In vivo comparison of a polymer-free Biolimus A9-eluting stent with a biodegradable polymer-based Biolimus A9 eluting stent and a bare metal stent in balloon denuded and radiated hypercholesterolemic rabbit iliac arteries.

OBJECTIVES: To evaluate the effect of a polymer-free Biolimus A9-eluting stent [BioFreedom (BF)], compared with that of a biodegradable polymer-based Biolimus A9-eluting stent [BioMatrix Flex (BMF)] and a bare metal stent (BMS) in balloon denuded and radiated hypercholesterolemic rabbit iliac arteries. METHODS: Rabbits were fed with 1% cholesterol diet (n = 14) for 14 days, both iliac arteries were balloon denuded and radiated, and then rabbits were switched to 0.15% cholesterol diet. After 4 weeks, BF (n = 8), BMF (n = 8), and BMS (n = 8) were deployed in denuded and radiated areas. Four weeks later animals were euthanized, arterial segments were processed for morphometry. RESULTS: The neointimal area in vessels implanted with BF stents was significantly less than that seen in vessels implanted with BMS (0.90 mm(2) ± 0.14 vs. 1.29 mm(2) ± 0.23, P <0.01). Percent fibrin and fibrin score were higher with BMF stents compared to BMS (P <0.03 and <0.04) and giant cell number was significantly higher with both BMF and BF stents (P < 0.01 for both). Percent endothelialization was significantly higher and % uncovered struts were lower with BMS compared to either BMF or BF stents (P < 0.05 for both). CONCLUSION: This study demonstrates that compared to BMS, BF stents significantly decreased neointimal hyperplasia.

Inhibition of neointimal hyperplasia after stent placement with rhenium 188-filled balloon dilation in a canine iliac artery model.

PURPOSE: To evaluate the efficacy of beta-irradiation therapy with rhenium 188 ((188)Re) mercaptoacetyltriglycine (MAG3)-filled balloon dilation to prevent neointimal hyperplasia after stent placement in a canine iliac artery model. MATERIALS AND METHODS: A total of 15 stents were implanted into the iliac arteries of eight dogs (one or two stents in each dog). Rhenium 188 MAG3-filled balloon dilation was performed immediately after placement of 10 bare stents-20 Gy in group II (n = 5) and 40 Gy in group III (n = 5)-and conventional balloon dilation was performed immediately after placement of the remaining five bare stents (group I). A follow-up angiogram was obtained 8 weeks after the procedure, and percentage of luminal stenosis was calculated for the proximal and distal ends of each stent. Neointimal thickening (expressed as the neointimal area divided by the sum of neointimal area and media area) was assessed for microscopic examination. RESULTS: All eight dogs survived until they were euthanized 8 weeks after the procedures. The mean luminal stenosis measurements at 8-week follow-up angiography in groups I, II, and III were 26.63%, -0.44%, and 10.53%, respectively. The mean neointimal thickening measurements in groups I, II, and III were 0.77, 0.21, and 0.34, respectively. The mean percentage of luminal stenosis and neointimal thickening differed significantly among the three groups (P < .05). CONCLUSIONS: beta-Irradiation with (188)Re-MAG3-filled balloon dilation has the potential to reduce neointimal hyperplasia secondary to stent placement in a canine iliac artery model. A dose of 20 Gy may be preferable versus a dose of 40 Gy to reduce neointimal hyperplasia.

Preliminary investigation of computed tomography-guided iodine-125 seed implantation treatment efficacy in patients with iliac lymph nodes metastases.

OBJECTIVES: The objective of this study is to assess the technical feasibility, safety, and efficacy of computed tomography (CT)-guided iodine-125 (125 I) seed implantation to treat malignant iliac lymph node metastases. MATERIALS AND METHODS: In this retrospective study, 11 patients with a total of 11 iliac lymph node metastases were implanted with 125 I seeds (14.8-25.9 MBq) under CT-guidance, both the seed quantity and distribution were measured with a computerized treatment planning system. Treatment effects and adverse events were evaluated. RESULTS: 125 I seeds were successfully implanted in all patients, and the minimum peripheral dose of seeds was ranged from 30 to 110 Gy (median of 75 Gy). The median follow-up period was 11 months (ranged 3-39 months). Follow-up at 2 months after implantation revealed partial response in eight patients, stable disease in two patients, and progressive disease in one patient. The overall response rate and the local tumor control rate at 2 months were 72.73% and 90.91%, respectively. The rates of refractory pain and leg edema relief were 100% and 50% within 2 weeks after treatment, respectively. Survival rate at 1 year was 45.45%. No peri-interventional mortality or major complication was observed. CONCLUSION: 125 I seed implantation was a safe and effective technique for minimally invasive treatment for iliac lymph node malignant metastasis.

Radiation-induced peripheral artery disease.

Radiation therapy is a cause of cardiovascular morbidity and mortality. This is due to the significant degree of atherosclerosis seen in the vessels in the vicinity of the area being irradiated. Radiation-induced peripheral arterial disease is increasingly being recognized as large populations of cancer patients survive longer, yet it is a problem that is often under reported. Although it has most commonly been associated with carotid artery disease, all vascular beds are prone to this form of injury. The injury is accelerated by usual risk factors for atherosclerosis. Developing a healthy lifestyle, dietary prudence and the aggressive treatment of hypertension, diabetes mellitus, and dyslipidemia should all be encouraged in this patient population. When revascularization strategies are warranted, the percutaneous approach may be superior to open surgery as technical difficulties may arise in the fibrotic, scarred tissue. Stenting with distal embolic protection devices should be considered as the treatment of choice for patients with radiation-induced carotid artery disease. Several reports also suggest good results with balloon angioplasty with or without stenting in the case of radiation-induced renal, iliac, and femoral artery disease. Lifelong antiplatelet therapy may be appropriate.

Late arterial responses (6 and 12 months) after (32)P beta-emitting stent placement: sustained intimal suppression with incomplete healing.

BACKGROUND: Three-month studies of stent-delivered brachytherapy in the rabbit model show reduced neointimal growth. However, intimal healing is delayed, raising the possibility that intimal inhibition is merely delayed rather than prevented. The purpose of this study was to explore the long-term histological changes after placement of beta-emitting radioactive stents in normal rabbit iliac arteries. METHODS AND RESULTS: Three-millimeter beta-emitting (32)P stents (6, 24, and 48 microCi) were placed in normal rabbit iliac arteries with nonradioactive stents as controls. Animals were euthanatized at 6 and 12 months, and histological assessment, morphometry, and analysis of endothelialization were performed. Morphometric measurements demonstrated a >50% reduction in intimal growth and percent lumen stenosis within 24- and 48-microCi stents versus control nonradioactive stents at both 6 and 12 months. However, the 24- and 48-microCi stents also showed delayed healing of the intimal surface, characterized by persistent fibrin thrombus with nonconfluent areas of matrix, incomplete endothelialization, and increased intimal cellular proliferation. Stent edge stenosis was present at 12 months in the 24- and 48-microCi stent groups, characterized by both intimal thickening and negative arterial remodeling. CONCLUSIONS: Inhibition of intimal growth is maintained 6 and 12 months after (32)P beta-emitting stent placement. However, delayed arterial healing, incomplete endothelialization, and edge effects are present.

Failure of a novel balloon-expandable gamma-emitting ((103)Pd) stent to prevent edge effects.

BACKGROUND: Balloon-expandable beta-particle-emitting ((32)P) stents inhibit within-stent neointimal hyperplasia but induce lumen narrowing beyond the stent margins, ie, the so-called "edge effects." METHODS AND RESULTS: We prospectively investigated the performance of novel stents impregnated with the gamma-emitting isotope (103)Pd, designed to reduce edge effects, in 24 rabbits. The stents had a length of 18 mm and were mounted on 20-mm-long delivery balloons for deployment. Angiograms were obtained immediately and 1 month after direct implantation of control and 1-, 2-, and 4-mCi (103)Pd stents into the iliac arteries without predilatation or postdilatation. Late lumen loss was measured with quantitative angiography. Neointimal hyperplasia and vascular remodeling were evaluated by histomorphometry. Late lumen loss was inhibited within (103)Pd stents (control 0.18 mm, 1 mCi 0.08 mm, 2 mCi 0.05 mm, and 4 mCi -0.03 mm, P<0.05 all activities versus control). Conversely, late lumen loss occurred at the edges of (103)Pd stents, correlating with areas of high balloon/artery ratios and vessel overstretch injury. Edge effects were primarily due to neointimal hyperplasia but were also caused by negative vessel remodeling at high stent activities. CONCLUSIONS: Edge effects after implantation of radioisotope stents can occur independently of the isotope chosen for stent impregnation.

Effect of short pulsed nonablative infrared laser irradiation on vascular cells in vitro and neointimal hyperplasia in a rabbit balloon injury model.

BACKGROUND: Neointimal hyperplasia after PTCA is an important component of restenosis. METHODS AND RESULTS: Cultures of rabbit endothelial cells and smooth muscle cells (SMCs) were irradiated with different doses of nonablative infrared (1064-nm) radiation. Normalized viability index detected with nondestructive Alamar Blue assay and direct cell count were studied. Our experiments demonstrated dose-dependent cytostatic or cytotoxic effects of laser irradiation. We also evaluated the long-term effect of endoluminal nonablative infrared laser irradiation on neointimal hyperplasia in a rabbit balloon injury model. PTCA of both iliac arteries of 23 New Zealand White rabbits was performed. One iliac artery was subjected to intra-arterial subablative infrared irradiation via a diffuse tip fiber. The contralateral vessel served as control. The diet was supplemented with 0.25% cholesterol and 2% peanut oil for 10 days before and 60 days after PTCA. Morphometry after 60 days showed that intimal areas were 0.76+/-0.18 and 1.85+/-0.30 mm(2) in the laser and control arteries, respectively (P=2.2x10(-11)). CONCLUSIONS: We conclude that nonablative infrared laser inhibited neointimal hyperplasia after PTCA in cholesterol-fed rabbits for up to 60 days.

Mobilized endothelial progenitor cells by granulocyte-macrophage colony-stimulating factor accelerate reendothelialization and reduce vascular inflammation after intravascular radiation.

BACKGROUND: Endothelial progenitor cells (EPCs) play a pivotal role in repair and regeneration of damaged vessels. We investigated the role of mobilized EPCs in the healing process after intravascular radiation therapy. METHODS AND RESULTS: One iliac artery of hypercholesterolemic rabbits was subjected to balloon injury and intravascular radiation with a Re-188 balloon and the contralateral iliac artery to balloon injury only. Rabbits received granulocyte-macrophage colony-stimulating factor (recombinant human GM-CSF) (60 microg/d subcutaneously) daily for 1 week, either 7 days before the angioplasty or at the time of angioplasty. Control rabbits received human albumin. GM-CSF significantly increased the double-positive (CD31+ and KDR+) fraction in peripheral blood monocytes and showed a higher number of EPCs than albumin after culture and, furthermore, enhanced migration and incorporation of EPCs. In the albumin group, intravascular radiation therapy reduced neointimal hyperplasia but delayed reendothelialization and aggravated monocyte infiltration. GM-CSF treatment significantly accelerated the reendothelialization and inhibited monocyte infiltration (reendothelialization index, 81+/-13% in the GM-CSF radiation [n=7] versus 30+/-11% in the control radiation [n=9] at 2 weeks, P<0.01). GM-CSF treatment produced an additional significant reduction in neointimal formation at 14 and 28 days after injury in the intravascular radiation groups (intima to media ratio, 0.14+/-0.11 in the GM-CSF radiation [n=5] versus 0.36+/-0.07 in the control radiation [n=5] at 4 weeks, P<0.01). CONCLUSIONS: GM-CSF treatment mobilizes EPCs, accelerates reendothelialization, and reduces monocytes infiltration after intravascular radiation therapy, suggesting that stem cell mobilization is a promising strategy for enhancing the vascular healing process after cytotoxic angioplasty.

External beam radiation after stent implantation increases neointimal hyperplasia by augmenting smooth muscle cell proliferation and extracellular matrix accumulation.

OBJECTIVES: We sought to examine the effects of high volume external beam radiation (EBR) after stent implantation on neointimal hyperplasia, smooth muscle cell (SMC) proliferation, presence of inflammatory cells and expression of extracellular matrix (ECM). BACKGROUND: Endovascular irradiation has been shown to reduce restenosis rates after angioplasty in preliminary trials, but conflicting results have been reported for the effects of external beam irradiation. METHODS: Forty-three Palmaz-Schatz stents were implanted into iliac arteries of New Zealand White rabbits. The arteries were externally irradiated after stent implantation with a single dose of 8 Gy (at day 3) or 16 Gy in two fractions (8 Gy at days 3 and 4) by means of a linear accelerator. In the control rabbits, no radiation was applied after stent implantation. Smooth muscle cells, macrophages and ECM were studied by immunohistochemistry at one and 12 weeks after stent implantation. Collagen type I and biglycan messenger ribonucleic acid (mRNA) levels were assessed by Northern blot analysis at one week. Neointimal cell densities and arterial lumen stenosis were measured by histomorphometry at 12 weeks. RESULTS: At 1 week, SMC proliferation at the site of stent implantation was increased after EBR with 8 and 16 Gy (26 +/- 5%, 32 +/- 3% vs. 17 +/- 8%; p < 0.01, 16 Gy vs. control). External beam radiation with 8 and 16 Gy augmented SMC proliferation proximal and distal to the angioplasty site (11 +/- 3%, 14 +/- 3 vs. 6 +/- 1%; p < 0.01, 16 Gy vs. control). Collagen type I and biglycan mRNA levels were elevated in stented arteries after EBR with 16 Gy. At 12 weeks, a marked decrease in neointimal cell density (248 +/- 97 vs. 498 +/- 117 SMCs/0.1 mm2 neointima; p < 0.005 vs. control) was noted after EBR with 16 Gy. Irradiation with 8 and 16 Gy increased arterial lumen stenosis compared with nonirradiated control rabbits (45 +/- 7%, 55 +/- 9% vs. 33 +/- 7%; p < 0.05, 8 Gy and p < 0.001, 16 Gy vs. control). CONCLUSIONS: High volume external beam radiation at doses of 8 or 16 Gy causes restenosis by augmenting proliferative activity at and adjacent to the site of stent implantation, and by dose-dependent up-regulation of extracellular matrix expression. The study suggests that excessive matrix accumulation is an important determinant of failure of radiation therapy to prevent restenosis.

Neointimal responses 3 months after (32)P beta-emitting stent placement.

PURPOSE: Studies have shown a potential benefit of brachytherapy in preventing restenosis. However, the effects of intravascular radiation on arterial healing have not been well-established. The purpose of this study was to explore the histologic changes following placement of beta-emitting radioactive stents in arteries focusing on intimal responses and endothelialization. METHODS AND MATERIALS: 3.0-mm beta-emitting (32)P stents (6-microCi and 24-microCi) were placed in rabbit iliac arteries with nonradioactive stents serving as controls. Animals were euthanized at 3 months and histologic assessment, morphometry, and analysis of endothelialization were performed. RESULTS: The lumen areas of 24-microCi stents (4.24 +/- 0.22 mm(2), p < 0.0007) and 6-microCi stents (4.23 +/- 0.49 mm(2), p < 0.01) were larger than control stents (3.64 +/- 0.44 mm(2)). The mean lumen percent stenosis was 11. 4 +/- 3.0% in the 24-microCi stents (p < 0.007 vs. 6-microCi stents and p < 0.0001 vs. control stents), 18.7 +/- 6.4% in the 6-microCi stents (p < 0.02 vs. control stents), and 25.0 +/- 4.9% in control stents. Neointimal area was least in the 24-microCi stent (54.2% smaller than controls and 42.7% smaller than 6-microCi); the neointimal area of the 6-microCi stents was 20.0% less than controls. The control stent neointima consisted of smooth muscle cells in a proteoglycan and collagen matrix. In contrast, the intima of radioactive stents showed persistent fibrin thrombus with nonconfluent areas of matrix. Actin-positive intimal cell density was reduced with radioactive stenting, but intimal cell proliferation was increased. Evans blue staining, an indicator of increased endothelial permeability, was present on 86 +/- 9% of the stented segment of 6-microCi stents vs. 10 +/- 11% in controls (p < 0.0001). Scanning electron microscopy demonstrated endothelialization of 97 +/- 8% of the intimal surface of control stents; in contrast, the midportion of the 6-microCi stents remained nonendothelialized, and only 33 +/- 15% (p < 0.0001) of the entire stent surface was endothelialized. CONCLUSIONS: (32)P beta-emitting stents reduce neointimal growth, but healing is incomplete with poor endothelialization at 3 months. Longer-term studies with complete arterial healing are needed to determine whether there is sustained neointimal inhibition by stent-delivered brachytherapy.

Experimental results with endovascular irradiation via a radioactive stent.

PURPOSE: The objective of this article is to describe the methods used to manufacture a radioactive stent and to review the experimental data on this therapy designed to improve arterial patency rates after stent placement. MATERIALS AND METHODS: Surface activation in a cyclotron and ion implantation techniques are used to render commercially available vascular stents radioactive. beta-Particle-emitting stents, most commonly 32P, were employed because of their short half-life (14.3 days) and limited range of tissue penetration (3-4 mm). The function and vascular response to these 32P radioactive stents with varying activities (range 0.14-23 microCi) was evaluated in several animal models of arterial injury and restenosis. RESULTS: In porcine iliac arteries, beta-particle-emitting stents with an initial activity of 0.14 microCi reduced neointimal formation 37% at 28 days after implant. On histology, the neointima consisted of smooth muscle cells and a proteoglycan-rich matrix. Scanning electron microscopy demonstrated complete endothelialization of the stent. beta-Particle-emitting stents with an initial activity of 3-23 microCi inhibited neointimal smooth muscle cell proliferation at 28 days in a porcine coronary restenosis model. The neointima within these high-activity stents consisted of fibrin, erythrocytes, and only rare smooth muscle cells. Studies with 1-year follow-up after implantation of a radioactive stent with a composition of gamma- and beta-particle-emitting radionuclides 55,56,57Co, 52Mg, and 55Fe and an initial activity of 17.5 microCi demonstrated almost complete inhibition of neointimal proliferation in a rabbit model. CONCLUSION: Endovascular irradiation delivered via a radioactive stent reduces neointimal formation and improves luminal patency without increasing the risk for stent thrombosis in experimental models of restenosis. The optimal radiation dose is unknown. At stent activities >3 microCi of 32P, the inhibition of neointimal formation is due to direct radiation affects on proliferating smooth muscle cells. At ultra-low activities (0.14 microCi), beta-particle irradiation reduces neointimal formation possibly by impairing cell proliferation or migration. This novel therapy may have a significant impact on preventing stent restenosis, and requires further investigation.

Late effects of low-energy gamma-emitting stents in a rabbit iliac artery model.

PURPOSE: To determine the long-term dose response of novel low-dose gamma-emitting stents in a rabbit iliac artery model. METHODS AND MATERIALS: Control stents (n=24) and 103Pd stents 1.0 to 4.0 mCi (n=36) were implanted in the iliac arteries of 30 New Zealand rabbits. Stents were evaluated by intravascular ultrasound (immediately post procedure and before killing) and by histomorphometry. RESULTS: At 26 weeks, 28 rabbits were killed, with no evidence of stent thrombosis. In the body of the stent there was a dose-response relationship with 50% inhibition of intimal hyperplasia at the highest activity compared to control stents (p=0.07) and a significant increase in intimal hyperplasia at the lowest activity (p < 0.01). At the stent edges, there was a significant reduction of lumen area at all activity levels compared to control stents, which was most prominent at the proximal stent edge. Higher-activity stents demonstrated incomplete endothelialization and immature neointimal formation. CONCLUSIONS: Continuous low-dose-rate irradiation by gamma-emitting 103Pd stents is feasible with reduction of in-stent hyperplasia in a dose-related manner. However, significant narrowing at the stent edges, increased in-stent hyperplasia at lower activities, and incomplete vascular healing with persistence of immature neointima at higher activities are significant limitations.

Feasibility of external beam radiation for prevention of restenosis following balloon angioplasty.

PURPOSE: Brachytherapy has been shown to inhibit neointima formation after vascular balloon injury. This study was done to test the feasibility of low dose external radiation for prevention of restenosis in a non-stented balloon injury model. MATERIALS AND METHODS: Twelve red Duroc swine underwent balloon overdilation injury of both iliac arteries. Twelve Gy was delivered to one side using a Theratron T-1000 Cobalt unit with the other side used as the control. Twelve weeks post injury arteriograms were performed. The animals were then sacrificed and iliac arteries explanted. Histomorphometric analysis of arterial cross sections was performed. RESULTS: Neointima formation was observed in all arteries. Unilateral thrombosis was noted in two animals. The mean neointimal thickness in the radiated and control arteries was 0.63 +/- 0.17 mm and 0.72 +/- 0.31 mm, respectively. The differences in minimal luminal diameter and the neointimal thickness between the two groups were not statistically significant. Complications included superficial hair loss in the radiation port in 4 animals, and 2 deaths prior to the completion date (1 of hemorrhagic enteritis possibly related to the radiation, and 1 of iliac rupture). CONCLUSION: External radiation at this low dose is not effective in preventing vascular restenosis following balloon injury in this animal model.

Radiation-induced arterial injuries.

In a 20-year period from 1961 to 1981 at the University of Kentucky Medical Center, there were 20 patients with vascular lesions directly attributable to irradiation. Two distinct patterns of arterial injury attributable to radiotherapy were identified--arterial disruption and occlusion. Arterial disruption occurred in 12 patients--11 carotid blowouts and 1 iliac artery rupture. Two patients underwent prophylactic carotid artery ligation for impending rupture. In the 11 carotid artery ruptures, ligation of the artery in nine patients resulted in stroke or death in five patients. Iliac artery disruption necessitated ligation, which eventually led to severe ischemia requiring hip disarticulation. Unusual arterial stenosis or occlusion occurred in six patients 7 to 24 years after irradiation. Three patients had severe stenosis or occlusion of the common, internal, or external carotid arteries leading to cerebrovascular insufficiency. Three other patients with focal stenosis of the iliofemoral region were successfully treated with bypass grafting.

External beam irradiation inhibits neointimal hyperplasia following balloon angioplasty.

Restenosis is a serious problem limiting the long-term efficacy of percutaneous transluminal coronary angioplasty. Neointimal smooth muscle proliferation is the major process underlying restenosis. The objective of this study was to investigate the effects of external irradiation on neointimal hyperplasia following balloon angioplasty. We examined the ability of external X-ray irradiation to inhibit intimal hyperplasia following balloon angioplasty in a non-atherosclerotic rabbit model. Baseline quantitative angiography (day 0) was performed in all rabbits and balloon angioplasty was performed in the right (control) and the left iliac arteries. Five days after balloon angioplasty, the left iliac in each rabbit was irradiated with either 600 cGy (n = 5) or 1200 cGy (n = 5). Twenty-eight days following angioplasty final angiography was performed. All rabbits were sacrificed, and the iliac arteries were fixed for morphometric measurements. Comparison of baseline and final angiographic measurements revealed a significant decrease in average and minimum lumen dimensions for both control and irradiated segments (600 and 1200 cGy) [average: P (baseline vs. final) 0.008 (control), 0.001 (600 cGy); 0.05 (control), 0.007 (1200 cGy)]. Morphometric analysis showed no difference in neointimal cross-sectional area between control (0.29 +/- 0.05 mm2) and 600 cGy irradiated segments (0.32 +/- 0.07 mm2) (P = 0.82). However, there was a statistically significant reduction in neointimal hyperplasia in the 1200 cGy irradiated segments (0.09 +/- 0.02 mm2) compared to control (0.23 +/- 0.06 mm2, P = 0.02). There was no significant difference in medial cross-sectional area between control and irradiated segments (600 and 1200 cGy). We conclude that in this model, external beam X-ray irradiation (1200 cGy) was successful in reducing neointimal proliferation after balloon angioplasty. Whether or not this approach can be used successfully to inhibit restenosis in the clinical setting requires further investigation.

Eccentric iliac artery stenosis: a canine model for angioplasty.

A canine model was developed to induce eccentric iliac artery stenosis. Lesions were induced by exposing the medial aspect of the right and left common iliac arteries in four animals to direct argon laser energy (LA). A 2.5-mm diameter side-firing laser probe was used to deliver 10 W of power in 5-s intervals. Twenty-five pulses were delivered over a 5-cm length of artery with an approximate spot size of 0.8 mm2. Selected arteries (n = 2, LA + Ca) were injected in the same laser injury site with calcium chloride (10% solution). Injections were accurately accomplished using an angioscopically guided guidewire/needle device. In all cases, the internal elastic lamina was broken with focal disruptions of the media. At 9 and 14 days, the LA (n = 3) and LA + Ca vessels (n = 1) had minimal stenoses (< 5% area reduction). These vessels contained edematous media with replacement of necrotic smooth muscle by fibrous tissue. At 23 days, the LA (n = 1) and LA + Ca (n = 1) vessels contained 22% and 33% luminal reductions, respectively, with moderate neointimal proliferation and no evidence of calcification. At 56 days the LA vessels (n = 2) contained 30 and 42% luminal area stenoses with marked neointimal hyperplasia. This preliminary data suggests that controlled arterial wall injury with LA irradiation can induce eccentric fibrointimal lesions in a canine model.

Surgical treatment of radiation induced atherosclerotic disease of the iliac and femoral arteries.

Ten patients with radiation induced atherosclerosis of the iliac and femoral arteries are described. Therapeutic irradiation in normal doses can induce and aggravate atherosclerosis of large arteries. The lesions are sharply defined within the field of radiation. Irradiation influences the permeability and cellular processes of the vessel wall which leads to development of the atheromatous plaque. Vascular surgery is possible with no mortality and with low morbidity. Because of peri-arterial involvement of tissues and commonly poor skin condition extra-anatomical bypass should be preferred as a primary procedure.

An experimental study of endovascular brachytherapy using liquid 32P filled balloon catheter.

OBJECTIVE: To observe the effect of endovascular brachytherapy on the prevention of restenosis after interveneional therapy and to investigate its possible mechanisms. METHODS: In the balloon-injuried rabbit model, pathological sections of iliac arteries were observed and the changes of vascular histomorphology were estimated by computer analysis of photomicrograms. Using immunohistochemical techniques, proliferating cell nuclear antigen (PCNA) was quantified to assess the proliferation of vascular smooth muscle cells. RESULTS: After rabbit iliac arteries were injured by balloon overstretch angioplasty, neointima were shown to be less proliferative in the irradiated group than in the control group, from PCNA scores. The formation of neointima was suppressed with the external elastic laminar area increasing and without the luminal area decreasing in the irradiation group. CONCLUSION: Endovascular brachytherapy using a liquid 32P filled balloon catheter system could prevent restenosis possibly by inhibiting the formation of neointima and improving positive vascular remodeling.

Adventitial response to intravascular brachytherapy in a rabbit model of restenosis.

BACKGROUND: The incidence of late major adverse cardiac events (MACE) after coronary brachytherapy is higher than in controls. Because expansive remodeling has been shown to correlate with poor clinical outcome after vascular interventions, we studied adventitial changes after intravascular irradiation in a rabbit model. METHODS: Twenty normolipidemic rabbits underwent balloon injury in both external iliac arteries. One artery was assigned for subsequent irradiation with a 90Y source (15 Gy or 30 Gy at 0.5 mm in the vessel wall). After four weeks morphometric measurements were made and cell density and collagen amount determined. Staining for Ki67 identified proliferating cells; apoptotic cells were identified by TUNEL staining. Proliferative and apoptotic indices were calculated as the number of respective positive cells/total cell count x100. RESULTS: The neointimal area decreased to 0.27 +/- 0.3 mm2 after irradiation compared with 0.55 +/- 0.2 mm2 in controls (p=0.007), whereas adventitial area increased from 0.62 +/- 0.3 mm2 to 0.87 +/- 0.3 mm2 (p=0.02). Irradiation reduced both the proliferative (0.95 +/- 2.6 vs. 3.73 +/- 4.7, p=0.026) and apoptotic (0.006 +/- 0.02 vs. 0.107 +/- 0.2, p=0.03) indices in the neointima, but not in the other arterial-wall layers. Collagen amount and arterial remodeling did not differ between the groups. There was no difference between 15 and 30 Gy in any of the parameters, although adventitial thickening was more pronounced in the high-dose group. CONCLUSIONS: In normolipidemic rabbits, intravascular beta-irradiation after balloon angioplasty is associated with an increase in neoadventitia and a reduction of neointima. It is conceivable that this phenomenon may contribute to the increased incidence of late MACE after vascular brachytherapy.