The use of patterned dual thermoresponsive surfaces for the collective recovery as co-cultured cell sheets

Heterotypic cell interactions are critical to achieve and maintain specific functions in many tissues and organs. We have focused on patterned structure surfaces to enable co-culture of heterotypic cells and recovery of patterned co-cultured cell sheets for applications in tissue engineering. Thermoresponsive polymers exhibiting different transition temperatures in water comprise both poly(N-isopropylacrylamide) (PIPAAm) and n-butyl methacrylate (BMA) co-grafted as side chains to PIPAAm main chains. These copolymers were surface-grafted in patterns to obtain patterned dual thermoresponsive cell culture surfaces using electron beam polymerisation method and porous metal masks. On patterned surfaces, site-selective adhesion on and growth of rat primary hepatocytes (HCs) and bovine carotid endothelial cells (ECs) allowed patterned co-culture, exploiting hydrophobic/hydrophilic surface chemistry regulated by culture temperature as the sole variable. At 27 degrees C, seeded HCs adhered exclusively onto hydrophobic, dehydrated P(IPAAm-BMA) co-grafted domains (1-mm laser dot), but not onto neighbouring hydrated PIPAAm domains. Sequentially seeded ECs then adhered exclusively to hydrophobised PIPAAm domains upon increasing culture temperature to 37 degrees C, achieving patterned co-cultures. Reducing culture temperature to 20 degrees C promoted hydration of both polymer-grafted domains, permitting release of the co-cultured, patterned cell monolayers as continuous cell sheets with heterotypic cell interactions. Recovered co-cultured cell sheets can be manipulated, moved and sandwiched with other structures, providing new useful constructs both for basic cell biology research and preparation of tissue-mimicking multi-layer materials through overlaying co-cultured cell sheets.     

Thermally responsive polymer-grafted surfaces facilitate patterned cell seeding and co-culture.

Tissue engineering constructs that effectively duplicate natural tissue function must also maintain tissue architectural and organization features, particularly the integration of multiple cell types preserving distinct, integrated phenotypes. Cell-cell communication and biochemical cross-talk have been shown to be essential for the maintenance of differentiated cell functions in tissues and organs. Current limitations of cell-culture hinder progress in understanding the features and dynamics of heterotypic cell communication pathways critical to developing more sophisticated or effective tissue-engineered devices. We describe a method to conveniently electron-beam pattern cell culture surfaces with thermo-responsive polymer chemistry that exploits changes in cell-polymer adhesive interactions over a temperature window amenable for high-throughput cell culture. Cells seeded on these patterned surfaces at 20 degrees C adhere only to surface areas lacking thermo-responsive grafting chemistry; grafted domains at 20 degrees C are hydrophilic and non-cell adhesive. The culture temperature is then increased to 37 degrees C collapsing the hydrated grafted chemistry. A second cell type is added to the culture and adheres only to these exposed relatively hydrophobic grafted patterns. Both cell types can then be effectively co-cultured at 37 degrees C under multiple conditions. Long-term cell pattern fidelity and differentiated cell functions characteristic of each co-planar cell type are observed. This method is simple and has few limitations, compared with other existing co-culture methods.     

Temperature-Responsive surface for novel co-culture systems of hepatocytes with endothelial cells: 2-D patterned and double layered co-cultures

We have developed two novel cell co-culture system, without any on cell type combination limitation, utilizing a polymer surface which is temperature-sensitive with respect to its cell adhesion characteristics. One system involves a patterned co-culture of primary hepatocytes with endothelial cells utilizing patterned masked of the electron-beam cured, temperature-responsive polymer, poly (N-isopropylacrylamide) (PIPAAm) by masked electron beam irradiation. Hepatocytes were cultured to confluency at 37 degrees C on these surfaces. When the culture temperature was reduced below 32 degrees C, cells detached from the PIPAAm-grafted areas without any need for trypsin. Endothelial cells were then seeded onto the same surfaces at 37 degrees C. These subsequently seeded endothelial cells adhered only to the now-exposed PIPAAm-grafted domains and could be co-cultured with the hepatocytes initially seeded at 37 degrees C in well-ordered patterns. The other system involves a double layered co-culture obtained by overlaying endothelial cell sheets of the designed shape onto hepatocyte monolayers. The endothelial cells adhered and proliferated on the PIPAAm-grafted surface, as on polystyrene tissue culture dishes at 37 degrees C. By reducing the temperature, confluent monolayers of cells detached from the PIPAAm surfaces without trypsin. Because the recovered cells maintained intact cell-cell junctions together with deposited extracellular matrix, the harvested endothelial cell sheets, with designed shapes, were transferable and readily adhered to hepatocyte monolayers. Stable double layered cell sheets could be co-cultivated. These two co-culture methods enabled long-term co-culture of primary hepatocytes with endothelial cells. Hepatocytes so co-cultured with endothelial cells maintained their differentiated functions, such as albumin synthesis for unexpectedly long periods. These novel two co-culture systems offer promising techniques for basic biologic researches upon intercellular communications, and for the clinical applications of tissue engineered constructs.     

Immobilization of cell-adhesive peptides to temperature-responsive surfaces facilitates both serum-free cell adhesion and noninvasive cell harvest

We have developed temperature-responsive cell culture surfaces to harvest intact cell sheets for tissue-engineering applications. Both cost and safety issues (e.g., prions, bovine spongiform encephalopathy) are compelling reasons to avoid use of animal-derived materials, including serum, in such culture. In the present study, synthetic cell-adhesive peptides are immobilized onto temperature-responsive polymer-grafted surfaces, and cell adhesion and detachment under serum-free conditions were examined. The temperature-responsive polymer poly(N-isopropylacrylamide) (PI-PAAm) was functionalized by copolymerization with a reactive comonomer having both a carboxyl group and an isopropylacrylamide group. These copolymers were covalently grafted onto tissue culture-grade polystyrene dishes. Synthetic cell-adhesive peptides were then immobilized onto these surfaces via carboxyl groups. Bovine aortic endothelial cells both adhered and spread on these surfaces even under serum-free conditions at 37 degrees C, similar to those in 10% serum-supplemented culture. Spread cells promptly detached from the surfaces on lowering culture temperatures below the lower critical solution temperature of the polymer, 32 degrees C. These surfaces would be useful for serumfree culture for tissue-engineering applications.     

Temperature-responsive glass coverslips with an ultrathin poly(N-isopropylacrylamide) layer

A temperature-responsive cross-linked polymer gel was covalently grafted onto glass coverslips by electron beam irradiation. The grafted thickness and amount of polymer as well as the surface wettability increased with the initial monomer concentration. When the monomer concentration was 5 wt.%, the grafted polymer density was 0.84microgcm(-2), and cells adhered and spread on the surface at 37 degrees C, but detached at 20 degrees C. In contrast, when the monomer concentration was 35 wt.%, the polymer density was 1.28microgcm(-2), and the surfaces were cell repellent even at 37 degrees C. These results show a remarkable contrast to those obtained from temperature-responsive polymer-grafted tissue culture polystyrene dishes, since various types of cells showed temperature-dependent cell adhesion/detachment when the grafted density was around 2microgcm(-2) on these surfaces. We discuss the possible molecular mechanisms underlying this discrepancy.     

Temperature-responsive culture dishes allow nonenzymatic harvest of differentiated Madin-Darby canine kidney (MDCK) cell sheets

We have developed a temperature-responsive culture dish grafted with a poly(N-isopropylacrylamide) (PIPAAm). Various types of cells adhere, spread, and proliferate on the grafted dishes in the presence of serum at 37 degrees C. By reducing only temperature, these cells can be harvested noninvasively from the dishes according to rapid hydration of the grafted polymer. Because the harvest does not need enzymatic digestion, differentiated cell phenotypes are retained. In the present study, a renal epithelial cell line, Madin-Darby canine kidney (MDCK) cell, was cultured on the dishes, and cell behavior was examined. MDCK cells showed differentiated phenotypes such as dome formation during long-term culture, similar to on ungrafted dishes. After 1-week culture at 37 degrees C, trypsin digestion disrupted cell-cell junctions but failed to liberate cells from both ungrafted and grafted dishes. However, short-term incubation at 20 degrees C released confluent MDCK cells as a single contiguous cell sheet only from the polymer-grafted dishes because of selective disruption of the cell-surface binding. Immunocytochemistry with anti-beta-catenin antibody revealed that functional cell-cell junctions were organized even in the recovered cell sheets. Intriguingly, incubation time at 20 degrees C required for cell sheet detachment gradually shortened during long-term culture before reducing temperature. The acceleration of cell detachment was correlated to the decrease of a single cell area by means of cell contractile force. These findings suggest that cell sheet detachment from PIPAAm-grafted dishes should be accomplished by both PIPAAm hydration and cellular metabolic activity such as cell contraction.     

Release of adsorbed fibronectin from temperature-responsive culture surfaces requires cellular activity

We have previously developed a temperature-responsive cell culture surface by grafting poly(N-isopropylacrylamide) that changes its surface hydrophobicity in response to temperature. While this surface shows similar hydrophobicity to that of commercial polystyrene cell culture surfaces and facilitates cell adhesion and proliferation at 37 degrees C, grafted polymer becomes hydrophilic below 32 degrees C and releases spread cultured cells without trypsin. Temperature-regulated cell detachment requires cell metabolic activity requiring ATP consumption, signal transduction, and cytoskeleton reorganziation. Precoating these surfaces with fibronectin (FN) improves spreading of less adhesive cultured hepatocytes and reducing culture temperature releases cultured cells from FN-adsorbed grafted surfaces. Immunostaining with anti-FN antibody revealed that only FN located beneath cultured cells is removed from culture surfaces after reducing temperature. FN adsorbed to surface areas lacking direct cell attachment remained surface-bound after reducing temperature. A novel concept of active cell detachment is also discussed.     

Adhesion behavior of monocytes, macrophages, and foreign body giant cells on poly (N-isopropylacrylamide) temperature-responsive surfaces.

Monocyte and macrophage adhesion and foreign body giant cell (FBGC) formation has been observed on surfaces with a wide range of properties. In this study we have utilized novel, temperature-responsive surfaces (TRS) with dynamic surface properties to investigate inflammatory cell adhesion behavior. With temperature changes, grafted chains of poly-N-isopropylacrylamide pass through their lower critical solution temperature (LCST) and can either extend (hydrate), creating a hydrophilic surface at 20 degrees C, or contract (dehydrate), creating a hydrophobic surface at 37 degrees C. Isolated human monocytes and monocyte-derived macrophages were able to adhere, spread, and form FBGC on the hydrophobic surface. Decreasing the temperature below the lower critical solution temperature induced a change in the surface wettability, creating a hydrophilic surface, that induced a differential detachment of adherent cells that decreased with time, ranging from 98% after 2 h of culture to 30% at day 10. These detached cells remained viable, and were recultured onto TCPS for 3, 7, and 10 days. These novel surfaces allow investigation of the adhesive behavior of adherent inflammatory cells in a temporal manner, and the effects of surface conformation and wettability changes on cell adhesion and detachment.     

Nanofabrication for micropatterned cell arrays by combining electron beam-irradiated polymer grafting and localized laser ablation

Most methods reported for cell-surface patterning are generally based on photolithography and use of silicon or glass substrates with processing analogous to semiconductor manufacturing. Herein, we report a novel method to prepare patterned plastic surfaces to achieve cell arrays by combining homogeneous polymer grafting by electron beam irradiation and localized laser ablation of the grafted polymer. Poly(N-isopropylacrylamide) (PIPAAm) was covalently grafted to surfaces of tissue culture-grade polystyrene dishes. Subsequent ultraviolet ArF excimer laser exposure to limited square areas (sides of 30 or 50 microm) produced patterned ablative photodecomposition of only the surface region (approximately 100-nm depth). Three-dimensional surface profiles showed that these ablated surfaces were as smooth and flat as the original tissue culture-grade polystyrene surfaces. Time-of-flight secondary ion mass spectrometry analysis revealed that the ablated domains exposed basal polystyrene and were surrounded with PIPAAm-grafted chemistry. Before cell seeding, fibronectin was adsorbed selectively onto ablated domains at 20 degrees C, a condition in which the non-ablated grafted PIPAAm matrix remains highly hydrated. Hepatocytes seeded specifically adhered onto the ablated domains adsorbed with fibronectin. Because PIPAAm, inhibits cell adhesion and migration even at 37 degrees C when the grafted density is > 3 microg/cm2, all the cells were confined within the ablated domains. A 100-cell domain array was achieved by this method. This surface modification technique can be utilized for fabrication of cell-based biosensors as well as tissue-engineered constructs.     

Proliferation and bone-related gene expression of osteoblasts grown on hydroxyapatite ceramics sintered at different temperature

Human osteoblast-like cells SaOS-2 (ATCC HTB85) were seeded onto three kinds of hydroxyapatite (HA) ceramics sintered at different temperature (1200 degrees C, 1000 degrees C and 800 degrees C). Scanning electron microscopy (SEM) was conducted to detect the surface microstructure. Cells were cultured on these substrates for 6 and 12 days and cell proliferation rate and mRNA expression for osteocalcin, osteonectin, type I collagen and alkaline phosphatase and protein production for osteocalcin, bone sialoprotein and osteonectin were detected with quantitative in situ hybridization and immunocytochemistry techniques. SEM revealed that crystal particle size was affected by sintering temperature. Result showed that cell proliferation rate on HA ceramics sintered at 1200 degrees C was the highest. Osteonectin and type I collagen mRNA expression was not altered by sintering temperature. After 12 days in culture, bone sialoprotein, osteocalcin and osteonectin proteins levels were significantly (p<0.05) higher when SaOS-2 cells were cultured on HA sintered at 1200 degrees C, compared to the other two surfaces, suggesting that HA sintered at high temperature may be a better candidate for in vivo implantation. This result provides valuable information concerning the clinic application of HA ceramics sintered at different temperature.     

Two-dimensional cell sheet manipulation of heterotypically co-cultured lung cells utilizing temperature-responsive culture dishes results in long-term maintenance of differentiated epithelial cell functions.

Here we report two-dimensional cell sheet manipulation (2D CSM) of heterotypically co-cultured lung cell sheets and the maintenance of differentiated phenotypes of lung epithelial cells over prolonged periods of up to 70 days. This was facilitated by poly(N-isopropylacrylamide) (PIPAAm)-grafted tissue culture dishes. PIPAAm-grafted dishes are responsive to temperature changes and offer a unique surface on which cells adhere and multiply like on ordinary tissue culture dishes under the permissive temperature of 37 degrees C, but on lowering of temperature resulting in changes in hydration of the polymer the cells spontaneously detach from the surface without use of enzymes like trypsin which is the common procedure. It has been well documented that type II pneumocytes of the lung lose many of their special features rapidly in culture. The culture system detailed here comprises random co-culture of epithelial and mesenchymal cells of lung. The heterotypic cell culture system promotes cell-cell interactions maintaining a harmonized physiology. When this heterotypic monolayer on PIPAAm-grafted dishes was subjected to lower temperature of 20 degrees C and 2D CSM we were able to transfer the monolayer as a single contiguous sheet with cell-cell connections intact to other surfaces. This non-invasive transfer of cell sheet resulted in shrinkage of the monolayer, enabling the type II cells to regain their cuboidal morphology and specialized characters like Maclura pomifera lectin binding and surfactant protein A (SP-A) expression. The active dome formation also observed subsequent to transfer reaffirms the uniqueness of the culture conditions and 2D CSM in future for developing tissue like architecture in vitro.     

Signal transduction and cytoskeletal reorganization are required for cell detachment from cell culture surfaces grafted with a temperature-responsive polymer.

We have developed a new cell culture substrate grafted with a temperature-responsive polymer, poly(N-isopropylacrylamide) (PIPAAm) using an electron beam irradiation method. These surfaces are hydrophobic in culture at 37 degrees C due to the hydration/dehydration changes intrinsic to PIPAAm at 32 degrees C, and they become highly hydrophilic below 32 degrees C. At 37 degrees C grafted and ungrafted surfaces showed no difference with regard to attachment, spreading, growth, confluent cell density, and morphology of bovine aortic endothelial cells. Stress fibers, peripheral bands, and focal contacts were established in similar ways. After the medium temperature was decreased to 20 degrees C, spread cells lost their flattened morphology, acquiring a rounded cell appearance similar to that of cells immediately after plating. After mild agitation cells floated free from the dish surface without trypsin treatment. Neither cell morphological changes nor cell detachment occurred on ungrafted surfaces. An ATP synthesis inhibitor, sodium azide, and a tyrosine kinase inhibitor, genistein, suppressed cell morphological changes and cell detachment while a protein synthesis inhibitor, cycloheximide, slightly enhanced cell detachment. An actin filament stabilizer, phalloidin, and its depolymerizer, cytochalasin D, also inhibited cell detachment. These findings suggest that cell detachment on grafted surfaces is mediated by intracellular signal transduction and reorganization of the cytoskeleton. While trypsinization causes damage to the cell membrane surface and extracellular matrix proteins, this alternative low temperature treatment is exceptionally noninvasive. The temperature-responsive cell culture surface also should prove useful for investigating the molecular machinery involved in cell-surface detachment.     

Comparative development of<Emphasis Type="Italic"> Eimeria tenella</Emphasis> (Apicomplexa) in host cells in vitro

Attempts to propagate Eimeria tenella in cell culture over the years have met with limited success. The host cell type is an important parameter in such cultures. This study assessed the ability of different host cell lines to support E. tenella infection in vitro. The initial development in cell lines and the effects of incubation at 37 degrees C and 41 degrees C on the host-parasite relationship was investigated. Eleven cell lines were seeded into 96 well plates and incubated at 37 degrees C in 5% CO(2) to reach confluency. Sporozoites of E. tenella were inoculated into wells and allowed to invade at 37 degrees C and 41 degrees C. Intracellular parasite development was quantified using (3)H-uracil incorporation. All cell lines facilitated parasite invasion and development. The MDBK cell line supported the highest degree of E. tenella development. A time-course study was undertaken to look at this host cell-parasite relationship during infection.     

Regaining chondrocyte phenotype in thermosensitive gel culture

Chondrocyte tissue engineering continues to be a challenging problem. When chondrocytes are duplicated in vitro, it is imperative to obtain an adequate number of cells of optimal phenotype. A temperature-sensitive polymer gel, a copolymer of poly(N-isopropylacrylamide) and acrylic acid (PNiPAAm-co-Aac), has the ability of gelling at 37 degrees C (the lower critical solution temperature, LCST) or above and liquefying below that temperature (Vernon and Gutowska, Macromol. Symp. 1996;109:155-167). The hypothesis of this study was that chondrocytes could (1) duplicate in the copolymer gel; (2) regain their chondrocyte phenotype; and (3) be easily recovered from the gel by simply lowering the temperature below 37 degrees C. Chondrocytes from adult rabbit scapular cartilage were harvested and cultured in a monolayer culture until confluency (approximately 2 weeks). Next, the cells were harvested and seeded into the copolymer gel and cultured for 2-4 weeks. The phenotype of the cultured cells was then characterized. Two groups of control cultures, monolayer and agarose gel, were used to compare their ability to maintain chondrocyte phenotype. The results showed that chondrocytes isolated from rabbit scapula can re-express chondrocyte phenotype in agarose culture and polymer gel culture but not in monolayer culture. Also, cultured chondrocytes can be easily recovered from polymer gel culture by simply lowering the temperature. This new in vitro method of chondrocyte culture is recommended for chondrocyte propagation and regaining chondrocyte phenotype before cell seeding or transplantation.     

The role of SEF14 and SEF17 fimbriae in the adherence of Salmonella enterica serotype Enteritidis to inanimate surfaces

To gain an understanding of the role of fimbriae and flagella in the adherence of Salmonella enterica serotype Enteritidis to inanimate surfaces, the extent of adherence of viable wild-type strains to a polystyrene microtitration plate was determined by a crystal violet staining assay. Elaboration of surface antigens by adherent bacteria was assayed by fimbriae- and flagella-specific ELISAs. Wild-type Enteritidis strains adhered well at 37 degrees C and 25 degrees C when grown in microtitration wells in Colonisation Factor Antigen broth, but not in other media tested. At 37 degrees C, adherent bacteria elaborated copious quantities of SEF14 fimbrial antigen, whereas at 25 degrees C adherent bacteria elaborated copious quantities of SEF17 fimbrial antigen. Non-fimbriate and non-flagellate knock-out mutant strains were also assessed in the adherence assay. Mutant strains unable to elaborate SEF14 and SEF17 fimbriae adhered poorly at 37 degrees C and 25 degrees C, respectively, but adherence was not abolished. Non-motile mutant strains showed reduced adherence whilst type-1, PEF and LPF fimbriae appeared not to contribute to adherence in this assay. These data indicate that SEF17 and SEF14 fimbriae mediate bacterial cell aggregation on inanimate surfaces under appropriate growth conditions.     

Growth factor and matrix molecules preserve cell function on thermally responsive culture surfaces.

Thermally-responsive culture surfaces were designed using copolymers of N-isopropylacrylamide, 4-(aminomethyl)styrene, and acrylic acid. These surfaces contained functional amine and carboxyl groups, which allowed biomolecules to be grafted by amide formation. Epidermal growth factor (EGF), and extracellular matrix (ECM) molecules (collagen type IV, and chondroitin sulfate) were investigated, as surface-grafted biomolecules, for their ability to stimulate cell attachment, proliferation, and function by signaling only from the basal side of cultured cells. Surface analysis of biomolecule-grafted porous inserts showed covalent binding of biomolecules to either amine or carboxyl groups. Multiple attachment to amine and/or carboxyl groups served as cross-linking points that made the polymer hydrogel permanently adherent to the culture surface. Immunofluorescence microscopy techniques gave positive identification of grafted biomolecules. Grafting of EGF improved cell proliferation versus that on nongrafted controls, or controls grafted only with ECM molecules. ECM grafting induced cell attachment on attachment-resistant surfaces. Analysis of trans-epithelial resistance, fluid transport, and polarized g-glutamyl transpeptidase activity indicated that simultaneous grafting of both EGF and ECM produced better polarized cell function than nongrafted controls, or controls grafted with only one type of biomolecule. Covalent grafting of biomolecules did not interfere with cells ability to detach from thermally responsive surfaces upon temperature decrease.     

Thermo-responsive culture dishes allow the intact harvest of multilayered keratinocyte sheets without dispase by reducing temperature

To develop new technology for harvesting transplantable cultured epithelium without dispase treatment, human keratinocytes were plated on culture dishes grafted with a thermo-responsive polymer, poly(N-isopropylacrylamide). The grafted dish surfaces are slightly hydrophobic above 32 degrees C, but reversibly change to hydrophilic below this temperature. According to the method of Rheinwald and Green, keratinocytes proliferated and made a multilayer on the grafted surfaces at 37 degrees C, as on the nongrafted culture dishes. The multilayered keratinocyte sheets were detached from the grafted surfaces only by reducing temperature to 20 degrees C without need for dispase. No cell remnants were observed on the dishes. Such cell sheet detachment was not observed on nongrafted dishes. Immunoblotting of harvested keratinocyte sheets revealed that dispase treatment disrupted E-cadherin and laminin 5, while these molecules remained intact in the keratinocyte sheets harvested by only reducing temperature from the grafted dishes. Transmission electron microscopy revealed that desmosomes were destroyed in dispase treatment but retained in low-temperature treatment. Use of thermo-responsive dishes was examined as a new tool for tissue engineering to achieve the preparation of artificial epithelium for cell transplantation as well as for the investigation of intact multilayered keratinocyte sheets.     

Evidence for a conformational change in human fibronectin which occurs between 4 and 37 degrees C

The effects of temperatures between 4 and 37 degrees C on the structure of human fibronectin (Fn) using monoclonal antibodies (MAb) with specificity for Fn have been studied. Three MAb bound to Fn in solution better at 4 than at 37 degrees C, assessed by both ELISA and immunoprecipitation. These MAb detected temp-dependent conformational changes in Fn which were not associated with a major refolding of the Fn molecule, since the S20,w of Fn and the binding of Fn to polyclonal anti-Fn were unchanged by temp shifts from 4 to 37 degrees C. Fn also was adhered directly to ELISA plates at 4 and at 37 degrees C, and then probed with MAb, with detergents, and with trypsin. One MAb bound better to surface adherent Fn when the Fn had bound to the surface at 4 rather than 37 degrees C. Both SDS and polyoxyethylene (20) sorbitan monolaurate (Tween-20) caused the release of more adherent Fn from surfaces to which it had adhered at 4 degrees C. Finally, trypsin released Fn fragments more rapidly and more completely from surfaces coated at 4 than at 37 degrees C. It is concluded that Fn has different conformations at 4 and 37 degrees C in solution and after adherence to surfaces, as reflected by MAb binding, detergent sensitivity and protease susceptibility. This conformational difference is not associated with alterations in the physiochemical properties of the molecule and is thus a result of a less extensive intramolecular rearrangement than the conformational changes resulting from manipulations of ionic strength or pH, and from binding to collagen or hydrophobic surfaces. Nonetheless, the more subtle conformational change demonstrated here may be important for the biological properties of Fn.     

Control of cell adhesion and detachment using temperature and thermoresponsive copolymer grafted culture surfaces

The hydrophobic monomer, n-butyl methacrylate (BMA) has been incorporated into thermoresponsive poly(N-isopropylacrylamide) (PIPAAm) to lower PIPAAm phase transition temperatures necessary for systematically regulating cell adhesion on and detachment from culture dishes at controlled temperatures. Poly(IPAAm-co-BMA)-grafted dishes were prepared by electron beam irradiation methods, systematically changing BMA content in the feed. Copolymer-grafted surfaces decreased grafted polymer transition temperatures with increasing BMA content as shown by water wettabilities compared to homopolymer PIPAAm-grafted surfaces. Bovine endothelial cells readily adhered and proliferated on copolymer-grafted surfaces above collapse temperature at 37 degrees C, finally reaching confluence. Cell sheet detachment behavior from copolymer-grafted surfaces depended on the culture temperature and BMA content. In conclusion, cell attachment/detachment can be controlled to an arbitrary temperature by varying the content of hydrophobic monomer incorporated into PIPAAm grafted to culture surfaces.     

In vitro study of monocyte viability during the initial adhesion to albumin- and fibrinogen-coated surfaces

Surface adherent monocytes and macrophages play a central role in the inflammatory response to biomaterials. In the present study the adhesion, viability and apoptotic changes in material surface adherent monocytes during the first hours of cell-surface interactions in vitro were studied, using tissue culture polystyrene surfaces coated with human albumin and fibrinogen. Human peripheral blood monocytes were enriched by a two-step gradient centrifugation and resuspended (1 x 10(6)/ml) in RPMI with 10% fetal bovine serum. The cells were added to polystyrene surfaces coated with human fibrinogen or albumin and incubated in 37 degrees C (5% CO2, 100% humidity) for 30 min, 1, 2, 3 and 24 h. The adherent cells were stained for early apoptotic changes (exposed phosphatidylserine) and cell death using Annexin-V-fluorescein and propidium iodide staining, respectively. A bi-phasic adhesion was observed on the fibrinogen coated surface, having the highest number of adherent cells after 30 min and 24 h, while the cell number was markedly reduced after 1-3 h. The number of adherent cells on albumin was relatively low after all short time incubations but had reached a high level after 24 h.The number of adherent dead cells was highest after I h on both albumin (approximately 30%) and fibrinogen (approximately 15%). In the 24 h cultures, the viability of adherent cells was high on both surfaces (95-100%). Viable cells staining positive for early apoptotic changes could only be clearly observed on the albumin coated surface, after 30 min of cell-material surface interaction. Cell death, including apoptotic death, thus seems to play an important role during the initial interactions between monocytes and a foreign surface.