Khawar Mehdi

Activation of MAP Kinase In Vivo Follows Balloon Overstretch Injury of Porcine Coronary and Carotid Arteries

Vascular restenosis involves contraction, proliferation, and remodeling of the arterial wall in response to overstretch injury. Mitogen-activated protein kinases (MAPKs) are implicated in both contraction and proliferation of vascular smooth muscle (VSM), and studies of porcine carotid arterial muscle strips have shown that mechanical stretch leads to the activation of the extracellular signal-regulated kinase (ERK) family of MAPKs in vivo. We, therefore, analyzed the acute effect of mechanical overstretch injury on ERK-MAPK (herein referred to simply as MAPK) activity in porcine coronary and carotid arteries in vivo. Balloon angioplasty catheters were inflated to 6 atm three times over 5 minutes at a balloon-artery ratio of 1.2:1 in either porcine coronary or carotid arteries. The arteries were snap-frozen after angioplasty, and MAPK activity was measured. Angioplasty of the left anterior descending (LAD, n = 5), left circumflex (LCx, n = 5), and carotid (n = 5) arteries effected an increase in MAPK activity compared with the activity in uninstrumented right coronary arteries (RCAs) or carotid arteries from the same animals used for controls. Balloon angioplasty of carotid arteries led to an increase in MAPK activity that was 7.7-fold over the activity in control arteries and comparable to the activity in stretched carotid arterial muscle strips in vivo. The increase in coronary artery kinase activity on angioplasty was variable from animal to animal. The increase in MAPK activity over that in control arteries ranged from 4.5- to 31.7-fold (mean +/- SEM, 10.7 +/- 5.3) in the LAD and 1.8- to 31.3-fold (mean +/- SEM, 9.7 +/- 5.7) in the LCx. There were no apparent inherent differences in the levels of MAPK activity in the three different types of coronary arteries (RCA, LAD, and LCx) without instrumentation. MAPK activation occurs rapidly during angioplasty, suggesting that this kinase may play an early role in initiating the injury response in both porcine coronary and carotid arteries. MAPKs may be key enzymes targeted to treat or prevent restenosis.

Microparticle deposition in periarterial microvasculature and intramural dissections after porous balloon delivery into atherosclerotic vessels: Quantitation and localization by confocal scanning laser microscopy

Local delivery of pharmacologic or genetic agents with a porous balloon catheter offers a potential therapeutic approach to reducing restenosis and atherosclerosis and minimizing undesirable systemic toxicity. However, the delivery efficiency and intramural retention of liquid agents is low. The local intramural delivery and prolonged retention of 5 microns microparticles (MP) has been described previously. The current study was designed to evaluate the distribution of locally delivered MPs and to determine the effects of MP size and infusion pressure on intramural delivery efficiency. A 1% suspension of fluorescent, latex MPs (1 or 4.5 microns in diameter) was infused at either 3 or 6 atm into atherosclerotic rabbit femoral arteries (n = 32) immediately after angioplasty. Four groups of arteries were evaluated: 1) 1 micron MPs infused at 3 atm; 2) 1 micron MPs at 6 atm; 3) 4.5 microns MPs at 3 atm; and 4) 4.5 microns MP at 6 atm. The location of MPs was evaluated by fluorescent and light microscopy and confocal laser scanning microscopy. The tissue was dissolved and the delivered MPs quantified. All groups manifested numerous MPs within the vasa vasorum and periadventitial microvasculature, with a substantially lesser number within the neointimal and medial layers. The intramural deposition of the MPs was associated with dissection within the intima or media caused by the antecedent angioplasty or local delivery, indicating that an intact vessel wall is an anatomic barrier to MP delivery. The median values of fractional intramural delivery, defined as the percentage of infused MPs retained within the arterial wall, were 0.059%, 0.071%, 0.047%, and 0.062% for the groups 1 through 4, respectively (p not significant [NS]). The values of intramural particle concentration, expressed as the total number of MPs per weight of arterial tissue, were 55, 65, 1.5, and 1.2 x 10(4) MPs/mg for groups 1 through 4, respectively (p < 0.001 for 1 micron vs 4.5 microns MPs). Although more 1 microM MPs were delivered than 4.5 microns MPs, the fractional intramural delivery was unaffected by particle size or infusion pressure. The local delivery of MPs at atherosclerotic sites after angioplasty is characterized by fractional intramural delivery values similar to values of nonparticulate agents, with few MPs deposited into intima or media in the absence of a dissection caused by the antecedent angioplasty or the delivery procedure itself.

Increased Intramural Retention After Local Delivery of Molecules with Increased Binding Properties: Implications for Regional Delivery of Pharmacologic Agents.

Background: Catheter-based local vascular delivery results in concentrated quantities of pharmaceutical agents or genes into focal areas of the arterial wall. However, intramural retention is short and has reduced the potential efficacy of this approach. It was postulated that agents that possess increased intramural binding would show increased intramural reten tion. Platelet-derived growth factor (PDGF) and basic fibroblast growth factor (bFGF) were models of agents with increased cellular and extracellular matrix binding properties. Methods and Results: The delivery efficiency and intramural retention of 2 mL of saline containing I125 labeled PDGF (n = 35 arteries) and bFGF (n = 24) were compared with albumin (n = 21) after local delivery into porcine coronary arteries. Animals were sacrificed at three or more prespecified timepoints: immediately after delivery, 1 day, or 3 days after delivery and if necessary at 5 or 7 days to document prolonged retention. Autoradiograms of the arterial sections were evaluated for the extent of delivery. Delivery efficiency, defined as the amount leaving the catheter and retrieved from the arterial wall, was 0.60% ± 0.42% for albumin, 1.98% ± 0.88% for PDGF (P = .001), and 0.31% ± 0.11% for bFGF. The calculated intramural half-life of albumin was 7.4 hours, 56.2 hours for PDGF, and 14.9 hours for bFGF (P = .0001 for PDGF). Infusate covering >50% of the medial area was observed in 85% of arteries immediately after delivery. Although myocardial delivery was similar for albumin, PDGF, and bFGF, myocardial retention was significantly longer for bFGF (P < .001). Conclusions: Molecules that exhibit preferential intramural binding show a longer intra mural residence duration than solutes without such binding properties. In addition, delivery and subsequent prolonged retention in the myocardium can be obtained by local delivery via the arterial lumen of solutions with preferential binding properties.

TCTAP A-144 Response of Loading Dose & Follow-up of Prasugrel (PRISA) on Platelet Aggregation in Coronary Artery Disease Patients Undergoing Percutaneous Coronary Intervention

The use of dual antiplatelet therapy with aspirin and a thienopyridine in coronary artery disease (CAD) is an essential aspect of a supportive pharmacologic regimen administered to patients undergoing percutaneous coronary intervention (PCI). Prasugrel, a thienopyridine reduces platelet aggregation