Introduction of a high-throughput double-stent animal model for the evaluation of biodegradable vascular stents.

Current stent system efficacy for the treatment of coronary artery disease is hampered by in-stent restenosis (ISR) rates of up to 20% in certain high-risk settings and by the risk of stent thrombosis, which is characterized by a high mortality rate. In theory, biodegradable vascular devices exhibit crucial advantages. Most absorbable implant materials are based on poly-L-lactic acid (PLLA) owing to its mechanical properties; however, PLLA might induce an inflammatory reaction in the vessel wall. Evaluation of biodegradable implant efficacy includes a long-term examination of tissue response; therefore, a simple in vivo tool for thorough biocompatibility and biodegradation evaluation would facilitate future stent system development. Rats have been used for the study of in vivo degradation processes, and stent implantation into the abdominal aorta of rats is a proven model for stent evaluation. Here, we report the transformation of the porcine double-stent animal model into the high-throughput rat abdominal aorta model. As genetic manipulation of rats was introduced recently, this novel method presents a powerful tool for future in vivo biodegradable candidate stent biocompatibility and biodegradation characterization in a reliable simple model of coronary ISR.

Blockade of angio-associated migratory cell protein inhibits smooth muscle cell migration and neointima formation in accelerated atherosclerosis.

OBJECTIVES: The aim of this study was to elucidate the role of angio-associated migratory cell protein (AAMP) for the migration of vascular smooth muscle cells (SMCs) and for the development of neointimal hyperplasia after vascular injury. BACKGROUND: Although AAMP has been shown to participate in angiogenesis and cancerogenesis and is predominantly expressed in cells with a migratory phenotype, involvement of AAMP during neointima (NI) formation after arterial injury has not been analyzed previously. METHODS: The AAMP content in SMCs was examined using 2-photon laser-scanning microscopy and subcellular fractioning. Migratory potential of SMCs transiently transfected with AAMP expression vectors, transfected with small interfering ribonucleic acid (siRNA), or treated with antirecombinant angio-associated migratory cell protein-antibody (anti-rAAMP-ab) was examined using transwell migration chamber assays. Expression of AAMP was determined in the atherogenic apolipoprotein E knockout (apoE(-/-)) mouse model and in the porcine coronary restenosis model by immunohistochemistry and by Western blot. ApoE(-/-) mice were treated intraperitoneally with anti-rAAMP-ab, and wire-injured carotid arteries were examined. RESULTS: Angio-associated migratory cell protein is localized in the membrane of SMCs, and its expression is enhanced in NI-derived SMCs. The AAMP overexpression increases, while both treatment with anti-rAAMP-ab and transfection with siRNA decreases SMC migration. Knockdown of AAMP decreases RhoA activity in the membrane fraction of SMCs. The AAMP expression by SMCs is enhanced in both animal models. Anti-rAAMP-ab reduces neointimal SMC density at 1 week and NI formation at 4 weeks in apoE(-/-) mice without affecting proliferation of SMCs. CONCLUSIONS: These data reveal an important functional role of AAMP in the migration of SMCs, identifying AAMP as a potential target to limit lesion formation after injury.

A novel drug-eluting stent coated with an integrin-binding cyclic Arg-Gly-Asp peptide inhibits neointimal hyperplasia by recruiting endothelial progenitor cells.

OBJECTIVES: Novel stents loaded with an integrin-binding cyclic Arg-Gly-Asp peptide (cRGD) were analyzed for their potential to limit coronary neointima formation and to accelerate endothelialization by attracting endothelial progenitor cells (EPCs). BACKGROUND: Re-endothelialization is important for healing after arterial injury. METHODS: Effects of cRGD on EPC number, recruitment in flow, and invasion were analyzed in vitro. A durable polymer coating containing 67 microg cRGD per stent was developed for Guidant Tetra stents. Twelve cRGD-loaded polymer, 12 unloaded polymer, and 12 bare metal stents were deployed in porcine coronary arteries. Quantification of cRGD in peri-stent tissue was established by high-performance liquid chromatography (HPLC) and mass spectrometry (MS). Histomorphometry and immunostaining were performed after 4 and 12 weeks. Recruitment of labeled porcine EPCs was assessed 7 days after intracoronary infusion. RESULTS: The cRGD clearly supported the outgrowth, recruitment, and migration of EPCs in vitro. At 4 weeks, there was no difference for mean neointimal area and percent area stenosis in the cRGD-loaded, polymer, or bare metal stent group. At 12 weeks, neointimal area (2.2 +/- 0.3 mm2) and percent area stenosis (33 +/- 5%) were significantly reduced compared with polymer stents (3.8 +/- 0.4 mm2, 54 +/- 6%; p = 0.010) or bare metal stents (3.8 +/- 0.3 mm2, 53 +/- 3%; p < 0.001). The HPLC/MS confirmed cRGD tissue levels of 1 to 3 mug/stent at 4 weeks, whereas cRGD was not detectable at 12 weeks. Staining for CD34 and scanning electron microscopy indicated enhanced endothelial coverage on cRGD-loaded stents at 4 weeks associated with a significant increase in the early recruitment of infused EPCs. CONCLUSIONS: Stent coating with cRGD may be useful for reducing in-stent restenosis by accelerating endothelialization.

Long-term assessment of a novel biodegradable paclitaxel-eluting coronary polylactide stent.

AIM: The aim of this study was to assess technical feasibility, biocompatibility, and impact on coronary stenosis of a new biodegradable paclitaxel-loaded polylactide stent. Due to high rates of in-stent restenosis and permanent nature of metal stent implants, synthetic polymers have been proposed as surrogate materials for stents and local delivery systems for drugs. Paclitaxel was shown to inhibit vascular smooth muscle cell proliferation and migration. METHODS AND RESULTS: A novel biodegradable double-helical stent was manufactured using controlled expansion of saturated polymers (CESP) for the moulding of a bioresorbable poly(D,L)-lactic acid (PDLLA). A modified balloon catheter for stent deployment was developed according to the mechanical stent properties. Twelve paclitaxel-loaded (170 microg) polylactide stents, 12 unloaded polylactide stents, and 12 316L bare metal stents were deployed in porcine coronary arteries of 36 animals. Six pigs of each group were sacrificed after 3 weeks and 3 months, respectively, for every setting. Drug release kinetics as well as histomorphometrical and histopathological analyses were performed. A slow paclitaxel release kinetic for more than 2 months and therapeutic tissue concentrations were demonstrated. Coronary stenosis after implantation of paclitaxel-loaded stents (30+/-5% or 49+/-4%) was significantly inhibited compared to unloaded PDLLA stents (65+/-10%, P=0.021 or 71+/-4%, P=0.004) and metal stents (53+/-6% or 68+/-8%, P=0.029 and P=0.020) after 3 weeks or 3 months. Early complete endothelialisation was shown. Nevertheless, a local inflammatory response to the polylactide as a result of the polymer resorption process was observed. CONCLUSIONS: This novel polylactide stent showed sufficient mechanic stability, and by incorporation of paclitaxel, a significant potential to reduce restenosis development after vascular intervention was seen.

Downregulation of N-cadherin in the neointima stimulates migration of smooth muscle cells by RhoA deactivation.

OBJECTIVE: The aim of the study was to analyze whether cadherin- and Rho-family GTPases-mediated dynamic rearrangement of cell-cell adhesion play an important role during human arterial smooth muscle cell (haSMC) migration. METHODS: Expression patterns of N-cadherin and beta-catenin were analyzed in a domestic pig restenosis model after 14, 28, and 90 days as well as in quiescent and migratory haSMCs in vitro. N-cadherin expression was upregulated by transient sense; downregulation was induced by antisense transfection. For functional inhibition, antibody GC-4 was used. Cell migration was quantified using Boyden chamber assays. Regulation of RhoA GTPase was tested by assessment of RhoA activity. RESULTS: In vivo analysis of N-cadherin expression in a porcine restenosis model revealed downregulation in the neointima after 14 days. After 28 days, N-cadherin expression was slightly restored, while after 90 days, no difference between medial and neointimal expression was detectable. beta-Catenin levels remained unchanged during the whole period. According to the in vivo situation, N-cadherin was significantly downregulated in migratory haSMCs compared to quiescent cells in vitro. After N-cadherin overexpression, haSMC migration was reduced by 87% (P<0.001). By contrast, inhibition of N-cadherin in quiescent haSMCs by GC-4 increased the migratory potential by 87% (P<0.01). In haSMCs overexpressing N-cadherin, a significant upregulation of RhoA activity was demonstrated, while RhoA activity was blocked by GC-4. CONCLUSIONS: These results indicate that the regulation of haSMC attachment by N-cadherins is essential for haSMC migration. Modification of N-cadherin expression and activity induces RhoA signaling with relevance for the reorganization of the actin cytoskeleton.

Expression patterns of integrins on quiescent and invasive smooth muscle cells and impact on cell locomotion.

Migration and invasion of human arterial smooth muscle cells (haSMCs) are essential steps during the development of atherosclerosis, restenosis, and transplant vasculopathy. The molecular mechanisms leading to these processes are only incompletely understood. Due to their contact to the surrounding extracellular matrix, integrins have been shown to be essentially involved in cell locomotion. Therefore, the function of integrins during this process was analyzed in an in vitro model which was based on the defined quiescent and invasive phenotypes of human haSMCs induced by cell culture conditions. Flow-cytometric analysis of integrin expression between both phenotypes showed a strong upregulation of alpha 5 beta 1 (13.1x) and a modest upregulation of alpha vs beta 3 (3.4x) and alpha IIb (3.0x) in invasive haSMCs in comparison to quiescent ones. Other integrins analyzed (alpha 2, alpha 3, alpha 4, beta 1) did not show differential regulation. Functional inhibition of alpha 5 beta 1 reduced cell migration (-29%+/-8), invasion (-49%+/-16), collagen contraction (-125%), and attachment to fibronectin. Although, there was a clear discrepancy between alpha 5 beta 1 and alpha vs beta 3 expression levels, inhibition of alpha vs beta 3 (-45%+/-9) reduced haSMC invasion equally. Interestingly, alpha vs beta 3 unlike alpha 5 beta 1 blockade caused a significant stimulation of collagen contraction (+52% vs 154%) with possible implications on vascular remodeling. In conclusion, alpha 5 beta 1 blockade or combined alpha 5 beta 1/alpha v beta 3 blockade by specific antibodies or selective RGD peptides together with local drug delivery strategies could be a promising strategy for the therapy of restenotic lesions or atheromatous plaques.

Decrease of vascular smooth muscle cell locomotion by abciximab, but not tirofiban: a possible role of different affinity to alpha v beta 3 integrins.

AIM: The EPISTENT and EPIC studies demonstrated a reduction of clinically driven re-interventions after percutaneous transluminal coronary angioplasty (PTCA) and stent implantation in patients treated with abciximab, while for tirofiban no similar effects could be demonstrated. This may be explained by the different effects on the migratory and invasive potential of vascular smooth muscle cells (VSMCs) by integrin alpha v beta 3 blockade. Therefore, the objective of this study was to compare the effectiveness of abciximab and tirofiban to affect VSMC migration and invasion. METHODS: Vascular smooth muscle cells were treated with abciximab (0.1-1 microg/ml), tirofiban (0.1-1 microg/ml), and the alpha v beta 3 specific antibody LM609 (1-5 microg/ml), that was used as a positive control during the assay (treatment) over 24 h before the assay (pre-treatment), or before and during the assay (combined treatment). Sodium 3'-[1-(phenylaminocarbonyl)-3,4-tetrazolium]-bis (4-methoxyy-6-nitro) benzene sulfonic acid (XTT)-assay and cell counting measured the influence of the substances on VSMC proliferation. Using a Boyden Chamber model, the capability of VSMCs for migration and invasion was tested with different chemo-attractants and barriers. RESULTS: Any influence of the platelet glycoprotein (GP) IIb/IIIa receptor (integrin alpha IIb beta 3) antagonists on VSMC proliferation could be excluded. After combined treatment, abciximab demonstrated a dose-dependent inhibition of migration (IC50 = 33 microg/ml) and invasion (IC50 = 0.5 microg/ml) of VSMCs. Administration during the assay without pre-treatment inhibited migration similarly (IC50 = 32 microg/ml) but invasion to a significant lower extent (IC50 = 44 microg/ml). Administration of tirofiban during the assay with or without pre-treatment had no inhibitory effect on VSMC migration and invasion. Pre-treatment alone with one of the substances also did not alter VSMC migration or invasion. CONCLUSION: Abciximab administration in physiological concentrations was capable of significantly inhibiting the migratory and invasive potential of VSMCs, while for tirofiban no similar effect could be demonstrated.

Characterization of differential gene expression in quiescent and invasive human arterial smooth muscle cells.

Proliferation, migration and invasion of smooth muscle cells (SMCs) are essential pathogenic processes in the development of a broad spectrum of cardiovascular disorders, like arteriosclerosis, restenosis after percutaneous transluminal angioplasty and stent implantation as well as transplant vessel disease. As an in vitro model mimicking these processes, the Boyden chamber was employed to characterize the diverging migratory and invasive potentials of proliferating and nonproliferating human arterial SMCs (haSMCs). Using this model, differential gene expression of both phenotypes was analyzed by a cDNA array system (Clontech human cardiovascular array). With these arrays, 558 cardiovascular-associated genes could be compared. Further, gene expression was exactly quantified by real-time RT-PCR. Protein expression was analyzed by ELISA and Western blotting. In total, 47 genes were differentially expressed more than 1.5 times. Most of the differentially regulated genes in this study were associated with the extracellular matrix (ECM) and cell motility. In detail, the respective groups were matrix-organizing proteins, ECM proteins, cell adhesion proteins, extracellular communication and cytoskeleton motility proteins. Genes known to be differentially regulated during haSMC migration and invasion, like TIMP 2, TIMP 3, and MMP 3, were confirmed by the array data. Reduced expression of several cytoskeletal proteins, like vimentin, fibronectin, cytokeratins and beta1 integrin, was shown in the invasive phenotype. Further, angio-associated protein, alpha E-catenin and atrial brain natriuretic peptide receptor were downregulated whereas TFPI 2 was strongly upregulated in invasive haSMCs. In conclusion, several relevant potential candidate genes for the quiescent and the invasive SMC phenotype were identified and genes already known to be differentially regulated by previous analysis were confirmed.

Efficient transfection method for primary cells.

Transfection of primary cells and stem cells is a problem in the laboratory routine and further in tissue engineering and gene therapy. Most methods working effectively for cell lines in culture fail to transfect primary cells. Here we describe the use of the Nucleofector technology developed by amaxa biosystems. We were able to transfect primary human melanocytes, human coronary smooth muscle cells, human chondrocytes, and human mesenchymal stem cells with high efficiencies (28.9-45.3%). All primary cell types failed to be transfected satisfactorily by methods based on liposome-mediated transfection in our hands. The viability of the transfected cells varied between 11.2% and 75% in comparison to untreated cells. Only 200,000 cells per transfection sample were needed. In summary, this method presents an effective and fast mean for transfection of primary and stem cells demonstrated by four cell types which are only transfected with low efficiency by other methods.

Upregulation of the cytoskeletal-associated protein Moesin in the neointima of coronary arteries after balloon angioplasty: a new marker of smooth muscle cell migration?

Migrating cells like coronary smooth muscle cells in restenosis change their cell shape and form cellular protrusions called filopodia. A prerequisite for filopodia formation is the rearrangement of the actin cytoskeleton. An essential role of the 78-kDa protein Moesin is described for Rho- and Rac-dependent assembly of actin filaments. In vivo Moesin is not observed in mature smooth muscle cells. The objective of this study was to demonstrate that Moesin is upregulated in migrating coronary smooth muscle cells during restenosis development. In vivo expression of Moesin was upregulated in neointimal coronary smooth muscle cells of dilated porcine coronary arteries compared to the undilated left circumflex coronary artery of the same swine. Concordant to these results Moesin expression was upregulated in migrating and invading human arterial smooth muscle cells in vitro analyzed by FACS, Western blotting and RT-PCR. In addition, the invasive potential of Moesin-positive Mel Im cells transfected with Moesin sense DNA increased by 28% as compared to mock-transfected control, whereas antisense transfected cells had a decreased invasive potential of 32%. Transfection of Moesin-negative HepG2 with Moesin sense cDNA increased the invasive potential by 43%. Finally, transfection of human arterial smooth muscle cells with Moesin sense cDNA caused an increased invasive potential of 30%. Transfection of haSMCs with antisense cDNA decreased the invasive potential by 37% in comparison to mock-transfected control. These results demonstrate for the first time an upregulation of Moesin expression in coronary smooth muscle cells of the neointima after arterial injury. The increased migrative and invasive potential of cells transfected with Moesin confirmed the functional role of Moesin in cell migration. This indicates an important role of Moesin during restenosis development.