Reactive oxygen species are critical mediators of coronary collateral development in a canine model.

Recent evidence suggests that reactive oxygen species (ROS) promote proliferation and migration of vascular smooth muscle (VSMC) and endothelial cells (EC). We tested the hypothesis that ROS serve as crucial messengers during coronary collateral development. Dogs were subjected to brief (2 min), repetitive coronary artery occlusions (1/h, 8/day, 21 day duration) in the absence (occlusion, n = 8) or presence of N-acetylcysteine (NAC) (occlusion + NAC, n = 8). A sham group (n = 8) was instrumented identically but received no occlusions. In separate experiments, ROS generation after a single 2-min coronary artery occlusion was assessed with dihydroethidium fluorescence. Coronary collateral blood flow (expressed as a percentage of normal zone flow) was significantly increased (71 +/- 7%) in occlusion dogs after 21 days but remained unchanged (13 +/- 3%) in sham dogs. Treatment with NAC attenuated increases in collateral blood flow (28 +/- 8%). Brief coronary artery occlusion and reperfusion caused ROS production (256 +/- 33% of baseline values), which was abolished with NAC (104 +/- 12%). Myocardial interstitial fluid produced tube formation and proliferation of VSMC and EC in occlusion but not in NAC-treated or sham dogs. The results indicate that ROS are critical for the development of the coronary collateral circulation.

Atrial pacing lead location alters the hemodynamic effects of atrial-ventricular delay in dogs with pacing induced cardiomyopathy.

The role of atrial lead location in cardiovascular function in the presence of impaired ventricular dysfunction is unknown. We tested the hypothesis that left atrial (LA) and left ventricular (LV) hemodynamics are affected by alterations in AV delay and are influenced by atrial pacing site in dogs with dilated cardiomyopathy. Dogs (n = 7) were chronically paced at 220 beats/min for 3 weeks to produce cardiomyopathy and then instrumented for measurement of LA, LV end diastolic pressure (LVEDP) and mean arterial pressure (MAP), LA volume, LV short-axis diameter, and aortic and pulmonary venous blood flow. Hemodynamics were measured after instrumentation and during atrial overdrive pacing from the right atrial appendage (RAA), coronary sinus ostium (CSO) and lower LA lateral wall (LAW). The AV node was then ablated, and hemodynamics were compared during dual chamber AV pacing (right ventricular apex) from each atrial lead location at several AV delays between 20 and 350 ms. Atrial overdrive pacing from different sites did not alter hemodynamics. Cardiac output (CO), stroke volume, LVEDP, MAP and +dLVP/dt demonstrated significant (P < 0.05) variation with AV delay during dual chamber pacing. CO was higher during LAW pacing than RAA and CSO pacing (2.3 +/- 0.4 vs 2.1 +/- 0.3 vs 2.0 +/- 0.3 l/min, respectively) at an AV delay of 120 ms. Also, MAP was higher in the LAW than RAA and CSO (65 +/- 9 vs 59 +/- 9 vs 54 +/- 11 mmHg, respectively) at an AV delay of 350 ms. Atrial lead location affects indices of LV performance independent of AV delay during dual chamber pacing in dogs with cardiomyopathy.

An intramyocardial catheter for repeated in vivo sampling of interstitial fluid.

INTRODUCTION: Coronary collateral development is an important adaptive response to chronic myocardial ischemia. Characterization of mitogenic factors responsible for collateral formation has been an elusive goal because these substances are difficult to sample from the myocardial interstitium at multiple times. We report the implantation of an exchange catheter capable of in vivo sampling of myocardial interstitial fluid in chronically instrumented dogs. METHODS: The catheter consisted of multiple perforations within a 2-cm segment of Micro-Renathane tubing that was implanted into the left ventricular myocardium between the left anterior descending (LAD) and left circumflex coronary artery (LCCA) perfusion territories and secured to the epicardium with a Silastic disk. Dogs (n=5) underwent brief (2 min) LAD occlusions once per hour, 8 times/day, 7 days/week for 2 weeks to stimulate coronary collateral growth. Another group of dogs (n=6) without repetitive coronary occlusions served as controls. Myocardial interstitial fluid was collected daily, and mitogenic activity was evaluated by the proliferative responses of growth-arrested, cultured vascular smooth muscle and endothelial cells. RESULTS: All dogs tolerated catheter implantation without complication. Each catheter functioned well throughout the duration of the experiment. Myocardial interstitial fluid obtained using the exchange catheter in this model of repetitive coronary occlusion produced marked proliferation of vascular smooth muscle and endothelial cells in vitro. DISCUSSION: The exchange catheter enables chronic in vivo sampling of myocardial interstitial fluid and may facilitate identification of mitogens involved in coronary collateral development.

Increases in coronary collateral blood flow produced by sevoflurane are mediated by calcium-activated potassium (BKCa) channels in vivo.

BACKGROUND: Sevoflurane enhances coronary collateral blood flow independent of adenosine triphosphate-regulated potassium channels. The authors tested the hypothesis that this volatile anesthetic increases coronary collateral blood flow by either opening calcium-activated potassium channels or by directly stimulating nitric oxide synthesis in the canine coronary collateral circulation. METHODS: Twelve weeks after left anterior descending coronary artery ameroid constrictor implantation, barbiturate-anesthetized dogs (n = 22) were instrumented for measurement of hemodynamics and retrograde coronary flow. Dogs received sevoflurane ([0.5 and 1.0 minimum alveolar concentration [MAC]) during intracoronary infusions of drug vehicle (0.9% saline), the calcium-activated potassium channel antagonist iberiotoxin (13 microg/min), or the nitric oxide synthase inhibitor -nitro-l-arginine methyl ester (l-NAME, 300 microg/min). Retrograde coronary collateral blood flow was measured under baseline conditions, during and after administration of sevoflurane, and during intracoronary infusion of bradykinin. Data are mean +/- SEM. RESULTS: Sevoflurane increased (* < 0.05) retrograde coronary collateral blood flow (from 65 +/- 11 during control to 67 +/- 12* and 71 +/- 12* ml/min during 0.5 and 1.0 MAC, respectively). Iberiotoxin but not l-NAME attenuated these sevoflurane-induced increases in retrograde flow (6 +/- 1*, 7 +/- 2*, and 3 +/- 2 ml/min during vehicle, l-NAME, and iberiotoxin, respectively). After discontinuation of sevoflurane, retrograde flow returned to baseline values in each group. Bradykinin increased retrograde flow in vehicle- (63 +/- 12 to 69 +/- 12* ml/min) but not in iberiotoxin- (61 +/- 7 to 62 +/- 5 ml/min) or l-NAME-treated dogs (64 +/- 11 to 63 +/- 10 ml/min). CONCLUSIONS: The results demonstrate that sevoflurane increases coronary collateral blood flow, in part, through activation of calcium-activated potassium channels. This action occurs independent of nitric oxide synthesis.

An automated coronary artery occlusion device for stimulating collateral development in vivo.

INTRODUCTION: Repetitive, brief coronary artery occlusions produce collateral development in experimental animals. This model causes coronary collateralization in a highly reproducible fashion, but the process is very labor intensive. We report the design and use of a fully automated hydraulic coronary occlusion device capable of producing repetitive coronary occlusions and enhancement of coronary collateral development in dogs. METHODS: The device consists of analog electronics that allow adjustment of occlusion number, frequency, pressure and duration, and mechanical components responsible for the coronary occlusion. The motor and piston of the device are coupled to a chronically implanted hydraulic vascular occluder placed around the left anterior descending coronary artery (LAD) of dogs instrumented for measurement of systemic and coronary hemodynamics. One group of dogs (n = 6) underwent brief (2 min) LAD occlusions once per hour, eight times per day, 5 days/week for 3 weeks to stimulate collateral development (measured using radioactive microspheres). Another group of dogs (n = 6) that did not receive repetitive occlusions served as controls. RESULTS: The device reproducibly produced repetitive LAD occlusions for the duration, frequency, and time interval initially programmed. A time-dependent increase in transmural collateral blood flow was observed in dogs undergoing repetitive occlusions using the device. Collateral blood flow was unchanged in dogs that did not undergo occlusions. DISCUSSION: The automated occluder device reliably produces repetitive coronary occlusions and may facilitate further study of coronary collateral development in response to chronic myocardial ischemia.