methane impairs cardiac response to simulated ischemic injury.

The effect of Bis(2-chloroethoxy)methane (CEM) on myocardial response to ischemia was tested in rats. CEM was dermally applied for 3 days to F344/N male rats, at 0, 100, 400, or 600 mg/kg/d. Subsequently, left ventricular sections were prepared from each rat heart. Part of the sections from each heart were exposed to 90 minutes of simulated ischemia, followed by 90 minutes of reoxygenation. The rest of the sections were continuously oxygenated. Mitochondrial activity was assessed in the sections by the MTT colorimetric assay, reflecting dehydrogenases redox activity. Myocardial toxicity occurred in response to 400 and 600 mg/kg, characterized by myofiber vacuoles, necrosis, and mononuclear infiltrates. The latter dose was lethal. In sections from rats treated with 400 mg/kg CEM, redox activity was decreased by 21% (p<0.01) in oxygenated conditions and by 45% (p<0.01) in ischemia-reoxygenation, compared to controls. Hearts of rats treated with 100 mg/kg/d CEM showed normal histology. Their mitochondrial activity did not differ from that of untreated rat hearts in oxygenated conditions. However, in ischemia-reoxygenation, their redox activity was significantly lower (by 46%, p<0.01) than that of untreated rat hearts. These results demonstrate that subtoxic dosage of a cardiotoxic agent may cause occult cardiotoxicity, reflected by impaired response to ischemia.

Dexrazoxane prevents myocardial ischemia/reperfusion-induced oxidative stress in the rat heart.

INTRODUCTION: Dexrazoxane (Dex), used clinically to protect against anthracycline-induced cardiotoxicity, possesses iron-chelating properties. The present study was designed to examine whether Dex could inhibit the ischemia/reperfusion (I/R) induced damage to the rat heart. MATERIALS AND METHODS: Isolated perfused rat hearts were exposed to global ischemia (37 degrees C) and 60 min reperfusion. Dex was perfused for 10 min prior to the ischemia, or administered intraperitoneally (150 mg) 30 min prior to anesthesia of the rats. I/R caused a significant hemodynamic function decline in control hearts during the reperfusion (e.g., the work index LVDP X HR declined to 42.7+/-10%). Dex (200 microM) applied during the preischemia significantly increased the hemodynamic recovery following reperfusion (LVDP X HR recovered to 55.7+/-8.8%, p<0.05 vs. control). Intraperitoneal Dex, too, significantly increased the hemodynamic recovery of the reperfused hearts. I/R caused an increase in oxidation of cytosolic proteins, while Dex decreased this oxidation. DISCUSSION: The decrease in proteins carbonylation and correlative hemodynamic improvement suggests that Dex decreases I/R free radical formation and reperfusion injury.

Apomorphine-induced myocardial protection is due to antioxidant and not adrenergic/dopaminergic effects.

Apomorphine (Apo), a dopaminergic agonist used for treatment of Parkinson disease, is a potent antioxidant. In addition to its antioxidative effects, the dopaminergic and adrenergic effects of Apo were studied. Isolated perfused rat hearts were exposed to 25 min of no-flow global ischemia (37 degrees C) and 60 min of reperfusion (I/R, control). Drugs were introduced for the first 20 min of reperfusion. The LVDP of the control group recovered to 54.6 +/- 3.3%. Apo-treated hearts had significantly improved recovery (61.6 +/- 5%, p < 0.05). The recovery of the work index LVDP x HR was even bigger: 67.8 +/- 3.7% (Apo treatment) vs 41.7 +/- 4.6% (control, p < 0.001). Haloperidol, a dopaminergic antagonist, did not affect the recovery with Apo. Propranolol, a beta-adrenergic blocker, initially inhibited the effect of Apo. However, the recovery of the combined group (Apo + propranolol) increased and reached significance (LVDP, p < 0.05 vs control group) after cessation of propranolol perfusion. At 60 min of reperfusion this group was superior to Apo-treated hearts (LVDP, p < 0.05). Propranolol (without Apo) did not improve the hemodynamic recovery. The same pattern of recovery applies also to the recovery of the +dP/dt during the reperfusion. L-DOPA was less effective than Apo. I/R caused significant increase in carbonylation of proteins. Apomorphine inhibited the increase in carbonylation. Haloperidol did not affect this beneficial effect of Apo. L-DOPA significantly decreased the carbonylation of proteins. We conclude that the antioxidative effect of Apo is its main mechanism of cardioprotection.

Apomorphine prevents myocardial ischemia/reperfusion-induced oxidative stress in the rat heart.

This study examined the hypothesis that low-concentration apomorphine improves postischemic hemodynamic and mitochondrial function in the isolated rat heart model by attenuating oxidation of myocardial proteins. Control and apomorphine-treated hearts were subjected to 35 min of perfusion, 25 min of normothermic global ischemia, and 60 min of reperfusion. Apomorphine (2 microM) was introduced into the perfusate for 20 min starting from the onset of reperfusion. Apomorphine significantly (p <.05) improved postischemic hemodynamic function: work index of the heart (product of LVDP and heart rate) was twice as high in apomorphine-treated hearts compared to controls at the end of reperfusion (p <.01). After isolation of cardiac mitochondria, the respiratory control ratio (RCR) was calculated from the oxygen consumption rate of State 3 and State 4 respiration. Apomorphine significantly improved postischemic RCR (87% of preischemic value vs. 39% in control, p <.05). Using an immunoblot technique, carbonyl content of multiple unidentified myocardial proteins (mitochondrial and nonmitochondrial) was observed to be elevated after global ischemia and reperfusion. Apomorphine significantly attenuated the increased protein oxidation at the end of reperfusion. These results support the conclusion that apomorphine is capable of preventing ischemia/reperfusion-induced oxidative stress and thereby attenuating myocardial protein oxidation and preserving mitochondrial respiration function.