Effect of hyperlipidemic serum and irradiation on wound healing in primary quiescent cultures of vascular cells

Effect of Hypercholesterolemia on Fatty Infiltration and Quality of Tendon-to-Bone Healing in a Rabbit Model of a Chronic Rotator Cuff Tear: Electrophysiological, Biomechanical, and Histological Analyses

BACKGROUND

The incidence of healing failure after rotator cuff repair is high, and fatty infiltration is a crucial factor in healing failure.

PURPOSE

To verify the effect of hypercholesterolemia on fatty infiltration and the quality of tendon-to-bone healing and its reversibility by lowering the cholesterol level in a chronic tear model using the rabbit supraspinatus.

STUDY DESIGN

Controlled laboratory study.

METHODS

Forty-eight rabbits were randomly allocated into 4 groups (n = 12 each). After 4 weeks of a high-cholesterol diet (groups A and B) and a regular diet (groups C and D), the supraspinatus tendon was detached and left alone for 6 weeks and then was repaired in a transosseous manner (groups A, B, and C). Group D served as a control. Group A continued to receive the high-cholesterol diet until the final evaluation (6 weeks after repair); however, at the time of repair, group B was changed to a general diet with administration of a cholesterol-lowering agent (simvastatin). Histological evaluation of the fat-to-muscle proportion was performed twice, at the time of repair and the final evaluation, and an electromyographic (EMG) test, mechanical test, and histological test of tendon-to-bone healing were performed at the final evaluation.

RESULTS

For the EMG test, group A showed a significantly smaller area of compound muscle action potential compared with groups C and D (all P <.01), and group B showed a larger area than group A, almost up to the level of group C (P = .312). Similarly, group A showed significantly lower mechanical properties both in load-to-failure and stiffness compared with groups C and D (all P <.05). In addition, although not significantly different, the mechanical properties of group B were higher than those of group A (mean load-to-failure: group A = 42.01 N, group B = 58.23 N [P = .103]; mean stiffness: group A = 36.32 N/mm, group B = 47.22 N/mm [P = .153]). For the histological test, groups A and B showed a significantly higher fat-to-muscle proportion than did groups C and D at 6 weeks after detachment (all P <.05), but at the final evaluation, group B showed a decreased fat-to-muscle proportion (mean ± SD: from 64.02% ± 11.87% to 54.68% ± 10.47%; P = .146) compared with group A, which showed increased fat-to-muscle proportion (from 59.26% ± 17.80% to 78.23% ± 10.87%; P = .015). Groups B and C showed better tendon-to-bone interface structures than did group A, which showed coarse and poorly organized collagen fibers with fat interposition.

CONCLUSION

Hypercholesterolemia had a deleterious effect on fatty infiltration and the quality of tendon-to-bone repair site, and lowering hypercholesterolemia seemed to halt or reverse these harmful effects in this experimental model.

CLINICAL RELEVANCE

Systemic diseases such as hypercholesterolemia should be tightly controlled during the perioperative period of rotator cuff repair.

Inhibitory effect of brachytherapy on intimal hyperplasia in arteriovenous fistula1

PURPOSE

To determine whether endovascular radiation can inhibit intimal hyperplasia in a swine model of hemodialysis access.

MATERIALS AND METHODS

Polytetrafluoroethylene arteriovenous grafts (6 mm in diameter) were placed between the common carotid artery and the external jugular vein bilaterally in 8 pigs. Two days after the surgery, fistulography was performed. Gamma radiation (12 Gy) was delivered endovascularly to one of the grafts at the venous anastomosis by using an iridium(192) source. Thus, the other graft in each pig served as an untreated control. Fistulas were evaluated with fistulography or venography 6 week after radiation. All grafts were then harvested for histological and immunohistochemical examination.

RESULTS

Seven grafts on the treated side and 5 grafts on the control side remained patent for at least 6 weeks. Angiography demonstrated that the percentage stenosis at the venous anastomosis was significantly lower for the treated group (15.9 +/- 14.1 versus 32.6 +/- 16.7%, P = 0.045). Histopathologic analyses revealed that the mean intimal area and maximal intimal thickness were significantly lower with reduced smooth muscle cell proliferation at the venous anastomosis on the treated side compared to the control side (0.68 +/- 0.30 versus 1.06 +/- 0.29 mm(2), P = 0.017, and 0.18 +/- 0.08 versus 0.26 +/- 0.07 mm, P = 0.004, respectively). The residual lumen was significantly greater for the treated group (1.59 +/- 0.42 versus 1.06 +/- 0.37 mm(2), P = 0.031). No significant differences were found in the area, nor maximal thickness in the vein either proximal or distal to the anastomosis between the two groups.

CONCLUSIONS

In an animal model of hemodialysis access, brachytherapy with iridium(192) delivered 2 days after graft implantation reduces intimal hyperplasia and stenosis at the venous anastomosis. The reduced smooth-muscle cells found in the radiated veins suggests that brachytherapy may exert its effect on neointimal formation by inhibition of smooth muscle cell proliferation.

Rationale for coronary artery radiation therapy

Within the past decade, focus on radiation to prevent restenosis has moved from a concept developed in the animal laboratory to a clinical treatment. The initial evaluation of coronary artery radiation therapy focused on changes in the function of the artery or lesion formation following overstretch balloon injury in pigs. A number of concepts emerged from this work: (1) radiation inhibits neointima formation in a dose-dependent fashion, (2) radiation prevents negative remodeling, (3) radiation does not reverse established injury, (4) low dose irradiation in an injured area may be injurious, (5) radiation is a useful adjunct to stenting, (6) benefits of radiation in animal models at 6 months are less pronounced than at 1 month, (7) radiation delays healing, (8) permanent stents and radiation delivered from external sources may have very different effects on restenosis, and (9) radiation interferes with vessel wall function. More recent studies of irradiation have looked at the molecular biological effects of radiation in hopes of understanding how this therapy works, and how it may be improved. This article attempts to summarize the known animal and cellular work on radiation in preventing restenosis.

The restenosis story: is intracoronary radiation therapy the solution?

Restenosis remains a major limitation of percutaneous transluminal coronary intervention. Stenting made an important contribution in restenosis reduction, but in-stent restenosis is becoming a growing problem. Although radiation therapy was traditionally used to kill relatively fast-growing tumor cells, it has also been used to clinically treat benign but problematic hyperplastic conditions. In addition, in vitro studies have shown that radiation inhibits serum-stimulated growth of arterial smooth muscle cells and fibroblasts, and decreases collagen synthesis by fibroblasts. The effects of radiation on neointimal inhibition after vascular injury were investigated in animal models using various catheter- and stent-based endovascular approaches (brachytherapy) as well as externally delivered x-irradiation. These studies have consistently shown that ionizing radiation delivered by the endoluminal approach results in remarkable suppression of neointima formation. However, animal studies also demonstrate altered vessel wall healing with increased thrombogenicity. The catheter-based approach with gamma- or beta-emitters showed feasibility and appears promising in early human clinical trials, whereas the strategy of using radiation stents is more problematic in the clinical arena. A number of randomized multicenter trials have been initiated and the results are eagerly awaited. More work needs to be done to define the optimal dosage, and to study the short- and long-term vascular biologic effects of brachytherapy. Additionally, if this form of therapy proves efficacious in the large, randomized, clinical trials, its cost-effectiveness will then need to be established. This review touches on some of the basic concepts involved in using the strategy of endovascular irradiation therapy for restenosis prevention after percutaneous coronary intervention and reviews the evidence of clinical efficacy and safety.

Effect of transcatheter endovascular radiation with holmium-166 on neointimal formation after balloon injury in porcine coronary artery

BACKGROUND

Neointimal formation in response to arterial injury is a major contributing element in restenosis after coronary balloon angioplasty and stenting. Endovascular irradiation has been reported to be effective in reducing restenosis. The purpose of this study was to investigate the effect of beta-emitting holmium-166 for the inhibition of neointimal formation in porcine coronary artery.

METHODS AND RESULTS

A total of 34 pigs weighing 25 to 30 kg underwent oversized balloon injury (balloon/artery ratio, 1.3:1.4) at the proximal portion of the left anterior descending and circumflex arteries. One artery was randomly assigned to receive radiation after injury. Ho-166 was left in the balloon within the delivery catheter for a period sufficient to deliver 9 Gy and 18 Gy to a depth of 1 mm from the surface of the balloon. Four weeks later, pigs were sacrificed and hearts were perfusion-fixed, followed by histopathologic analysis and planimetry for measurement of maximal intimal thickness, intimal area, and fracture length. The coronary segment of the pigs in the control group had neointimal area of 1.18+/-0.55 mm2; the pigs in the 9-Gy group had neointimal area of 0.68+/-0.40 mm2 (P<.05 vs. control); and the pigs in the 18-Gy group had neointimal area of 0.29+/-0.12 mm2 (P<.01 vs. control). The maximal intimal thickness in the 18-Gy group (0.14+/-0.11 mm) was significantly reduced compared with the maximal intimal thickness in the control group (0.48+/-0.13 mm) (P<.01).

CONCLUSIONS

Intracoronary radiation with liquid Ho-166 contained in a perfusion balloon catheter is feasible and effective in reducing neointimal formation after coronary overstretch injury in pigs. Therefore intracoronary irradiation on the injured segment may further reduce restenosis after balloon injury.

Irradiation and postangioplasty restenosis: a recent overview

One of the most intriguing developments in recent years towards prevention of restenosis after angioplasty is the use of ionizing radiation. The background for the use of radiation treatment for this application is sound, since radiation is used not only to treat malignant cancerous growths but also is used for treatment of benign hyperplastic disorders such as post-surgical keloid formation and recurrence of pterygium after surgical removal. Restenosis can be considered a form of overexuberant wound healing triggered by angioplasty. Ionizing radiation inhibits serum-stimulated proliferation of many cell types including fibroblasts and smooth muscle cells in vitro and also suppresses the synthesis of collagen by cultured fibroblasts. Liermann who showed inhibition of post-stent restenosis first used ionizing radiation for restenosis prevention clinically in iliac and iliofemoral arteries. Subsequently, extensive animal studies in various restenosis models have shown a profound inhibitory effect of catheter-based radiation (endovascular brachytherapy) on neointima formation and overall vessel shrinkage (negative remodeling). Based on these results clinical trials have been initiated with several types of devices and isotopes. Among these are 192Ir, 32P, 90Y, 90Sr/Y and 188Re. Additionally, radioactive stents have been developed; devices for clinical use are made radioactive at the microCi level by surface implantation of 32P ions. Results from early clinical trials are encouraging and brachytherapy appears safe for clinical use and at an appropriate dose, may be highly effective for restenosis prevention.

Inhibition of rat smooth muscle proliferation by radiation after arterial injury: temporal characteristics in vivo and in vitro

Although several studies have suggested that inhibition of arterial narrowing by radiation after angioplasty is dependent on both time and dose, little is known regarding the temporal aspects of this effect and the mechanisms by which radiation affects the response of smooth muscle cells to injury. To determine the time course of inhibition of intimal hyperplasia by radiation, 135 rats were given single-fraction external gamma irradiation (1-10 Gy) to one carotid artery at intervals from 5 days before to 5 days after bilateral carotid artery balloon catheter injury, and intimal cross-sectional area was determined from histological sections at 20 days after injury. There was a prominent time- and dose-dependent inhibition of intimal hyperplasia by radiation when it was administered before or after balloon injury, with the greatest effect noted within 24 h before or after injury. To investigate the effect of radiation on smooth muscle cell growth (by cell counting) and proliferation, cell cycle kinetics (by BrdU incorporation), and cell killing (by clonogenic assay), smooth muscle cell cultures derived from rat aortic explants were seeded in equine plasma to induce quiescence, and radiation (2.5-10 Gy) was administered at various intervals before or after synchronous growth stimulation by 10% whole blood serum. A similar time and dose dependence was noted in growth kinetics, BrdU incorporation and cell killing for smooth muscle cells irradiated in vitro; in each case, the effect was most prominent for radiation administered in temporal proximity to stimulation with whole blood serum. By Western blot analysis, cultured smooth muscle cells showed a rapid time-dependent increase in Cdkn1a (formerly known as p21) protein expression, followed by a delayed increase in Tp53 (formerly known as p53) expression after irradiation. Activation of intracellular caspases, manifest by proteolytic poly(ADP-ribose) polymerase (PARP) cleavage, was not detected in smooth muscle cell cultures after irradiation. These observations suggest that radiation limits intimal hyperplasia in vivo by a transient, reversible process. Although apparent cytotoxic injury occurs in vitro, apoptosis of smooth muscle cells is not apparent. Both inhibition of proliferation of smooth muscle cells and cell cycle delay may contribute to inhibition of intimal hyperplasia in vivo by radiation.

Effects of radiation on cerebral vasculature: a review

Radiation therapy plays a critical role in the treatment of central nervous system neoplasms and cerebral arteriovenous malformations. The deleterious effects of radiation on cerebral arteries may be the primary limitation to these treatment methods, as radiation may cause a variety of cerebrovascular injuries and hemodynamic changes. Radiation-induced changes in the cerebral arterial wall are determined by a number of cellular processes in endothelium and smooth muscle cells that modulate differences in radiosensitivity and phenotypic expression. The histopathological findings in arterial radiation injury include vessel wall thickening, thrombosis, luminal occlusion, and occasional telangiectases. Mechanisms for radiation injury to blood vessels include phenotypic changes in normal vessel wall cells (especially endothelium) manifested by the expression or suppression of specific gene and protein products that affect cell cycle progression or cellular proliferation or demise via cytotoxic injury or apoptosis. This review describes the molecular and cellular events involved in the systemic and cerebral vascular response to radiation and the potential means by which these responses may be influenced to augment the therapeutic effects of radiation while minimizing the untoward consequences.

Radiation therapy to prevent coronary artery restenosis

The problem of restenosis after coronary angioplasty remains a major limiting factor of the procedure. Intracoronary stenting has led to a modest reduction in the frequency of this event. In the early 1990s, the effectiveness of ionizing radiation combined with balloon angioplasty and stenting was first convincingly demonstrated in animal models of restenosis. Small feasibility studies and two randomized trials have, in general, supported the promise of these initial preclinical studies in the prevention of restenosis. Much remains to be learned about the application of radiation for this therapy. This article reviews the current status of preclinical and clinical investigation of this therapy.

[Intravascular irradiation in the combined therapy and prevention of restenosis. Overview]

Despite numerous efforts in catheter technology and procedural approaches the problem of restenosis in interventional cardiology persists. Although the implantation of coronary stents has significantly reduced restenosis rates based on the inhibition of elastic recoil, intimal proliferation as the second major mechanism for postinterventional restenosis could not effectively be suppressed. Intimal proliferation is the response to vessel injury following interventional procedure, e.g. balloon angioplasty. It results in the adhesion of mono- and lymphocytes which themselves trigger the colonisation of myofibroblasts. Intracoronary irradiation seeks to prevent this proliferative process as it destroys or irreversibly alters DNA structures of cells at the site of balloon injury. The antiproliferative effect depends on the irradiation dosis, the timing and the cell cycle phase. Mainly beta- and gamma-radiation is used for intracoronary irradiation. Beta-emitters are characterized by a sharp decline of dose rate within millimeters from the actual source. The exposure to surrounding tissue as well the catheter staff can be kept to a minimum. The high intensity of beta-emitters allow a short treatment period of minutes to gain an effective radiation dose to the target. In contrast, gamma-emitters have a low radial dose distribution resulting in high dosage even centimeters away from the source. These emitters require additional shielding in the catheter laboratory and lead to excessive whole body doses. To achieve a sufficient dose in the target tissue, irradiation times of more than 20 minutes are necessary which prolongs the interventional procedure substantially. At present, catheter based systems or radioactive implantable stents are available to deliver the required dose. Catheter based systems seem more flexible in a number of considerations. On the other hand they require a substantial amount of hardware. Beta-emitting stents are implanted via a conventional stent delivery system with small shielding modifications. However, stents emit an inhomogeneous radiation profile due to the mesh-like structure. In addition, not every lesion can be reached by a stent nor does every lesion require a stent solely to deliver radiation. External irradiation is presently not recommended due to its ineffectiveness and the high rate of side effects. In the experimental setting the porcine model comes closest to the clinical situation in man. Animal experiments have demonstrated the effective reduction of intimal proliferation using beta- and gamma-sources in a wide dose range of 3 to 56 Gy. Although the initial and early results are convincing little is know about the long term results. Only few studies have been and are currently performed in patients. Some of these investigations demonstrate a significant reduction of restenosis rate after 6 months. Again, information on long-term results are lacking. It has to be considered that perivascular fibrosis, which may occur with a delay of 5 to 10 years depending on the dosage, could curtail the initial success. Intracoronary irradiation is a promising method for the prevention of restenosis. The dose finding with respect to the dose effect relation, the determination of the therapeutic window and the timing of irradiation have to be further defined in the clinical setting. Nevertheless, intracoronary irradiation remains high on the priority list in fighting restenosis.

High dose rate intracoronary radiation for inhibition of neointimal formation in the stented and balloon-injured porcine models of restenosis: angiographic, morphometric, and histopathologic analyses

PURPOSE

We examined the effects of intracoronary irradiation delivered at a high dose rate on neointimal hyperplasia after injury induced by two methods: balloon overstretch injury, and stent implantation in a porcine model of coronary restenosis.

METHODS AND MATERIALS

In 34 Hanford miniature swine, a segment of each coronary artery was targeted for injury and treatment. The artery segments were treated with 192Ir at doses of 10 Gy over 4 min (eight animals), 15 Gy over 6 min (nine animals), 25 Gy over 10 min (nine animals) or control (simulation wire only; eight animals). The treated segments were subjected to stent implantation (left anterior descending and right coronary artery) or balloon overstretch (circumflex) injury. Twenty-eight days later, repeat coronary angiography and sacrifice were done. Quantitative coronary angiography, morphometry, and extensive histopathologic analyses were carried out in a blinded fashion.

RESULTS

The change in minimal lumen diameter from postinjury to presacrifice in the stent-injured left anterior descending was -0.79 +/- 0.34 (mean: +/- SD) mm in the control group, compared to -0.43 +/- 0.35 mm in the 15 Gy (p = 0.04) and -0.21 +/- 0.50 mm in the 25 Gy (p = 0.01) groups; and in the balloon-injured circumflex was -0.31 +/- 0.22 mm in the control group compared to -0.03 +/- 0.18 mm in the 10 Gy (p = 0.05) and 0.00 +/- 0.33 in the 15 Gy (p = 0.01) groups. Percent area stenosis in the left anterior descending was 36 +/- 9% in the control group compared to 18 +/- 12% in the 15 Gy (p = 0.003) and 11 +/- 11% in the 25 Gy (p < 0.001) groups; and in the circumflex was 16 +/- 10% in the control groups, compared to 5 +/- 5% in the 15 Gy (p = 0.02) and 2 +/- 2% in the 25 Gy (p = 0.009) groups. Histopathology showed a striking reduction in the amount of neointima in the irradiated arteries compared with control vessels. Other radiation effects were stromal fibrin exudate, thinning of the media, and adventitial fibrosis and leukocyte infiltration in the radiated arterial segments.

CONCLUSIONS

High dose rate intracoronary irradiation with 192Ir effectively inhibits intimal proliferation after stent-induced as well as balloon-overstretch injury. This shorter treatment time (4 to 10 min) may provide a clinically practical approach to the prevention of restenosis after angioplasty.

Local catheter-based intracoronary radiation therapy for restenosis

Intracoronary radiation therapy was shown to be effective in limiting "restenosis-like" phenomena by inhibiting neointima formation after balloon angioplasty in porcine coronary arteries. Using the same treatment doses, both gamma and beta emitters demonstrated similar results, despite differences in isotope characteristics (e.g., penetration, activity, dose rate, and treatment time). In addition, intracoronary radiation delivered via a catheter-based system prior to coronary stenting reduced neointimal hyperplasia in the porcine model and may further reduce restenosis when coupled with stent implantation. Radioactive stents are of value, especially in large vessels, because of their low activity and proximity to the vessel wall. Adventitial labeling and immunostaining have suggested that the mechanisms by which radiation reduces restenosis are (1) inhibition of smooth muscle cell proliferation in the adventitia and (2) favorable effects on vessel remodeling. Technical radiation considerations are also discussed, including isotope selection, treatment dose, homogeneous dosimetry, treatment time, and total body dose to the patient and healthcare personnel. New catheter-based delivery systems for intracoronary use are currently being developed and are described. Preliminary clinical and angiographic studies using endovascular radiation after balloon angioplasty in both stented and nonstented peripheral and coronary arteries indicate favorable long-term results. In response to the growing enthusiasm for this approach, larger populations must be studied to determine whether this new therapy will influence the restenosis rate and clinical events after angioplasty and, in a broader sense, the field of interventional cardiology.

Reduced smooth muscle cell regeneration in Yoshida (YOS) spontaneously hypercholesterolemic rats

Hypercholesterolemia is a predisposing factor for atherosclerosis. We studied the response to damage of vascular smooth muscle cells (SMC) from normocholesterolemic Brown Norway (BN) and from spontaneously hyper-cholesterolemic Yoshida (YOS) rats (16-24 month old). The regrowth rate of SMC from BN and YOS rats after freeze-induced damage was similar in the presence of fetal calf serum and of serum derived from normocholesterolemic rats, while it was reduced in the presence of serum from hypercholesterolemic rats. Freeze-injury of the abdominal aorta was followed by reduced neointima formation in YOS rats, as compared to BN rats, confirming the impaired response of vascular cells from hypercholesterolemic rats to injury. This defect may be due either to lipids or to unknown factors present in the hyperlypidemic serum.

Gamma irradiation inhibits neointimal hyperplasia in rats after arterial injury

BACKGROUND AND PURPOSE

Restenosis complicates a significant proportion of endovascular and open vascular procedures such as carotid endarterectomy. In contrast to the primary atheroma, restenosis is characterized by intimal hyperplasia of vascular smooth muscle cells. We hypothesized that gamma radiation would reduce restenosis by limiting intimal hyperplasia after arterial injury.

METHODS

To demonstrate the effect of gamma radiation on smooth muscle hyperplasia in vivo, a standardized bilateral carotid balloon catheter arterial injury was produced in 37 rats. A single dose of 750, 1500, or 2250 cGy (1cGy = 1 rad) gamma radiation was delivered to the right carotid artery at either 1 or 2 days after injury; the shielded contralateral carotid artery served as matched control. At 21 days after injury, vessels were perfusion-fixed in situ, and cross-sectional area of neointima was determined from axial sections using image analysis.

RESULTS

Marked reductions in neointimal cross-sectional area were demonstrated in vessels subjected to 1500- and 2250-cGy radiation at both 1 and 2 days after injury. A less prominent effect was noted for 750 cGy, reaching statistical significance only at 2 days after injury. By two-way ANOVA, radiation dose (P = .0002), timing of radiation delivery (P = .003), and an interaction between timing and dose (P = .0278) were significantly associated with reduction in neointimal cross-sectional area. At 1500 cGy, delivery of radiation 1 day after injury inhibited neointimal hyperplasia more prominently than the same dose 2 days after injury; a dose-response relation was evident at 1 day.

CONCLUSIONS

Radiation may be an important adjunctive therapy for reducing the incidence of restenosis after angioplasty or endarterectomy.

A standardised method of culturing aortic explants, suitable for the study of factors affecting the phenotypic modulation, migration and proliferation of aortic smooth muscle cells

The study of factors affecting phenotypic change and growth of aortic smooth muscle cells (SMC) typically involves either the isolation of SMC by enzymatic dissociation or observation of outgrowth of cells from primary explants of vascular tissue. Explants provide a system in which the growth of cells can be investigated without dissociating them totally from their normal environment and avoids some of the problems of variability associated with enzymatic digestion. We describe here a standardised method for the preparation of medial explants of arterial tissue using a McIlwain tissue chopper, which is both fast and reproducible. Measurement was made of the percentage of explants showing outgrowth and of the distance migrated by cells at various times after plating explants singly into wells of a 96-well plate. Using this method, by 12 days after explanting, more than 95% of explants from normal rabbit aorta had shown outgrowth, in contrast to only 50% of explants prepared using a scalpel blade. Explants from atherosclerotic rabbit aorta showed a shorter lag phase before outgrowth commenced than explants from normal rabbit aorta of a similar age, but the subsequent rate of growth was the same. In contrast, when explants of normal rabbit aorta were grown in hyperlipidic rabbit serum, the lag phase was the same as for normal serum, but the subsequent rate of growth was greater. Explants from normal rabbit aorta treated with heparin showed an increased lag phase but reduced rate of growth. Treatment with heparinase decreased the lag phase and increased the rate of growth as did elastase.