Fibrin glue containing fibroblast growth factor type 1 and heparin decreases platelet deposition.

BACKGROUND: The early success rates of endarterectomy and angioplasty are influenced by the thrombogenicity of the deendothelialized surface. We previously reported decreased platelet deposition after 30 and 120 minutes and after 28 days on expanded polytetrafluoroethylene (ePTFE) grafts coated with fibrin glue (FG) containing fibroblast growth factor type 1 (FGF-1) and heparin in canine aortoiliac bypass grafts when compared with control uncoated grafts. The FG/FGF-1/heparin coating has been shown to enhance spontaneous endothelialization at 28 days in canine ePTFE bypass grafts. The current study evaluates the thrombogenicity of this FG/FGF-1/heparin suspension applied to a balloon de-endothelialization model of endarterectomy in canine carotid arteries. METHODS: Nine dogs underwent bilateral, deendothelialization balloon injury to 6-cm segments of their carotid arteries. Fibrin glue (fibrinogen 32.1 mg/mL + thrombin 0.32 U/mL) containing FGF-1 (11 ng/mL) and heparin (250 U/mL) was applied to the luminal surface of one carotid artery in each dog. Both femoral arteries were circumferentially dissected but not balloon injured; one femoral artery was clamped for the same period as the carotid arteries. In the 6 acute dogs, 10 minutes prior to the restitution of flow in both carotid arteries and one femoral artery, 4 to 8 x 10(9) (111)In-labelled autologous platelets were injected intravenously. Four-cm segments of both carotid and femoral arteries were excised after 15 or 120 minutes of circulation (n = 3/time/artery, 24 arteries). In the 3 chronic dogs, the radiolabelled platelets were injected 30 days after carotid injury. The carotid and femoral vessels were then excised after 120 minutes of perfusion. Radioactive platelet deposition was quantitated by gamma counting. RESULTS: After 2 hours, the injured carotid arteries demonstrated significantly more platelet deposition than either uninjured femoral artery controls (P < 0.001). There was also a significant 45.2% decrease (P = 0.008) in platelet deposition on the balloon injured carotid arteries treated with FG/FGF-1/heparin when compared with balloon injured carotid arteries alone. At 30 days there was an insignificant trend toward decreased thrombogenicity in the FG/FGF-1/heparin treated injured carotids. CONCLUSION: Surface coating with FG/FGF-1/heparin significantly decreases platelet deposition on balloon injured canine carotid arteries after 2 hours of perfusion and may be clinically applicable in endarterectomy and angioplasty procedures. The long-term induction of reendothelialization of arterial surfaces by this technique is under investigation.

Fibrin glue containing fibroblast growth factor type 1 and heparin with autologous endothelial cells reduces intimal hyperplasia in a canine carotid artery balloon injury model.

PURPOSE: Intimal hyperplasia plagues all types of vascular intervention. Early confluent re-endothelialization may attenuate the smooth muscle cell (SMC) proliferative response. We previously reported that fibroblast growth factor type 1 (FGF-1) and heparin at relative concentrations of 10 ng/ml:250 U/ml delivered in a fibrin glue (FG) suspension can selectively stimulate endothelial cells (EC) and inhibit SMC proliferation in cell culture. This current study evaluates this surface treatment with and without seeded autologous ECs on intimal hyperplasia in a canine carotid artery balloon injury model. METHODS: Twenty-nine adult dogs underwent bilateral balloon injury to a 6 cm segment of their carotid arteries. The injury resulted in a reproducible removal of the intima and 4 to 6 medial lamellae. Nine dogs were used in part I to determine the percent retention of FGF-1 and EC when applied in a FG suspension to the balloon-injured carotid arteries. Part 2 used the remaining 20 dogs to determine the effect of this surface treatment on intimal hyperplasia. In 10 group I dogs, FG (fibrinogen 32.1 mg/ml and thrombin 0.32 U/ml) containing FGF-1 (11 ng/ml) and heparin (250 U/ml) was applied to the luminal surface of one carotid artery, whereas the contralateral carotid artery underwent balloon injury alone. In 10 group II dogs, an identical FG preparation with FGF-1 and heparin was applied to the surface of one carotid artery, whereas the contralateral carotid artery received FG/FGF-1/heparin that also contained autologous ECs (P3; 5 x 10(4) to 10 x 10(4) cells/cm2). Five dogs from both group I and group II were killed at 10 days and the remaining 10 dogs at 30 days. Histologic analysis and computerized morphometric analysis were used to determine intimal and medial thickness and area, percent endothelialization, and medial SMC proliferative rate. RESULTS: There was no measurable neointima in any 10-day dog. There was no difference in neointimal area between the treatments in group I 30-day dogs. There was a significant decrease in maximal neointimal area, intima/media thickness ratio, and intima/media area ratio in group II 30-day dogs that were treated with FG/FGF-1/heparin plus EC. There was an insignificant increase in percent EC coverage and an insignificant decrease in medial SMC proliferative rate in group II 10-day dogs treated with FG/FGF-1/heparin plus EC. CONCLUSIONS: In this canine carotid model, FG with FGF-1 and heparin did not induce significant intimal or medial thickening after 10 or 30 days when compared with vessels that were only balloon-injured. The seeding of autologous ECs within the FG/FGF-1/heparin suspension caused a reduction in neointima formation with no concomitant medial thickening 30 days after injury. The use of FG to locally deliver FGF-1 and ECs may have clinical relevance in the inhibition of intimal hyperplasia.

Platelet deposition on ePTFE grafts coated with fibrin glue with or without FGF-1 and heparin.

INTRODUCTION: The disappointing long-term patency of small-caliber prosthetic grafts may be due in part to early thrombogenicity of the prosthetic surface. We previously reported that the coating of expanded polytetrafluoroethylene (ePTFE) with fibrin glue (FG) containing fibroblast growth factor type 1 (FGF-1) and heparin accelerated spontaneous endothelial coverage of ePTFE grafts in an animal model; however, FG's effect on platelets remains unclear. This study was done to evaluate platelet deposition onto GF/FGF-1/ heparin-coated vs FG-coated vs whole-blood-preclotted ePTFE surfaces. METHODS: Twelve 5-cm ePTFE grafts were treated either with FG (thrombin, 0.32 U/ ml, and fibrinogen, 32.1 mg/ml, n = 8) or with FG containing FGF-1 (11 ng/ml) plus heparin (250U/ml, n = 4). Twelve control ePTFE grafts were preclotted with canine (n = 8) or human (n = 4) whole blood. These treated grafts were placed onto a loop pulsatile perfusion system in pairs (preclotted with either FG or FG/ FGF-1/heparin) and perfused with a M-199/10% FBS/ 111indium-labeled platelet suspension. After 60 min the grafts were gamma counted and CPM/mm2 were determined. RESULTS: In both trials, the preclotted ePTFE grafts demonstrated similarly increased platelet deposition when compared to grafts treated with FG/FGF-1/heparin or FG alone (P < 0.001 for each). CONCLUSION: The decrease in platelet deposition on the FG/FGF-1/ heparin-coated grafts vs preclotted grafts is not due to heparin and is not specific to canine or human platelets. FG-coated grafts may induce a decrease in early graft thrombogenicity when compared to whole blood preclotting.

Angioscopy.

Angiography currently is the principle diagnostic test for evaluation of the vasculature. Though this invasive radiologic procedure demonstrates vascular anatomy and areas of narrowing and blockage, it does not define the specific cause of the occlusion. This limitation may inhibit the appropriate treatment of vascular disease. Recently, a variety of endovascular tools designed for the treatment of specific disorders have been developed, such as lytic therapy for thrombotic occlusions, lasers for fibrotic occlusions, and atherectomy catheters for calcific atherosclerotic occlusions. For effective use of these tools, the specific cause of a vascular lesion must be determined. Angioscopy can enhance the use of these innovative therapies by providing a real-time panoramic view of the lumen, which permits both the diagnosis of luminal irregularities and visual guidance of specific luminal therapy.