The influence of functional groups of self-assembled monolayers on fibrous capsule formation and cell recruitment

The contribution of the surface chemistry of an implant to the thickness of the fibrous capsule formed after implantation was herein investigated. For that, self-assembled monolayers (SAMs) of alkanethiols on gold with different terminal functional groups (COOH, OH, and CH(3)) were used. These surfaces were implanted in subcutaneous air pouches of BALB/c mice and the ensuing fibrous capsules were evaluated and compared with the initial inflammatory response caused by the implant. The thickness of the fibrous capsules that are under organization around the implant was measured 1 week after implantation by histology. Inflammatory exudates were collected from the air pouches 24 h after the implantation of SAMs and were analyzed by flow cytometry. A significant increase in the thickness of fibrous capsules was seen around implanted CH(3)-terminated SAMs, and also in gold surfaces, in comparison with the air pouch wall of sham-operated mice and of COOH- and OH-covered SAMs. The CH(3)-coated implants also recruited higher numbers of inflammatory cells; this enhancement involved a significant number of Mac-1(+) cells. Our data indicate that implant surfaces coated with CH(3) induce thick fibrous capsules and this may be the result of the stronger inflammatory effect of CH(3) in comparison with COOH or OH chemical groups.     

The attraction of Mac-1+ phagocytes during acute inflammation by methyl-coated self-assembled monolayers

We have used self-assembled monolayers (SAMs) of alkanethiolates on gold to study the contribution of methyl terminal functional groups in implant-triggered inflammation. The CH3-coated biomaterials were inserted in an air-pouch cavity of the BALB/c mouse and the in situ inflammatory response was monitored 4, 24, 48 and 72 h later. Flow cytometry was applied to define surface expression of the adhesion receptor Mac-1 (CD11b/CD18), a marker of activated leukocytes, and also of CD3 and B220 antigens (T and B lymphocytes). The CH3-coated surfaces caused a significant enhancement in the number of Mac-1+ cells in the implant. The only significant change in T and B lymphocytes was a transient increase in T cells detected 48 h after the implantation. Peak numbers of Mac-1+ phagocytes were observed 24 h after implantation. We conclude that if CH3 is present at the surface of implants, this chemical group will trigger a significant enhancement of activated phagocytes involved in the inflammatory reaction, and this phenomenon may extend the local phlogistic event.     

Leukocyte adhesion on model surfaces under flow: effects of surface chemistry, protein adsorption, and shear rate

The effect of specific chemical functionalities on the adhesion of polymorphonuclear leukocytes (PMNs) under flow was investigated using a set of well-characterized, chemically functionalized surfaces prepared by self-assembly of alkanethiolate monolayers on gold surfaces. Terminal functionalities included CH(3), CH(2)OH, COOH, and (OCH(2)CH(2))(3)OH groups. A new surface modification was used to incorporate a phosphorylcholine moiety on the hydroxyl-terminated monolayer. Surface modification was verified using contact-angle measurements, ellipsometry, and X-ray photoelectron spectroscopy. Adhesion on the surfaces was studied in the presence and absence of pre-adsorbed fibrinogen. Fibrinogen adsorption on self-assembled monolayers (SAMs) was quantified using radioisotope detection. PMN adhesion was found to be dependent on the monolayer's terminal functionality. Adhesion was higher on the hydrophobic CH(3) surface and the polar COOH monolayer. Leukocyte adhesion was least on the phosphorylcholine-rich surface, followed by the ethylene-oxide-containing monolayer. Cell adhesion also was low on the hydrophilic OH monolayer. Attachment was decreased with increasing shear rate, exhibiting a three-fold decrease between 20 and 100 s(-1). Fibrinogen adsorption was higher on the CH(3) monolayer but comparable for the other four SAMs. Preincubation of the surfaces with fibrinogen decreased adhesion on all SAMs examined.     

Effect of wettability and surface functional groups on protein adsorption and cell adhesion using well-defined mixed self-assembled monolayers

Self-assembled monolayers (SAMs) of alkanethiols, which can provide flat and chemically well-defined surfaces, were employed as model surfaces to understand cellular interaction with artificial materials. SAMs presenting a wide range of wettabilities were prepared by mixing two kinds of alkanethiols carrying terminal methyl (CH(3)), hydroxyl (OH), carboxylic acid (COOH), or amino (NH(2)) groups. Adhesion behavior of human umbilical vein endothelial cells (HUVECs) and HeLa cells on these mixed SAMs were examined. The number of adhered HUVECs reached a maximum on CH(3)/OH mixed SAMs with a water contact angle of 40 degrees , while cell adhesion increased with decreasing water contact angle up to 60-70 degrees and then leveled off on CH(3)/COOH and CH(3)/NH(2) mixed SAMs. Numbers of adhered HeLa cells showed a maximum on CH(3)/OH and CH(3)/COOH mixed SAMs with a water contact angle of 50 degrees . These facts suggest that cell adhesion is mainly determined by surface wettability, but is also affected by the surface functional group, its surface density, and the kinds of cells. The effect of exchange of adsorbed proteins on cell adhesion was also examined. HUVECs were cultured on the mixed SAMs preadsorbed with albumin. Cell adhesion was effectively prohibited on hydrophobic SAMs pretreated with albumin. Albumin strongly adsorbed and resisted replacement by cell adhesive proteins on hydrophobic SAMs. On the other hand, cells adhered to albumin-adsorbed hydrophilic SAMs. Displacement of preadsorbed albumin with cell adhesive proteins effectively occurs on these hydrophilic SAMs. This effect contributes to induce SAMs with moderate wettability to give suitable surfaces for cell adhesion.     

Fibrinogen adsorption, platelet adhesion and activation on mixed hydroxyl-/methyl-terminated self-assembled monolayers

The effect of surface wettability on fibrinogen adsorption, platelet adhesion and platelet activation was investigated using self-assembled monolayers (SAMs) containing different ratios of longer chain methyl- and shorter chain hydroxyl-terminated alkanethiols (C15CH3 vs. C11OH) on gold. Protein adsorption studies were performed using radiolabeled human fibrinogen (HFG). Platelet adhesion and activation studies with and without pre-adsorbed fibrinogen, albumin and plasma were assessed using scanning electron microscopy (SEM) and a glutaraldehyde-induced fluorescence technique (GIFT). Results demonstrated a linear decrease of HFG adsorption with the increase of OH groups on the monolayer (increase of the hydrophilicity). Platelet adhesion and activation also decrease with increase of hydrophilicity of surface. Concerning SAMs pre-immersed in proteins, fibrinogen adsorption was related with high platelet adhesion and activation. The passivant effect of albumin on platelet adhesion and activation was only demonstrated on SAMs contained C11OH. When all the blood proteins are present (plasma) platelet adhesion was almost absent on SAMs with 65% and 100% C11OH. This could be explained by the higher albumin affinity of the SAMs with 65% C11OH and the lower total protein adsorption associated with SAMs with 100% C11OH.     

Surface chemistry modulates fibronectin conformation and directs integrin binding and specificity to control cell adhesion

Integrin-mediated cell adhesion to proteins adsorbed onto synthetic surfaces anchors cells and triggers signals that direct cell function. In the case of fibronectin (Fn), adsorption onto substrates of varying properties alters its conformation/structure and its ability to support cell adhesion. In the present study, self-assembled monolayers (SAMs) of alkanethiols on gold were used as model surfaces to investigate the effects of surface chemistry on Fn adsorption, integrin binding, and cell adhesion. SAMs presenting terminal CH(3), OH, COOH, and NH(2) functionalities modulated adsorbed Fn conformation as determined through differences in the binding affinities of monoclonal antibodies raised against the central cell-binding domain (OH > COOH = NH(2) > CH(3)). Binding of alpha(5)beta(1) integrin to adsorbed Fn was controlled by SAM surface chemistry in a manner consistent with antibody binding (OH > COOH = NH(2) > CH(3)), whereas alpha(V) integrin binding followed the trend: COOH > OH = NH(2) = CH(3), demonstrating alpha(5)beta(1) integrin specificity for Fn adsorbed onto the NH(2) and OH SAMs. Cell adhesion strength to Fn-coated SAMs correlated with alpha(5)beta(1) integrin binding (OH > COOH = NH(2) > CH(3)), and experiments with function-perturbing antibodies demonstrated that this receptor provides the dominant adhesion mechanism in this cell model. This work establishes an experimental framework to analyze adhesive mechanisms controlling cell-surface interactions and provides a general strategy of surface-directed control of adsorbed protein activity to manipulate cell function in biomaterial and biotechnological applications.     

Adhesion of human leukocytes to biomaterials: an in vitro study using alkanethiolate monolayers with different chemically functionalized surfaces

The adhesion of human leukocytes to self-assembled monolayers of well-defined surface chemistry was investigated in vitro. Polymorphonuclear (PMN) and mononuclear leukocytes were isolated from human blood by centrifugation techniques. The effect on adhesion of cell activation produced by pre-incubation of leukocytes with phytohemagglutinin (PHA) and phorbol 12-myristate 13-acetate (PMA) was also studied. Gold substrates were modified by treatment with alkanethiols with three different terminal chemical groups: COOH, OH, and CH(3). After incubation with the two subpopulations of leukocytes, the monolayers were washed, treated with fixative, stained with a Giemsa method, and observed by light microscopy to quantify the number of attached leukocytes. Comparative quantification of the density of leukocyte adhesion to the three types of self-assembled monolayers was determined. The hydrophobic surface expressing CH(3) was found to be the one that induced the highest adhesion density of leukocytes, both of PMN and mononuclear cells. In vitro activation of both mononuclear and PMN leukocytes further increased cell adhesion to the chemically defined monolayers that were used. This enhancement was higher for PHA-activated than for PMA-stimulated mononuclear cells, whereas PMA treatment of neutrophils resulted in a higher rate of adhesion of these cells than PHA stimulation.     

Susceptibility of cartilage to damage by immunological inflammation

Injection of ovalbumin into subcutaneous air pouches prepared on the backs of rats previously sensitised to the antigen resulted in the induction of a small and transient accumulation of inflammatory fluid with a predominantly polymorph cell infiltrate. Challenge of pouches of appropriately sensitised rats with Bordetella pertussis vaccine, on the other hand, resulted in a larger and more prolonged accumulation of fluid and cells with a predominantly mononuclear presence. When intact homologous femoral head cartilage was implanted in these inflamed pouches proteoglycan loss was found to be not different from similar implants in non-inflamed pouches. Coating the cartilage with human heat-aggregated immunoglobulin G prior to implantation in air pouches was also found to be without effect on subsequent proteoglycan loss.     

Rabbit leukocyte adhesion molecules CD11/CD18 and their participation in acute and delayed inflammatory responses and leukocyte distribution in vivo

In humans the glycoprotein complexes CD11/CD18 mediate leukocyte adhesion to cells. Mouse monoclonal antibodies (mAb) 60.3, 7E4, and IB4 to human CD18, found to cross-react with rabbit white blood cells, were used to identify the antigen in rabbit cells and to study adherence of rabbit leukocytes in vitro and in vivo. These antibodies labeled almost all unfractionated rabbit blood leukocytes and immunoprecipitated surface glycopolypeptides with apparent molecular weights of 85,000 and 150,000 from these cells. Adhesion of purified rabbit polymorphonuclear cells (PMNs) to cultured vascular endothelial cells in the presence of phorbol ester was blocked by the antibodies in a dose-dependent manner. The acute inflammatory response characterized by local accumulation of PMNs and concomitant plasma extravasation following intradermal injections of zymosan-activated serum (ZAS) in rabbits was inhibited in animals pretreated intravenously with anti-CD18 mAb. Intravital microscopy of the rabbit tenuissimus muscle demonstrated that anti-CD18 mAb. Intravital microscopy of the rabbit tenuissimus muscle demonstrated that anti-CD18 treatment specifically blocked the adhesion of activated leukocytes to the venular endothelium and thereby the subsequent diapedesis of these cells into the extravascular space. The lymphocyte-dependent tissue swelling resulting from a delayed-type hypersensitivity reaction in the rabbit ear was partially inhibited by anti-CD18 mAb. Systemic anti-CD18 treatment induced a pronounced increase in the number of circulating mononuclear and polymorphonuclear cells with a maximum at 24 hr after injection of the antibody. It is concluded that GP150/GP85 is the rabbit homologue of human CD11/CD18, and that leukocyte-cell adhesion mediated by these glycoprotein complexes participates in acute and delayed inflammatory responses and leukocyte distribution in vivo.     

The effect of adsorbed fibronectin and osteopontin on macrophage adhesion and morphology on hydrophilic and hydrophobic model surfaces

Macrophages play a crucial role in the host response to biomaterials. Here we investigated the effect of adsorbed fibronectin (FN) and osteopontin (OPN), two important proteins for tissue repair, on macrophage adhesion and morphology. Since cell-biomaterial interactions are modulated via proteins adsorbed onto biomaterial surfaces, FN and OPN were adsorbed on model self-assembled monolayers (SAMs) of alkanethiols on gold with different functional terminal groups (CH(3), OH and tetra(ethylene-glycol)). The initial interaction of inflammatory cells with a biomaterial is crucial for the ensuing phases of an inflammatory reaction. For this reason short-term cultures of primary human macrophages were performed. To account for the competitive adsorption of other proteins serum was added to the culture medium and the effect compared with serum-free medium cultures. In the presence of serum hydrophilic surfaces increased macrophage adhesion. In particular, FN induced a higher cell density, while OPN tended to decrease it. In serum-free medium cell adhesion was greater on hydrophobic surfaces, except for OPN-coated SAMs. Importantly, FN no longer enhanced macrophage adhesion, while OPN maintained its inhibitory effect. Cell polarization studies indicated that macrophage morphology variations induced by surface chemistry are overcome by pre-adsorbed OPN. Taken together our results show that in the presence of serum macrophage adhesion is promoted by FN hydrophilic surfaces, but impaired on OPN-coated surfaces. The effects of inhibited macrophage adhesion on macrophage fusion, and its relevance to the initial stages of the inflammatory response to biomaterials are discussed.     

Self-assembled monolayers with different terminating groups as model substrates for cell adhesion studies

Cell shapes induced by cell-substratum interactions are linked with proliferation, differentiation or apoptosis of cells. To clarify the relevance of specific surface characteristics, we applied self-assembled monolayers (SAM) of alkyl silanes exhibiting a variety of terminating functional groups. We first characterised the SAMs on glass or silicon wafers by measuring wettability, layer thickness and roughness. Water contact angle data revealed that methyl (CH(3)), bromine (Br), and vinyl (CH=CH(2)) groups lead to hydrophobic surfaces, while amine (NH(2)) and carboxyl (COOH) functions lead to moderately wettable surfaces, and polyethylene glycol (PEG) and hydroxyl (OH) groups created wettable substrata. The surfaces were found to be molecular smooth except for one type of NH(2) surface. The SDS-PAGE analysis of proteins adsorbed from bovine serum to the SAMs showed less protein adsorption to PEG and OH than to CH(3), NH(2) and COOH. Immunoblotting revealed that a key component of adsorbed proteins is vitronectin while fibronectin was not detectable. The interaction of human fibroblasts with CH(3), PEG and OH terminated SAMs was similarly weak while strong attachment, spreading, fibronectin matrix formation and growth were observed on COOH and NH(2). The strong interaction of fibroblasts with the latter SAMs was linked to an enhanced activity of integrins as observed after antibody-tagging of living cells.     

Protein adsorption and human osteoblast-like cell attachment and growth on alkylthiol on gold self-assembled monolayers.

Protein adsorption and growth of primary human osteoblasts on self-assembled monolayers of alkylthiols on gold (SAMs) with carboxylic acid and hydroxyl and methyl termini were investigated. Single-component SAMs and SAMs patterned by photolithographic techniques were used. Cell growth on patterned SAMs demonstrated preferences for one pattern region in all combinations of alkylthiols, with the hierarchical preference COOH > OH > CH(3). Patterned SAMs and immunochemistry were used to investigate adsorption of fibronectin and albumin with respect to different alkylthiol termini. Fibronectin adsorption from both pure solution and serum containing cell culture medium (SDMEM) followed the sequence COOH > OH > CH(3). Albumin adsorption from pure solution followed the sequence OH > COOH > CH(3); from SDMEM the sequence was CH(3) > OH > COOH. Cell attachment to SAMs with the above termini, after preadsorption with fibronectin, albumin, or mixtures of fibronectin and albumin, was measured. Attachment was maximal on COOH-terminated SAMs precoated with fibronectin. Attachment to COOH was significantly reduced only when fibronectin was omitted from the protein preadsorption solution. On OH and CH(3) SAMs increasing the proportion of albumin in the solution was sufficient to significantly reduce cell attachment. The distribution vinculin and the integrins alpha(5)beta(1) and alpha(v)beta(3) indicated that focal contact formation by cells varied with alkylthiol termini in the following sequence: COOH > OH > CH(3).     

Alpha-fetoprotein (AFP) in granulomatous inflammation of the mouse

Inflammatory granulomas constituted of various proportions of macrophages, polynuclear (PMNs) and mononuclear cells were induced in adult pathogen-free mice by injecting polyacrylamide beads into subcutaneous pouches. Using specific anti-mouse alpha-fetoprotein (AFP) antibodies, the presence of AFP was immunocytochemically demonstrated in the cytoplasm of macrophages and of immature PMNs (mature PMNs and mononuclear cells were AFP negative). AFP-labelling started as soon as 36 h after granuloma induction and reached a maximum 60-72 h later, to disappear on day 5. The examination of different organs in these mice also showed a transitory labelling for AFP of liver hepatocytes and of elements of kidney and of exocrine pancreas. Parallel to these findings, the selective concentration inside the granulomatous pouches of radiolabelled AFP injected in the course of inflammation was observed. These results suggest that (a) shortly after the inflammatory reaction the synthesis of AFP is resumed by the liver; (b) the newly synthesized AFP is secreted in the serum and preferentially taken up by the granulomas; and (c) consequently, in adult mice, AFP behaves as a positive acute phase reactant. The physiopathological implications of these facts are discussed in relation with the biological properties of AFP.     

Alpha-fetoprotein (AFP) in granulomatous inflammation of the mouse.

Inflammatory granulomas constituted of various proportions of macrophages, polynuclear (PMNs) and mononuclear cells were induced in adult pathogen-free mice by injecting polyacrylamide beads into subcutaneous pouches. Using specific anti-mouse alpha-fetoprotein (AFP) antibodies, the presence of AFP was immunocytochemically demonstrated in the cytoplasm of macrophages and of immature PMNs (mature PMNs and mononuclear cells were AFP negative). AFP-labelling started as soon as 36 h after granuloma induction and reached a maximum 60-72 h later, to disappear on day 5. The examination of different organs in these mice also showed a transitory labelling for AFP of liver hepatocytes and of elements of kidney and of exocrine pancreas. Parallel to these findings, the selective concentration inside the granulomatous pouches of radiolabelled AFP injected in the course of inflammation was observed. These results suggest that (a) shortly after the inflammatory reaction the synthesis of AFP is resumed by the liver; (b) the newly synthesized AFP is secreted in the serum and preferentially taken up by the granulomas; and (c) consequently, in adult mice, AFP behaves as a positive acute phase reactant. The physiopathological implications of these facts are discussed in relation with the biological properties of AFP.     

Effect of surface chemistry on bacterial adhesion, viability, and morphology

Helicobacter pylori (H. pylori) is one of the most common infectious agents in the world and it is thought to colonize the gastric mucosa of about half of the world's population causing several gastric diseases. In this work, the effect of surface chemistry on H. pylori nonspecific adhesion, viability, and morphology was evaluated using three H. pylori strains with different adhesins expression profile. Self-assembled monolayers (SAMs) of alkanethiols on gold were used to obtain surfaces exposing different functional groups: OH, CH3, and ethylene glycol (EG4). Bacterial adhesion onto the surfaces reached a plateau at 2 h. There was a correlation between adhesion and the exposed surface group, with bacterial cells adhering preferentially to CH3-SAMs while EG4-SAMs prevented H. pylori adhesion during the entire adhesion test (24 h). Surfaces that presented the EG4 group were also the only ones that significantly reduced the viability of adhered bacteria. Surface chemistry also influenced the morphology of adhered bacteria. The H. pylori rod shape observed in the control (Tissue Culture Polyethylene-TCPE) was only retrieved on CH3-SAMs. This work demonstrates that surface chemistry, namely specific functional groups on the material, influence the nonspecific adsorption of H. pylori. Moreover, the features of the bacterial strain and the surface chemistry can alter the adhesion kinetics, as well as the morphology and viability of attached bacteria.     

Impaired microtubule function correctable by cyclic GMP and cholinergic agonists in the Chediak-Higashi syndrome.

The Chediak-Higashi (CH) syndrome of man and several animal species is characterized by the presence of abnormal giant granules in all granule-containing cells and by defects in chemotaxis and lysosomal degranulation during phagocytosis in polymorphonuclear leukocytes (PMNs). Since similar functional abnormalities have been reported in normal PMNs following exposure to colchicine and other agents that disrupt microtubles it was proposed that microtubule function may be impaired in the CH syndrome. The mobility of concanavalin A (con A)-receptor complexes on PMN membranes was used to test microtubule integrity. Normal PMNs showed a uniform distribution of membrane-bound con A. By contrast, con A was aggregated into surface caps on both colchicine-treated normal PMNs and untreated PMNs from mice and a patient with CH syndrome. This result is consistent with impaired microtubule function in the CH cells. The spontaneous capping response of CH PMNs was inhibited by cyclic GMP and by cholinergic agonists that can elevate cyclic GMP levels in neutrophils. This raised the possibility that the microtubule defect in CH cells may be correctable by treatments that increase cyclic GMP generation. Direct evidence for both the absence of microtubule assembly in con A-treated PMNs from the CH patient and for normal microtubule assembly in CH PMNs incubated with cyclic GMP and cholinergic agonists prior to con A treatment was obtained by electron microscopy. In addition, evidence for a direct relationship between the microtubule defect and the development of giant lysosomes in CH cells was obtained. Thus, CH fibroblasts grown in vitro developed abnormal lysosomes in the majority of cells. However, the same cells cultured in the presence of cholinergic agonists developed a majority of lysosomes that were morphologically normal at the level of the light microscope. Similarly, granule morphology appeared normal in peripheral blood leukocytes from mice treated chronically in vivo with cholinergic agonists.     

Degradation of cartilage in contact with soft tissue

Observations have been made on histological changes in femoral-head articular cartilage transplanted into soft tissue in rats under a variety of conditions. Articular cartilage was implanted either whole or minced. Implants were made into deflated subcutaneous air pouches with or without an inflammatory irritant and into normal subcutaneous tissue. Cartilage-matrix loss occurred in four patterns: marginal zone encroachment, loss of metachromatic staining without loss of tissue mass, surface invasion and lacunar enlargement and coalescence. The presence of an inflammatory reaction had no discernible effect on loss of cartilage matrix. Changes at the marginal zone preceded changes at the centre. Loss of metachromatic staining without loss of tissue mass occurred in areas of chondrocyte death. Surface invasion was not affected by the viability of the underlying chondrocytes. Surface invasion occurred earliest in cartilage transplanted into subcutaneous tissue, and latest in cartilage implanted into air pouches inflamed with carrageenan. The onset of surface invasion appeared to be dependent on soft-tissue adhesion to the cartilage surface. Mincing of cartilage was associated with an increase in surface invasion in the deeper cartilage zone with large lacunae but not in the superficial zone with small lacunae. Occasional cut surfaces showed outgrowth of new cartilage matrix. These observations on artefactual modes of cartilage degradation may assist in analysing the critical steps in cartilage degradation in arthritic joints.     

The effect of non-specific interactions on cellular adhesion using model surfaces

The contribution of non-specific interactions between cells and model functional surfaces was measured using a spinning disc apparatus. These model functional surfaces were created using self-assembled monolayers (SAM) of alkylsilanes terminated with epoxide, carboxyl (COOH), amine (NH(2)), and methyl (CH(3)) groups. These SAMs were characterized using ellipsometry, atomic force microscopy, contact angle goniometry, and X-ray photoelectron spectroscopy to confirm the presence of well-formed monolayers of expected physicochemical characteristics. All substrates also demonstrated excellent stability under prolonged exposure (up to 18 h) to aqueous conditions. The adhesion strength of K100 erythroleukemia cells to the functional substrates followed the trend: CH(3) < COOH approximately epoxide < NH(2). The NH(2) SAM surface exhibited nearly an order of magnitude greater adhesion strength than the other SAMs and this non-specific effect exceeded the adhesion measured when RGD tri-peptides were also immobilized on the surface. These findings illustrate the importance of substrate selection in quantitative studies of peptide-mediated cellular adhesion.     

Effect of biomaterial surface properties on fibronectin-alpha5beta1 integrin interaction and cellular attachment

The ability of fibronectin (Fn) to mediate cell adhesion through binding to alpha(5)beta(1) integrins is dependent on the conditions of its adsorption to the surface. Using a model system of alkylsilane SAMs with different functional groups (X=OH, COOH, NH(2) and CH(3)) and an erythroleukemia cell line expressing a single integrin (alpha(5)beta(1)), the effect of surface properties on the cellular adhesion with adsorbed Fn layers was investigated. (125)I-labeled Fn, a modified biochemical cross-linking/extraction technique and a spinning disc apparatus were combined to quantify the Fn adsorption, integrin binding and adhesion strength, respectively. This methodology allows for a binding equilibrium analysis that more closely reflects cellular adhesion found in stable tissue constructs in vivo. Differences in detachment strength and integrin binding were explained in terms of changes in the adhesion constant (psi, related to affinity) and binding efficiency of the adsorbed Fn for the alpha(5)beta(1) integrins (CH(3) approximately NH(2)相似文献   

Effects of supernatants and lysates of polymorphonuclear leukocytes--lymphocyte mitogenic factors

Rat polymorphonuclear leukocytes (PMNs), harvested from the site of a non-specific acute inflammatory reaction, liberated into culture fluids factors which not only enhanced the phytohaemagglutinin-induced proliferative response of thymocytes and lymph node cells, but were also mitogenic for these cells. This activity was associated with low molecular weight molecules (less than 10,000 daltons) and both these activities were also found in lysates of these PMNs. Our results suggest that inflammatory PMNs both contain and are able to release low molecular weight factors which can modulate lymphocyte function.