The present invention refers to an implant with a surface layer having a topographic modification.
US 2009/0248157 A1 provides a biocompatible substrate for cell adhesion, differentiation, culture and/or growth. The substrate having an arrangement of topographical features arrayed in a pattern based on a notional symmetrical lattice in which the distance between nearest neighbour notional lattice points is C and is between 10 nm and 10 μm. The topographical features are locally miss-ordered such that the centre of each topographical feature is a distance of up to one half of C from its respective notional lattice point.
Cell spreading on a substrate is a highly regulated process that requires the fast interaction between transmembrane receptors of the integrin family and specific ligands on the surface of the substrate (B. Geiger, J. P. Spatz and A. D. Bershadsky, Nat Rev Mol Cell Biol, 2009, 10, 21-33). Early receptor binding leads to onset of spreading and goes along with the enrichment of cytoplasmic proteins at the adhesion site. Here, talin, paxillin, vinculin, and several other proteins contribute to the generation of a nascent focal complex. The recruitment of activated Focal Adhesion Kinase (FAK) and Src-kinase, in turn, forms the basis of adhesion signalling (X. Zhang, G. Jiang, Y. Cal, S. J. Monkley, D. R. Critchley and M. P. Sheetz, Nat Cell Biol, 2008). Small, isotropic focal complexes can mature into larger focal adhesions in a process requiring myosin-II mediated cell contractility and a mechanical linkage with the actin cytoskeleton. On the other hand, insufficient integrin engagement or clustering delays spreading and/or induces cell detachment and eventually apoptosis, thus leading to an incomplete coverage of the target surface (E. A. Cavalcanti-Adam, T. Volberg, A. Micoulet, H. Kessler, B. Geiger and J. P. Spatz, Biophysical journal, 2007, 92, 2964-2974).
Endothelial cells (EC) spread poorly on flat, rigid implant surfaces such as those of commonly used stents for the treatment of the effects of coronary artery disease (S. Garg and P. W. Serruys, J Am Coll Cardiol, 2010, 56, S1-42; M. Hristov, A. Zernecke, E. A. Liehn and C. Weber, Thromb Haemost, 2007, 98, 274-277). Topographic modifications of the surface with micron and sub-micron scale structures may accelerate onset of spreading as well as subsequent topography-guided cell polarization (contact guidance), which are requirements for the re-establishment of a differentiated endothelium. Indeed, surface texturing of known biocompatible materials represents a promising strategy to modulate cellular processes which are essential for the development or regeneration of functional tissues (F. Guilak, D. M. Cohen, B. T. Estes, J. M. Gimble, W. Liedtke and C. S. Chen, Cell Stem Cell, 2009, 5, 17-26; F. Variola, F. Vetrone, L. Richert, P. Jedrzejowski, J. H. Yi, S. Zalzal, S. Clair, A. Sarkissian, D. F. Perepichka, J. D. Wuest, F. Rosei and A. Nanci, Small, 2009, 5, 996-1006). Studies have shown that surface modifications profoundly influence almost all tested cellular activities from cell polarization and migration to gene expression profile, differentiation, and apoptosis (K. Kandere-Grzybowska, C. J. Campbell, G. Mahmud, Y. Komarova, S. Soh and B. A. Grzybowski, Soft Matter, 2007, 3, 672-679; K. Kulangara and K. W. Leong, Soft Matter, 2009, 5, 4072-4076; V. Brunetti, G. Maiorano, L. Rizzello, B. Sorce, S. Sabella, R. Cingolani and P. P. Pompa, Proc Natl Acad Sci USA, 2010, 107, 6264-6269; M. J. Dalby, N. Gadegaard, R. Tare, A. Andar, M. O. Riehle, P. Herzyk, C. D. Wilkinson and R. O. Oreffo, Nat Mater, 2007, 6, 997-1003; J. Z. Gasiorowski, S. J. Liliensiek, P. Russell, D. A. Stephan, P. F. Nealey and C. J. Murphy, Biomaterials, 2010, 31, 8882-8888). However, these studies followed only phenomenological approaches due to the lack of knowledge of the underlying biochemical mechanism. While some insights were provided by works investigating the role of focal adhesion maturation during contact guidance, the effects of topography on cell-to-substrate interaction prior to spreading are still unknown. Fundamental questions remain to be answered, such as whether onset of spreading and contact guidance are independently modulated by the surface topography and whether it is possible to decouple the two processes by pure topographical means.
Thus, beside the tremendous development of stent technology in the last 20 years, there are still some major difficulties which have to be overcome:
The intention of this invention with respect to the case wherein the implant is a stent is therefore to provide a specific geometrical arrangement of surface structures in the sub-micron to micrometer regime for faster re-endothelialization of stent struts after drug eluting stent deployment via Percutaneous Coronary Intervention (PCI). This soft healing approach will significantly reduce the problem of late stent thrombosis (LST) and restenosis.
In order to solve or at least to reduce one or more of the above mentioned technical problems, there is provided an implant with a surface layer having a topographic modification including a line pattern with ridge and groove widths of 0.9 to 1.1 μm, more preferred 0.95 to 1.05 μm, especially 1 μm, and a ridge height of more than 0.9 μm, especially 1 μm or more.
As a result of the inventive topographic modification, neointima formation on the surface of an implant could be significantly accelerated. The adhesion of for example Human Umbilical Vein Endothelial Cells (HUVEC) is supported by the inventive surface structure. The topographic modification includes a line pattern (or grating) of characteristic dimension suitable for cell adhesion. Ridge width and groove width should be the same or nearly the same (for example a ratio of 0.9 μm ridge width to 1.1 μm groove width should be included). The entire surface or only fractions of the surface of the implant may be covered by the surface layer showing the inventive topographic modification.
According to a preferred embodiment, the implant includes a main body made of a metallic material and the surface layer is disposed on the main body and being made of a polymer material. The manufacturing process of the inventive topographic modification can be simplified for example in that a surface layer of the polymeric material is heated up to its glass transition temperature and a die having a negative contour of the line pattern is pressed into the polymeric material.
Preferably, the metallic material is a biodegradable metallic material. The biodegradable metallic material may be one selected of a magnesium alloy, iron alloy, magnesium or iron. Especially, the biodegradable metallic material is a magnesium alloy. A magnesium alloy is to be understood as a metallic structure, the main component of which is magnesium. The main component is the alloy component that has the highest proportion of weight in the alloy. The share of the main component preferably amounts to more than 50% by weight, particularly more than 70%. The same applies to what is understood of the term iron alloy.
For purposes of the present disclosure, a material referred to as biodegradable in which degradation occurs in a physiological environment, which finally results in the entire implant or the part of the implant formed by the material losing its mechanical integrity. Artificial plasma, as has been previously described according to EN ISO 10993-15:2000 for biodegradation assays (composition NaCl 6.8 g/l. CaCl2 0.2 g/l. KCl 0.4 g/l. MgSO4 0.1 g/l. NaHCO3 2.2 g/l. Na2HPO4 0.126 g/l. NaH2PO4 0.026 g/l), is used as a testing medium for testing the corrosion behavior of a material coming into consideration. For this purpose, a sample of the material to be assayed is stored in a closed sample container with a defined quantity of the testing medium at 37° C. At time intervals-tailored to the corrosion behaviour to be expected of a few hours up to multiple months, the sample is removed and examined for corrosion traces in a known way.
In addition, also the polymer material of the surface layer may a biodegradable polymer material. Exemplary biodegradable polymers include polydioxanone, polyglycolide, polycaprolactone, polylactide (for example poly-L-lactide, poly-D,L-lactide and copolymers and blends such as poly(L-lactide-coglycolide), poly(D,L-lactide-coglycolide), poly(L-lactide-co-D,L-lactide), poly(L-lactide-cotrimethylene carbonate), polysaccharides (for example chitosan, levan, hyaluronic acid, heparin, dextran, cellulose), polyhydroxyvalerate, ethylvinyl acetate, polyethylene oxide, polyphosphoryl choline, fibrin, albumin, polyhydroxybutyric acid (atactic, isotactic, syndiotactic and blends thereof), and the like.
The line pattern of the surface layer may be covered by a biodegradable topcoat. The topcoat may protect the line pattern as well as a drug eluting coating especially during the process of implantation.
According to another preferred embodiment of the invention, an angle between a groove bottom surface and a side wall of the ridge is between 90° to 135°.
The line pattern needs not to cover the whole surface of the implant but may be interrupted for example in longitudinal extension of the implant. According to own investigations (cf.
Implants are devices introduced into the body via a surgical method and comprise sensors, fasteners for bones, such as screws, plates, or nails, surgical suture material, intestinal clamps, vascular clips, prostheses in the area of the hard and soft tissue, and anchoring elements for electrodes, in particular, of pacemakers or defibrillators.
The implant is preferably a stent. Stents are endovascular prostheses which may be used for treatment of stenoses (vascular occlusions). Stents typically have a hollow cylindrical or tubular basic mesh which is open at both of the longitudinal ends of the tubes. The tubular basic mesh of such an endoprosthesis is inserted into the blood vessel to be treated and serves to support the vessel. Stents of typical construction have filigree support structures made of metallic struts which are initially provided in an unexpanded state for introduction into the body and are then widened into an expanded state at the location of application. Preferably, the line pattern covers at least a luminal surface of the stent.
As described above, arterial walls are injured during the deployment of BMS. In 20-30% of all cases, SMC proliferation is enhanced over EC growth due to an inflammatory response that leads to a non-functional ECL and excessive tissue formation. To prevent this, the wound healing process should be reasonable fast supporting EC growth while suppressing SMC proliferation. Development of a functional endothelial cell layer covering the stent and therefore shielding the thrombogenic metal surface from direct blood contact will minimize LST, Restenosis on the other hand will be suppressed by the reduced inflammatory response to stent implantation by providing a functional ECL. Beside external chemical or biological signaling pathways, topography in the nano to micro-meter range does also influence ECL formation. The reason behind is, cellular mechanosensation is influencing adhesion, proliferation and migration by transducing the external mechanical signals into internal biological stimuli regulating cellular behaviour. By precisely control the geometrical dimensions, the orientation and arrangement of the structural features and the wall shear stress along the strut surface one can significantly enhance and accelerate the wound healing process. Not only circulating progenitor cell adhesion may be enhanced but also proliferation and migration of existing endothelial cells will be influenced and guided by the micro-texture.
The stent may be a drug eluting stent (DES). Incorporation of drug eluting stents into a vessel is usually prohibited or inhibited by use of antiproliferative drugs like rapamycin or paclitaxel as a side effect. However, formation of a thin neointima appears to be essential for healing of the vessel. By means of the inventive topographic modification the healing process can be supported and accelerated.
According to the studies for the present invention, live-cell imaging and high-resolution microscopy has been applied to measure spreading dynamics and contact guidance on biocompatible structured substrates. The interaction between cells and topography was further resolved using scanning electron microscopy. Additionally, specific inhibitors of cell contractility to further analyze the role of the ROCK1/2-myosin-II pathway in the regulation of onset of endothelial spreading and contact guidance has been used. Finally, biochemical techniques and fluorescent staining to pinpoint the relevant molecular players contributing to this effect is have been applied.
Substrate Fabrication
For the fabrication of the molding tool, chromium patterns had to be transferred into a 525 μm thick silicon wafer via photo lithography and reactive ion etching. In the first step the wafer was spin-coated with a Microposit 51805 positive tone photo resist (thickness ˜0.5 μm). The gratings were imprinted on 180 μm thick untreated Cyclic Olefin Copolymer (COC) foils (Ibidi, Germany) using nanoimprint lithography (NIL). The height of the ridges was adjusted by tuning the etching time while the side wall steepness was kept constant. This procedure generated squared patterned areas of 1 cm side length. Ten molds were fabricated with ridge and groove widths of 1 μm and ridge height of 0.1, 0.2, 0.4, 0.6, 0.8, 1, 1.5, and 2 μm and with ridge and groove width of 5 μm and ridge height of 0.1 and 1 μm (Table 1). The COC substrates were placed on top of the mold and softened by raising the temperature up to 160-180° C. A pressure of 50 bar was then applied for 10 minutes before cooling down to 40° C. Finally, the pressure was released and the mold was detached from the substrate with a scalpel (
Constructs
Vinculin-FP635 (Far Red Fluorescent Protein) construct was used (a kind gift of Dr. Ralf Kemkemer, Max Planck Institute for Metals Research, Stuttgart, Germany).
Antibodies
Rabbit anti-Src (pan; #2123), FAK (pan; #3285), phospho-Src (#2101) and phospho-FAK (#3283) were purchased from Cell Signaling Technology (USA). Goat anti-VE-Cadherin (#6458) was purchased from Santa Cruz Biotechnology Inc. (USA). Secondary goat anti-rabbit HRP (#65-6120) and donkey anti-goat (A-11055) antibodies were from Invitrogen (Carlsbad, USA).
Cell Culture and Inhibitor Treatment
Human umbilical vein endothelial cells (HUVEC; Invitrogen) were grown in medium 200PRF supplemented with fetal bovine serum 2% v/v, hydrocortisone 1 μg/ml, human epidermal growth factor 10 ng/ml, basic fibroblast growth factor 3 ng/ml and heparin 10 μg/ml (all reagents from Invitrogen) and were maintained at 37° C. and 5% CO2. To visualize focal adhesions, HUVEC were transfected using a Neon Transfection System (Invitrogen). All reported experiments were performed using cells with less than seven passages in vitro. Up to six imprinted COC substrates (1 cm2) were individually sealed to the bottom of a well in a 12-multiwell culture plate (Becton Dickinson, USA) hereafter denoted as ‘topographic chip’. The topographic chips were sterilized by overnight treatment with ethanol and rinsed three times with PBS. The substrates were then coated with Poly-L-lysine (PLL) solution 0.01% (Sigma-Aldrich, USA) according to the manufacturer's specification. The topographic chip was stored at 4° C. until the seeding of the cells.
To generate confluent monolayers cells were seeded on COC substrates at high density (60-70×104 cell/cm2) as reported by Lampugnani et al. and cultured for three days. To measure the time to onset of spreading, cells were detached from a subconfluent cell culture and resuspended in pre-warmed medium without antibiotics. The cells were then counted, diluted to reach a concentration of 5×104 cells in 1 ml of medium and then seeded onto the substrates.
To measure the spreading dynamics of individual HUVECs contacting flat or topographically modified substrates, the cell membrane was labelled using a vital fluorophore (CellTracker Green, C2925 Molecular Probes; Invitrogen). HUVECs were seeded 24 hours before the experiment in a 12 well plate (1×105 cell/well). For staining, cells were washed and incubated for 30 min at 37° C. in medium without serum containing 0.5 μM CellTracker Green. After labeling, complete fresh medium was added and cells were left to recover for 30 minutes before starting the spreading experiment. Cells were gently detached, counted and seeded on the substrate and imaging started immediately after seeding.
For contractility inhibition experiments during endothelial spreading, the cells were treated with DMSO (corresponding v/v), 30 μM ML-7, 10 μM Y27632 or 50 μM blebbistatin. The drugs were dissolved in DMSO (ML-7, blebbistatin) or in distilled water (Y27632) and added to the cells 30 minutes before starting the experiment.
Immunostaining
HUVEC adhering to COC substrates were fixed for 15 minutes with 3% paraformaldehyde (PFA, pH=7.4) at room temperature. Cells were then rinsed once with PBS and permeabilized for 30 minutes with a solution of 0.1% TritonX-100 in PBS at room temperature. After rinsing with PBS, cells were incubated for 3 hours in blocking buffer. F-actin was stained by incubating with TRITC-phalloidin (Sigma, USA) overnight at 4° C. After rinsing five times with PBS, the substrates were mounted on glass coverslips and immediately imaged. VE-Cadherin and phosphorylated (p)-FAK in HUVECs were localized following the protocol reported by Lampugnani et al. 22 Briefly, cells were fixed for 15 minutes with 3% PFA and then permeabilized for 3 minutes with a solution of 0.1% TritonX-100 in 3% PFA at room temperature. After washing once with PBS, cells were incubated for 1 hour with blocking buffer. Samples were then incubated with primary antibody in blocking buffer overnight. After five washings with 5% BSA in PBS, cells were incubated with secondary antibody for 1 hour. Samples were finally washed three times (1 hour each) in PBS, post-fixed for 2 minutes in 3% PFA and mounted with DAPI-containing Vectashield (Vector Labs Inc., USA).
Wide Field Time-Lapse Microscopy
Cell imaging was performed using an inverted Nikon-Ti wide-field microscope (Nikon, Jaw pan) equipped with an Orca R-2 CCD camera (Hamamatsu Photonics, Japan). After cell seeding, the topographic chip was placed under the microscope in an incubated chamber (Life Imaging Services, Switzerland), where temperature and CO2 concentration were maintained at 37° C. and 5%, respectively. Images were collected with a 20×, 0.45 NA long-distance objective (Plan Fluor, Nikon). Endothelial spreading on topographic substrates in topographic chips was recorded in parallel time-lapse movies for up to 6 different substrates (a flat control and five different gratings). Before starting the experiment, five non-overlapping positions were chosen within each substrate and stored in a position list. Immediately after cell seeding, the experiment was started to automatically acquire a differential interference contrast (DIC) image at each saved position with a time resolution of 1 minute for a total of one or two hours. Focal drift during the experiments was eliminated using the microscope's PFS autofocus system. At the end of the experiment, the resulting time-lapses were converted into a single 8 bit movie for each imaging field under analysis.
Fluorescent movies of CellTracker Green-labelled cells were collected at the cell-substrate interface using a 40×, 1.30 NA oil immersion objective (PlanFluor, Nikon) for a total of one or two hours. Images were collected in both DIC and FITC channels with a time resolution of 1 or 2 minutes.
Fluorescent images of HUVEC expressing vinculin-FRFP or stained with TRITC-phalloidin, VE-Cadherin, or pFAK antibodies were acquired with a 60×, 1.2 NA water immersion objective (PlanApo, Nikon) using a TRITC or FITC filter.
Scanning Electron Microscopy (SEM)
One hour after seeding, cells were fixed with 2.5% glutaraldeyde (Sigma) in sodium cacodylate buffer (pH 7.2, 0.15 M) for 1 hour and successively rinsed three times with sodium cacodylate buffer. 23 Samples were then dehydrated and dried with ethanol absolute at increasing concentrations (50%, 70%, and 98%) and coated with a 20 nm thick gold layer by thermal evaporation. The metal layer was shorted to the SEM sample holder to allow proper electron discharge during imaging. The substrates were then loaded into a LEO 1525 (Carl Zeiss Inc., Germany) field emission SEM and image acquisition was carried out by secondary-electron detection with an Everheart-Thornley detector in order to enhance the topography of cell substrate interfaces.
Image Analysis
Collected movies were loaded into ImageJ (National Institutes of Health, USA) and analyzed as follows: In a first step, movies acquired on patterned substrates were filtered by Fast Fourier Transform (FFT). This procedure eliminates the scattering generated by the gratings. The time to onset of spreading on the respective substrates was then measured for each cell detected within all parallel time-lapses acquired. The time to onset of spreading was individuated by the first frame of the time-lapse (_t=1 minute) in which the cell produces visible membrane protrusions at the cell-substrate-interface. A mean time to onset of spreading was calculated for each substrate under analysis by averaging the values measured for all individual cells. HUVEC alignment to the gratings was measured for all cells detected in the last frame of each recorded movie. The cell profile was manually drawn using the ‘Freehand selection’ tool of ImageJ. The cell area and the cell orientation angle were then obtained respectively using the ‘Area’ and the ‘Fit ellipse’ options in the ‘Measurements’ tool of ImageJ. In the latter case, the obtained value in degrees was normalized relative to the orientation of the grating extracted from the same image. The range of possible alignment angles between cells and gratings is 0° to 90°. Thus a value close to 0° indicates perfect alignment while a value of 45° indicates no alignment.
For the measurements of spreading dynamics, collected fluorescent movies were loaded into ImageJ and the cell profile at the cell-to-substrate interface was manually drawn using the ‘Freehand selection’ tool of ImageJ. The cell area and the cell circularity were then obtained respectively using the ‘Area’ and the ‘Circularity’ options in the ‘Measurements’ tool of ImageJ. The quantitative comparison of spreading dynamics in cells interacting with different substrates was performed by analyzing the central and more active time of spreading during which cells increase their area from 20% to 80% of their eventual maximum area, as reported by Dubin-Thaler et al.
For focal adhesion size measurements, fluorescent images of HUVEC transiently expressing vinculin-FP635 were loaded into ImageJ and the profile of each visible focal adhesion was manually drawn using the “Freehand selection” tool. A value for the focal adhesions size (in μm2) was obtained using the “Measurements” tool. For groove bridging efficiency quantification, SEM images were loaded into ImageJ. The total number of grooves encompassed by the cell as well as the number of membrane arcs bridging over a groove was manually counted for each cell.
Western Blot
For western blot analysis, nine COC surfaces were assembled into a square and surrounded by a Polydimethylsiloxane (PDMS) barrier to create an artificial incubation chamber with an active surface of approximately 9 cm2. After sterilization with ethanol, freshly detached HUVEC (120,000) were seeded onto these artificial wells. After 20 minutes of incubation, medium was removed and lysis buffer was directly added. Lysed cells were then collected by scraping. Cell lysates were analyzed by standard Western blot using antibodies against total FAK and Src proteins and their phosphorylated isoforms. Unsaturated bands on Amersham ECL-Hyperfilms (GE Healthcare, UK) were analyzed using a calibrated densitometer (GS-800, Bio-Rad, USA) and Quantity One software version 4.5.0 (Bio-Rad). Band intensity was quantified using global background subtraction and the ‘Volume Analysis’ tool of Quantity One.
Statistical Analysis
Statistical comparison of average time to onset of spreading and average alignment obtained on different gratings and on control flat substrates was performed using a non-parametric Mann-Whitney test (α=0.05). All quantitative measurements reported are expressed as average values±the standard error of the mean. The total number of events counted is reported in the upper or lower right corner of the presented graphs.
Results
Experimental Setting
In order to prove the biocompatibility of substrates under analysis, the ability of human umbilical vein endothelial cells (HUVEC) to generate a differentiated monolayer on cyclicolefincopolymer (COC) foils was initially assessed. HUVECs proved perfectly viable on all tested substrates and generated a confluent monolayer within 3 days of culture when seeded at high density. These monolayers showed a typical localization of the junctional marker vascular endothelial (VE)-Cadherin at cell-cell contacts, confirming their full differentiation.
In order to investigate the influence of substrate topography on endothelial cell spreading, the projected cell surface was recorded during the entire process for individual cells contacting four different grating types (A-10, A-1, B-10, B-1; Table 1) and compared to what was observed on flat substrates. The graph in
Endothelial Spreading on Textured Surfaces
In order to quantify the effect of surface texture on endothelial spreading, the time to onset of spreading and the final orientation of cells on gratings were measured and compared to those obtained on flat substrates under otherwise identical experimental conditions (
In order to further evaluate endothelial regeneration on the textured substrates, the cell area was quantified at different times after seeding and compared to what was measured in the case of cells contacting flat substrates (
Anisotropic topographies are known to induce the polarization of adherent cells. 16 Contact guidance measures the efficiency of cell-topography-interaction upon spreading. The average cell-to-substrate alignment angles are 6.3±1.3°, 32.5±5°, 18±4.3°, and 34.9±1.3° for substrates A-10, A-1, B-10, and B-1, respectively (
It could be further demonstrated that polarization of the cells along a centre line of the structure is not influenced by the groove depth (
Furthermore, the velocity of wound closure under a simulated blood flow has been studied. It could be demonstrated that a vertical alignment of the grooves and ridges with respect to the blood flow reverses the direction of migration of the cells located at the downstream edge of the wound against the flow. This reversal significant accelerates wound closure as compared to cells grown on non-structured surfaces, where the cell migration of the downstream wound edge is in direction of flow (
In
Spreading Dynamics on Gratings A-10
In order to better understand the effect of surface topography during endothelial spreading, we performed a high-resolution analysis of cells surface and shape dynamics (
The graph in
Effect of Groove Depth
In order to decouple the contribution of groove depth to the effect of substrate A-10 on onset of spreading and contact guidance, five gratings with the same lateral period but increasing groove depths (A-2, A-4, A-6, A-8, A-10, A-15, and A-20; Table 1) were tested (
Scanning electron microscopy images of HUVEC spreading on gratings with lateral period of 2 μm and groove depths ranging from 0.2 to 1 μm (
Focal Adhesion Maturation and Cell-Mediated Contractility
To elucidate the mechanism of interaction between endothelial cells and grating A-10 (
Adhesion maturation requires forces generated by the cell and the mechanical linkage between the actin cytoskeleton and the adhesion site, which are established after the onset of spreading. Hence, the question is whether the measured effect on FA maturation (
To answer this, FA maturation was blocked by the direct inhibition of myosin-II mediated contractility with Blebbistatin or by the selective inhibition of its two major activator kinases (
Integrin Signaling
Finally, we performed a biochemical analysis of the observed effect of gratings A-10 (
Figure Captions of
Discussion
Reactions occurring at the interface between cells and anisotropic topographies either promote or demote the onset of spreading of human endothelial cells (
Onset of Spreading
The mechanism governing mammalian cell spreading on two-dimensional substrates was largely analysed by experimental and theoretical studies. These works revealed that the spreading of mouse fibroblasts on fibronectin-coated glass proceeds through differently regulated phases including early integrin binding and onset of spreading, fast cells spreading, and focal adhesion formation and substrate traction. While the spreading and adhesion dynamics might, to a certain extent, be cell-type and substrate specific, our results for human endothelial cells contacting COC substrates clearly confirm the existence of an early, focal adhesion and contractility independent stage which can be decoupled from later processes by the use of myosin-II inhibitors (
In particular, our data show that the cellular activities leading to onset of spreading are influenced both by the lateral and vertical feature size of the substrate topography (
Contact Guidance
The elongation of cells and their polarization along the direction of gratings (alternating lines of ridges and grooves) was reported for several cellular models, including fibroblasts, neurons, epithelial and endothelial cells. The features size range at which contact guidance is most efficient varies from cell to cell.
In our experimental setup the observation that onset of spreading and contact guidance are differently sensitive to the vertical size of the tested gratings (
Altogether our results support a model in which a topographical modification of the substrate with a specific geometry influences the interaction between endothelial cells and the surface at two different stages: onset of spreading and contact guidance (
We have identified a topographic modification of biocompatible substrates that enhances their endothelialization. Our results demonstrate that the coverage of target surfaces by human endothelial cells is strongly modulated by the lateral and vertical feature size of anisotropic topographies. Early reactions occurring at the interface between cells and grooved surfaces either promote or demote the spreading of endothelial cells. Importantly, by indentifying the cellular machineries which are active at different stages during cell-to-topography interaction, we have discovered two independent phases of this process. While the effect on onset of spreading is mediated by early integrin signaling through Focal Adhesion Kinase, the later interaction during contact guidance depends on ROCK1/2 and myosin-II mediated cell contractility, and on focal adhesion maturation.
In summary, the resulting model paves the way to an improved design of cardiovascular implants yielding a faster and more efficient re-endothelialization.
It will be apparent to those skilled in the art that numerous modifications and variations of the described examples and embodiments are possible in light of the above teaching. The disclosed examples and embodiments are presented for purposes of illustration only. Other alternate embodiments may include some or all of the features disclosed herein. Therefore, it is the intent to cover all such modifications and alternate embodiments as may come within the true scope of this invention.
Number | Date | Country | Kind |
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10 2010 037 194 | Aug 2010 | DE | national |
This invention claims benefit of priority to U.S. patent application Ser. No. 61/377,464 filed Aug. 27, 2010 and German patent application serial no. 10 2010 037 194.7 filed Aug. 27, 2010 the contents of which are herein incorporated by reference in their entirety.
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