Biometric surfactant polymers designed for shear-stable endothelialization on biomaterials

We have developed a series of extracellular matrix (ECM)-like biomimetic surfactant polymers to improve endothelial cell adhesion and growth on vascular biomaterials. These polymers provide a single-step procedure for modifying the surface of existing biomaterials and consist of a poly(vinyl amine) (PVAm) backbone with varying ratios of cell-binding peptide (RGD) to carbohydrate (maltose), ranging from 100% RGD:0% maltose to 50% RGD:50% maltose. Three biomimetic surfaces, as well as a fibronectin (FN)-coated glass surface were seeded at confluence with human pulmonary artery endothelial cells (HPAECs) and exposed to shear stresses ranging from 0-40.6 dyn/cm2 for periods of 2 h and 6 h. Surfaces were examined for HPAEC coverage and cytoskeletal arrangement as a function of time and shear stress. In general, after 6 h of shear exposure, EC retention on 100% RGD > FN > 75% RGD > 50% RGD. The 100% RGD surface maintained more than 50% of its initial EC monolayer at low to moderate shear stresses whereas all other surfaces dropped to approximately 40% or less in the same shear stress range. The most stable surface, 100% RGD, showed a significant increase in cytoskeletal organization at all shear stresses greater than 2.5 dyn/cm2. In contrast, there was no real change in cytoskeletal organization on the FN surface, and there was a decrease on the 75% RGD surface over time. These results indicate that increasing surface peptide density can control EC shear stability. Furthermore, improved shear stability increases with increasing peptide density and is related to the EC's ability to reorganize its cytoskeleton.     

RGD肽对内皮细胞在聚酯材料表面粘附、增殖的影响

RGD是许多粘附蛋白结构中的高度保守序列，与细胞在生物材料表面的粘附、增殖密切相关。本研究在聚酯薄膜表面分别预衬纤维粘连蛋白和共价接枝RGD三肽，然后在不同聚酯材料上种植体外培养的人脐静脉内皮细胞，结果显示RGD可明显促进细胞在材料表面的粘附和增殖，与纤维粘连蛋白相比，RGD促进细胞粘附的作用更为明显，而在细胞增殖方面，二者的作用无显著性差异。本研究为改进生物材料的表面设计，促进心血管移植物的内皮化提供了一个切实可行的思路。     

RGD肽与生物材料的内皮化

生物材料的表面内皮化可以明显改善材料的血液相容性,促进各种生物材料,尤其是心血管移植物的临床应用,种植内皮细胞在生物材料表面的贴附及生长状况是决定内皮化能否成功的关键因素,RGD是许多粘附蛋白所共有的高度保守氨基酸序列,这一序列在介导细胞粘附,迁移及生长方面起重要作用,我们综述了RGD与整合素受体的相互作用,RGD生物活性的影响因素以及它在生物材料内皮化方向的应用。     

Corneal epithelial cell growth over tethered-protein/peptide surface-modified hydrogels

In this study, we investigated the corneal epithelial cell growth rate and adhesion to novel hydrogels with (1) extracellular matrix proteins [fibronectin, laminin, substance P, and insulin-like growth factor-1 (IGF-1)] and (2) peptide sequences [RGD and fibronectin adhesion-promoting peptide (FAP)] tethered to their surface on poly(ethylene glycol) (PEG) chains. The growth rate to confluence of primary rabbit cornea epithelial cells was compared for plain polymethacrylic acid-co-hydroxyethyl methacrylate (PHEMA/MAA) hydrogels, PHEMA/MAA hydrogels coated with extracellular matrix proteins or peptides, and PHEMA/MAA hydrogels with tethered extracellular matrix proteins or peptides on the surface. The development of focal adhesions by the epithelial cells grown on the surfaces was determined by F-actin staining. Little to no epithelial cell growth occurred on the plain hydrogel surfaces throughout the 15-day culture period. Of the coated hydrogels, only the fibronectin-coated surfaces showed a significant increase in cell growth compared to plain hydrogels (p < 0.009). However, even these surfaces reached a maximum of only 20% confluence. Laminin, fibronectin adhesion-promoting peptide (FAP), and fibronectin/laminin (1:1) tether-modified hydrogels all achieved 100% confluence by the end of the culture period, although the rates at which confluence was reached differed. F-actin staining showed that focal adhesions were formed for the laminin, FAP, and fibronectin/laminin tether-modified surfaces. The results support the hypothesis that tethering certain extracellular matrix proteins and/or peptides to the hydrogel surface enhances epithelial cell growth and adhesion, compared with that seen for protein-coated or plain hydrogel surfaces.     

Additive effect of RGD coating to functionalized titanium surfaces on human osteoprogenitor cell adhesion and spreading

Titanium-based biomaterials for endosseous implants have found widespread applications in the orthopedic, maxillofacial, and dental domains. Indeed, the surface characteristics such as their chemical modification control considerably the cellular response and, subsequently, the quality and the quantity of new-formed bone around the implant. In this study, human osteoprogenitor (HOP) cell adhesion on different titanium surfaces functionalized with hydroxyapatite (HA), type I collagen, or Arg-Gly-Asp (RGD)-containing peptides is investigated by the quartz crystal resonators and by confocal laser scanning microscopy (CLSM) for the imaging of focal contact formation. Data obtained by quartz crystal resonator technique revealed that RGD-containing peptides alone increase HOP cell adhesion in early time period of culture. Moreover, association of RGD-containing peptides with either type I collagen or with HA layers induces an additive effect on HOP cell adhesion compared to Ti-Coll or Ti-HA. CLSM shows both the area of focal contact by cell unit and the cytoskeleton network organization to differ according to the surfaces. Interestingly, association of RGD-containing peptides with HA layers induces an additive effect on focal contact formation on HOP cells compared to Ti-HA alone. These data confirm that an RGD peptide effect occurs in the early time of culture, which is beneficial for osteoblast to spreading, differentiation, and survival.     

Human microvascular endothelial cell growth and migration on biomimetic surfactant polymers

Successful engineering of a tissue-incorporated vascular prosthesis requires cells to proliferate and migrate on the scaffold. Here, we report on a series of "ECM-like" biomimetic surfactant polymers that exhibit quantitative control over the proliferation and migrational properties of human microvascular endothelial cells (HMVEC). The biomimetic polymers consist of a poly(vinyl amine) (PVAm) backbone with hexanal branches and varying ratios of cell binding peptide (RGD) to carbohydrate (maltose). Proliferation and migration behavior of HMVEC was investigated using polymers containing RGD: maltose ratios of 100:0, 75:25 and 50:50, and compared with fibronectin (FN) coated glass (1 microg/cm2). A radial Teflon fence migration assay was used to examine HMVEC migration at 12 h intervals over a 48 h period. Migration was quantified using an inverted optical microscope, and HMVEC were examined by confocal microscopy for actin and focal adhesion organization/ arrangement. Over the range of RGD ligand density studied (approximately 0.19-0.6 peptides/nm2), our results show HMVEC migration decreases with increasing RGD density in the polymer. HMVEC were least motile on the 100% RGD polymer (approximately 0.38-0.6 peptides/nm2) with an average migration of 0.20 mm2/h in area covered, whereas HMVEC showed the fastest migration of 0.48+/-0.06 mm2/h on the 50% RGD surface ( approximately 0.19-0.30 peptides/nm2). In contrast, cell proliferation increased with increasing surface peptide density; proliferation on the 50% RGD surface was 1.5%+/-0.06/h compared with 2.2%+/-0.07/h on the 100% RGD surface. Our results show that surface peptide density affects cellular functions such as growth and migration, with the highest peptide density supporting the most proliferation but the slowest migration.     

Cell adhesion peptide modification of gold-coated polyurethanes for vascular endothelial cell adhesion

Gold-coated polyurethanes were chemisorbed with three cell-adhesion peptides having an N-terminal cysteine: cys-arg-gly-asp (CRGD), cys-arg-glu-asp-val (CREDV), and the cyclic peptide cys-cys-arg-arg-gly-asp-try-leu-cys (CCRRGDWLC). The peptides were selected based on their presumed preferential interactions with the cell-surface integrins on vascular endothelial cells. The ability of the surfaces to support the preferential adhesion of human vascular endothelial cells was studied by comparing in vitro adhesion results for these cells with those from mouse 3T3 fibroblasts. Surface modification with the peptides was confirmed by water-contact angles and XPS. Surface morphology was determined by AFM and SEM. In vitro cell-culture studies in conjunction with plasma-protein adsorption and immunoblotting were performed on the various modified surfaces. The data suggest that peptide-modified surfaces have significant potential for supporting cell adhesion. Little or no cell adhesion was noted on gold- or cysteine-modified control surfaces. Human vascular endothelial cells showed the greatest adhesion to the CCRRGDWLC-modified surfaces, and the 3T3 fibroblasts adhered best to the CREDV-modified surfaces. Protein adsorption studies suggest that the preferential adsorption of the cell-adhesive proteins fibronectin and vitronectin is not likely mediating the differences noted. It is concluded that the cell-adhesive peptide-modified gold-coated polymers have significant potential for further development both as model substrates for fundamental studies and for use in biomaterials applications.     

Cell adhesion to textured silicone surfaces: the influence of time of adhesion and texture on focal contact and fibronectin fibril formation.

Cell adhesion and spreading on biomaterials is a key issue in the study of cell-biomaterial interactions. With the development of new disciplines within biomaterials research such as tissue engineering and cellular therapy, information at molecular and structural levels is needed in order to conceive and design biomaterials that elicit specific, functional cell responses. In this study we determined the formation of focal adhesions and fibronectin fibrillar structures by human fibroblasts and human umbilical vein endothelial cells adhered to fibronectin-precoated, smooth, and textured silicones as a function of time. Textures consisted of parallel ridges and 0.5 mm deep grooves with a width of 2, 5, and 10 mm. In addition, pillar and well constructs were used. Cells assembled focal adhesions within the first 24 h of adhesion. Fibronectin production and assembly resulted in a dense fibrillar network at day 6. Initial focal adhesion density and size were dictated by the presence of the texture. Topography also influenced initial fibronectin deposition, although the differences did not result in apparent differences in fibronectin networks after 6 days of incubation. Without fibronectin preadsorption, cells did not proliferate on the silicone surfaces. Cells adhered to glass removed all the preabsorbed fibronectin, whereas on silicone they did not. The present study shows that different textures initially give rise to differences in focal contact and fibronectin fibril assembly. The effects of the small, initial in vitro differences on in vivo tissue biocompatibility remains to be studied.     

RGD-grafted thermoreversible polymers to facilitate attachment of BMP-2 responsive C2C12 cells

The purpose of this study was to design thermoreversible biomaterials for enhanced adhesion of bone morphogenetic protein-2 (BMP-2)-responsive cells. Peptides containing the arginine-glycine-aspartic acid (RGD) sequence were conjugated to N-isopropylacrylamide (NiPAM) polymers via amine-reactive N-acryloxysuccinimide (NASI) groups. In monolayer cultures, the adhesion of BMP-2-responsive C2C12 cells to RGD-grafted NiPAM/NASI surfaces was significantly higher than adhesion on ungrafted NiPAM/NASI surfaces. Although the morphology of cells adhered to RGD-grafted NiPAM/NASI surfaces was comparable to cells adhered on tissue culture polystyrene (TCPS), long-term cell growth was limited on the NiPAM/NASI surfaces, even for RGD-grafted surfaces. Treatment of C2C12 cells with recombinant BMP-2 induced dose-dependent osteoblastic differentiation as assessed by alkaline phosphatase (ALP) activity. In the absence of BMP-2, cells cultured on NiPAM/NASI polymers (either grafted with RGD peptide or not) expressed significantly higher levels of ALP activity than the cells cultured on TCPS, indicating that the polymer surfaces induced some osteoblastic activity in C2C12 cells without the need for BMP-2. We conclude that NiPAM-based thermoreversible biomaterials, despite their limited ability to support cell growth, allowed an enhanced expression of the chosen osteogenic marker (ALP) by C2C12 cells in vitro.     

Acrylic Acid-RGD as a Biomimetic Surface Modifier for Poly(ethylene terephthalate)

INTRODUCTION　Biomaterials play an importantrole in human disease- treatmentand healing〔1,2〕.Due to the good mechanical property,PET is used to the coating of artificial heartvalve,the film of mending hearts and artificial vessel etc〔3〕.But the imperfection isthe low capability of surface hydrophile leading to the high static and low water ad-sorption〔4〕.In the application,traditional artificial cardiovascular materials( e.g.PET) have blood coagulation,alexin- activation and other…     

Cardiomyocytes in vitro adhesion is actively influenced by biomimetic synthetic peptides for cardiac tissue engineering

Scaffolds for tissue engineering must be designed to direct desired events such as cell attachment, growth, and differentiation. The incorporation of extracellular matrix-derived peptides into biomaterials has been proposed to mimic biochemical signals. In this study, three synthetic fragments of fibronectin, vitronectin, and stromal-derived factor-1 were investigated for the first time as potential adhesive sequences for cardiomyocytes (CMs) compared to smooth muscle cells. CMs are responsive to all peptides to differing degrees, demonstrating the existence of diverse adhesion mechanisms. The pretreatment of nontissue culture well surfaces with the (Arginine-Glycine-Aspartic Acid) RGD sequence anticipated the appearance of CMs' contractility compared to the control (fibronectin-coated well) and doubled the length of cell viability. Future prospects are the inclusion of these sequences into biomaterial formulation with the improvement in cell adhesion that could play an important role in cell retention during dynamic cell seeding.     

Mediating specific cell adhesion to low-adhesive diblock copolymers by instant modification with cyclic RGD peptides

One promising strategy to control the interactions between biomaterial surfaces and attaching cells involves the covalent grafting of adhesion peptides to polymers on which protein adsorption, which mediates unspecific cell adhesion, is essentially suppressed. This study demonstrates a surface modification concept for the covalent anchoring of RGD peptides to reactive diblock copolymers based on monoamine poly(ethylene glycol)-block-poly(D,L-lactic acid) (H(2)N-PEG-PLA). Films of both the amine-reactive (ST-NH-PEG(2)PLA(20)) and the thiol-reactive derivative (MP-NH-PEG(2)PLA(40)) were modified with cyclic alphavbeta3/alphavbeta5 integrin subtype specific RGD peptides simply by incubation of the films with buffered solutions of the peptides. Human osteoblasts known to express these integrins were used to determine cell-polymer interactions. The adhesion experiments revealed significantly increased cell numbers and cell spreading on the RGD-modified surfaces mediated by RGD-integrin-interactions.     

Endothelial cell formation of focal adhesions on hydrophilic plasma polymers.

Endothelial cell (EC) formation and distribution of both actin stress fibers and focal contacts on hydrophilic plasma polymers derived from gamma-butyrolactone (GBL) and n-vinylpyrrolidone (NVP) were examined to determine their ability to support endothelial cell growth in comparison to fibronectin. One hour after seeding, cells adhered and spread moderately on fibronectin with the development of defined actin stress fibers and focal adhesions compared to NVP and GBL, on which the cells were spread with poorly developed stress fibers and a perinuclear localization of vinculin. At 3 h, cells continue to spread more on fibronectin and NVP than GBL, and the cells on fibronectin had well-defined stress fibers terminating with sharp spikes of vinculin, typical of focal adhesions. At this time point, paxillin, a signaling component of focal adhesion complex, was predominantly localized at the focal contacts for well-spread EC on fibronectin and NVP, whereas it was almost entirely concentrated in the perinuclear region of less-spread cells on GBL. However, by 24h, cells were much more spread on all three surfaces with defined stress fibers and focal contacts although EC expression of vinculin and paxillin was moderate on GBL compared to fibronectin and NVP. These results suggest that EC can form cytoskeletal structures necessary for cell survival on plasma polymers, especially on more hydrophilic NVP, which could be exploited as interface material for seeding endothelial cells.     

RGD modified polymers: biomaterials for stimulated cell adhesion and beyond

Since RGD peptides (R: arginine; G: glycine; D: aspartic acid) have been found to promote cell adhesion in 1984 (Cell attachment activity of fibronectin can be duplicated by small synthetic fragments of the molecule, Nature 309 (1984) 30), numerous materials have been RGD functionalized for academic studies or medical applications. This review gives an overview of RGD modified polymers, that have been used for cell adhesion, and provides information about technical aspects of RGD immobilization on polymers. The impacts of RGD peptide surface density, spatial arrangement as well as integrin affinity and selectivity on cell responses like adhesion and migration are discussed.     

High-affinity augmentation of endothelial cell attachment: long-term effects on focal contact and actin filament formation

Coadsorption of high-affinity avidin with lower affinity cell adhesion protein fibronectin has been shown to significantly augment short-term (1 h) adhesion and spreading of endothelial cells; however, the longer term persistence of avidin binding and its effect on endothelial cell adhesion have not been addressed. In this study, the presence of avidin-biotin bonds 24 h after cell adhesion to the dual ligand surfaces was verified by laser confocal microscopy of a fluorescent avidin analog, streptavidin. Total internal reflection microscopy showed that the focal contact area, focal contact density, and cell spreading all increased significantly at 24 h compared to fibronectin-treated control surfaces. Focal contact area was identical when measured with cells that were labeled with either the fluorescent streptavidin or a carbocyanine dye incorporated in the cell membrane. Confocal images of stress fibers formed in cells adherent to dual ligand surfaces after 24 h were thicker and more numerous compared to cells adherent to fibronectin controls. The results indicate that 24 h after initial attachment avidin-biotin is localized to focal contacts on the basal surface and affects cell spreading, actin filament organization, and focal contact density.     

Mechanisms underlying the attachment and spreading of human osteoblasts: From transient interactions to focal adhesions on vitronectin-grafted bioactive surfaces

The features of implant devices and the reactions of bone-derived cells to foreign surfaces determine implant success during osseointegration. In an attempt to better understand the mechanisms underlying osteoblasts attachment and spreading, in this study adhesive peptides containing the fibronectin sequence motif for integrin binding (Arg-Gly-Asp, RGD) or mapping the human vitronectin protein (HVP) were grafted on glass and titanium surfaces with or without chemically induced controlled immobilization. As shown by total internal reflection fluorescence microscopy, human osteoblasts develop adhesion patches only on specifically immobilized peptides. Indeed, cells quickly develop focal adhesions on RGD-grafted surfaces, while HVP peptide promotes filopodia, structures involved in cellular spreading. As indicated by immunocytochemistry and quantitative polymerase chain reaction, focal adhesions kinase activation is delayed on HVP peptides with respect to RGD while an osteogenic phenotypic response appears within 24 h on osteoblasts cultured on both peptides. Cellular pathways underlying osteoblasts attachment are, however, different. As demonstrated by adhesion blocking assays, integrins are mainly involved in osteoblast adhesion to RGD peptide, while HVP selects osteoblasts for attachment through proteoglycan-mediated interactions. Thus an interfacial layer of an endosseous device grafted with specifically immobilized HVP peptide not only selects the attachment and supports differentiation of osteoblasts but also promotes cellular migration.     

A fluorophore-tagged RGD peptide to control endothelial cell adhesion to micropatterned surfaces

The long-term patency rates of vascular grafts and stents are limited by the lack of surface endothelialisation of the implanted materials. We have previously reported that GRGDS and WQPPRARI peptide micropatterns increase the endothelialisation of prosthetic materials in vitro. To investigate the mechanisms by which the peptide micropatterns affect endothelial cell adhesion and proliferation, a TAMRA fluorophore-tagged RGD peptide was designed. Live cell imaging revealed that the micropatterned surfaces led to directional cell spreading dependent on the location of the RGD-TAMRA spots. Focal adhesions formed within 3 h on the micropatterned surfaces near RGD-TAMRA spot edges, as expected for cell regions experiencing high tension. Similar levels of focal adhesion kinase phosphorylation were observed after 3 h on the micropatterned surfaces and on surfaces treated with RGD-TAMRA alone, suggesting that partial RGD surface coverage is sufficient to elicit integrin signaling. Lastly, endothelial cell expansion was achieved in serum-free conditions on gelatin-coated, RGD-TAMRA treated or micropatterned surfaces. These results show that these peptide micropatterns mainly impacted cell adhesion kinetics rather than cell proliferation. This insight will be useful for the optimization of micropatterning strategies to improve vascular biomaterials.     

High molecular weight kininogen inhibition of endothelial cell function on biomaterials

Synthetic vascular grafts implanted into humans fail to develop a complete endothelial lining. In previous studies, we have shown that high-molecular-weight kininogens (HMWK) adsorb to the surfaces of biomaterials. In addition, it has been demonstrated that these proteins modulate cellular function. In the present study, we report on the adhesion and proliferation of human umbilical-vein endothelial cells (HUVEC) on tissue culture polystyrene, glass, polyurethane, and Mylar(trade mark) surfaces coated with human HMWK, either single-chain HMWK (SC-HMWK) or double-chain HMWK (DC-HMWK). Surfaces coated with fibronectin served as a positive control for these experiments. Parallel experiments were performed in which HUVEC were allowed to migrate from crosslinked dextran microcarrier beads (Cytodex 2) onto HMWK-coated surfaces. Our results indicate that HMWK-coated surfaces inhibit endothelial cell adhesion, proliferation, and migration at 24 and 72 h, and this inhibition is concentration dependent. To determine a potential mechanism for this inhibitory phenomenon, cells were stained for cytoskeletal actin filaments using rhodamine-phalloidin. Endothelial cells on HMWK-coated surfaces displayed F-actin filament reorganization/disassembly, characterized by the absence of peripheral actin bands in focal adhesion contacts. We conclude that HMWK inhibit endothelial cell adhesion, proliferation, and migration on a variety of biomaterial surfaces. This inhibitory effect may play a role in promoting the lack of endothelialization in synthetic vascular grafts, which is thought to play a significant role in the failure of these devices.     

Evaluation of protein-modulated macrophage behavior on biomaterials: designing biomimetic materials for cellular engineering

Macrophage is a central cell type in directing host inflammatory and immune processes; hence, its response to biomaterials (i.e. adhesion and giant cell formation) has a direct impact on material biostability and biocompatibility. In this paper, several in vitro and in vivo techniques from previously published results and current investigations are highlighted and presented to demonstrate means of delineating a part of the complex molecular mechanisms involved in the interaction between biomaterials and macrophages. Complement component C3 was found critical in mediating the initial adhesion of human macrophages on medical-grade polyetherurethaneureas. From radioimmunoassay studies, the presence of a diphenolic antioxidant additive in polyetherurethaneureas increased the propensity for complement upregulation but did not affect adherent macrophage density. The subcutaneous cage-implant system was utilized to confirm the role of interleukin-4 in the fusion of adherent macrophages to form foreign body giant cells on polyurethanes in vivo. To probe the function-structural relationship of macrophage-active proteins, fibronectin was employed as a model in the formulation of synthetic oligopeptide mimetics. Peptides were grafted onto previously developed, non-cell adhesive polyethyleneglycol-based networks. The results indicate that grafted tripeptide RGD sequence supported higher adherent macrophage density than surfaces grafted with other peptides such as PHSRN and PRRARV sequences. However, the formation of foreign body giant cells on peptide-grafted networks was highly dependent on the relative orientation between PHSRN and RGD sequences located in a single peptide.     

Protein and surface effects on monocyte and macrophage adhesion, maturation, and survival

Cell adhesion and maturation can be affected by the protein adsorption profile on the surface of an implanted biomaterial. In this study we have investigated how surface chemistry and adsorbed proteins can modulate monocyte and macrophage adhesion, IL-13-induced foreign-body giant cell formation, and apoptosis in vitro. Compared to a dimethylsilane-modified surface (DM), a surface modified with RGD peptides had no effect on adhesion density, foreign-body giant cell (FBGC) formation, or apoptosis in nondepleted serum conditions. The depletion of specific adhesive proteins affected adhesion, FBGC formation, and apo- ptosis. While the depletion of fibronectin and vitronectin had no overall effect compared to nondepleted serum conditions, the depletion of IgG from serum caused a significant decrease in initial adherent cell density [1000 +/- 200 compared to 2460 +/- 590 (p = 0.02)], a significant decrease in FBGC formation [2% compared to 17% (p = 0.02)], and a significant increase in the level of apoptosis [57% compared to 32% (p = 0.01)] on DM. The lowered initial adherent cell density on DM was not observed on the RGD surface, indicating that the RGD surface promotes increased initial adhesion. However, the RGD surface does not affect FBGC formation (i.e., macrophage fusion) or levels of apoptosis, which remained comparable to those on the DM surfaces at days 7 and 10.