Short collagen fibers provide control of contraction and permeability in fibroblast-seeded collagen gels.

Tissue engineering may allow for the reconstruction of breast, facial, skin, and other soft tissue defects in the human body. Cell-seeded collagen gels are a logical choice for creating soft tissues because they are biodegradable, mimic the natural tissue, and provide a three-dimensional environment for the cells. The main drawback associated with this approach, however, is the subsequent contraction of the gel by the constituent cells, which severely reduces permeability, initiates apoptosis, and precludes control of the resulting shape and size of the construct. In this study, type I collagen gels were seeded with fibroblasts and cast either with or without the addition of short collagen fibers. Gel contraction was monitored and permeability was assessed after 7 and 14 days in culture. The addition of short collagen fibers both significantly limited contraction and increased permeability of fibroblast-seeded collagen gels. The addition of short collagen fibers had no detrimental effect on cell proliferation, and there were a high number of viable fibroblasts in gels with fibers and gels without fibers. Gels containing short collagen fibers demonstrated permeabilities that were 100 to 1000 times greater than controls and also closely maintained their casting dimensions (never less than 96% of original). By limiting contraction and maintaining permeability, the incorporation of short collagen fibers should enable the creation of larger constructs by allowing for greater nutrient diffusion, and permit the creation of more complicated shapes during gel casting.

Examination of continuum and micro-structural properties of human vertebral cancellous bone using combined cellular solid models.

Two- and three-dimensional structural models of the vertebral body have been used to estimate the mechanical importance of parameters that are difficult to quantify experimentally such as lattice disorder, trabecular thickness, trabecular spacing, connectivity, and fabric. Many of the models that investigate structure-function relationships of the vertebral body focus only on the trabecular architecture and neglect solid-fluid interactions. We developed a cellular solid model composed of two idealized unit cell geometries to investigate the continuum and micro-structural properties of human vertebral cancellous bone in a mathematically tractable model. Using existing histomorphological data we developed structure-function relationships for the mechanical properties of the solid phase, estimated the micro-structural strains, and predicted the fluid flow characteristics. We found that the micro-structural strains may be 1.7 to 2.2 times higher than the continuum level strains between the ages of 40 and 80. In addition, the predicted permeability agrees well with the experimental data.

Endothelial cell migration on surfaces modified with immobilized adhesive peptides.

Endothelial cell (EC) migration has been studied on aminophase surfaces with covalently bound RGDS and YIGSRG cell adhesion peptides. The fluorescent marker dansyl chloride was used to quantify the spatial distribution of the peptides on the modified surfaces. Peptides appeared to be distributed in uniformly dispersed large clusters separated by areas of lower peptide concentrations. We employed digital time-lapse video microscopy and image analysis to monitor EC migration on the modified surfaces and to reconstruct the cell trajectories. The persistent random walk model was then applied to analyze the cell displacement data and compute the mean root square speed, the persistence time, and the random motility coefficient of EC. We also calculated the time-averaged speed of cell locomotion. No differences in the speed of cell locomotion on the various substrates were noted. Immobilization of the cell adhesion peptides (RGDS and YIGSRG), however, significantly increased the persistence of cell movement and, thus, the random motility coefficient. These results suggest that immobilization of cell adhesion peptides on the surface of implantable biomaterials may lead to enhanced endothelization rates.

An assessment of the strength of NG108-15 cell adhesion to chemically modified surfaces.

The strength of adhesion of NG108-15 cells to glass substrates modified with adsorbed proteins (laminin and poly-ornithine) or modified with covalently bound peptides (tri-ornithine and Tyr-Ile-Gly-Ser-Arg) was quantitatively assessed, by determining the shear stresses necessary to denude the cells from substrates using a spinning disk device. The shear stresses required to detach NG108-15 cells from glass modified with either adsorbed poly-ornithine or with both poly-ornithine and laminin were significantly (P < 0.05) higher than the shear stresses required to detach the cells from plain glass substrates. Covalent surface modifications resulted in higher strengths of NG108-15 adhesion than were exhibited on surfaces modified with adsorbed proteins. NG108-15 cell adhesion strength was maximal on surfaces covalently modified with only amine groups (without any peptides or proteins). These results indicate that general (i.e., not necessarily receptor-specific) surface modification strategies, which increase the net surface charge of a substrate, will elicit strong adhesion of NG108-15 cells.

Osteoblast population migration characteristics on substrates modified with immobilized adhesive peptides.

The process of cell migration is inextricably linked with the process of cell adhesion and, therefore, with cell/substrate adhesiveness. The present study adapted an under-agarose cell migration assay to quantitatively examine population migration characteristics of osteoblasts, on substrates modified with adhesive peptides, in the absence and presence of growth factors. Short-term, that is, 48 h osteoblast migration distances on substrates modified with adhesive Arg-Gly-Asp-Ser peptides were significantly (P < 0.05) less than migration distances on substrates modified with non-adhesive Arg-Asp-Gly-Ser peptides, demonstrating that osteoblast population haptokinesis was significantly decreased on substrates modified with adhesive peptides. Random motility coefficients calculated in the present study for osteoblast populations were an order of magnitude lower than a published random motility coefficient for leukocytes, proving quantitatively that, compared to leukocytes, osteoblasts migrate via haptokinesis more slowly. The 48 and 72 h osteoblast population migration differentials in the presence of an initial mass of 60 ng of basic Fibroblast Growth Factor, on substrates modified with Arg-Gly-Asp-Ser or with Arg-Asp-Gly-Ser, were larger than all other chemotactic differentials on these substrates. Quantitative investigations (such as the present study) of cell population migration characteristics on model biomaterial surfaces will become increasingly necessary as the discipline of cell/tissue engineering matures.

Design and function of novel osteoblast-adhesive peptides for chemical modification of biomaterials.

Proactive, "next generation" dental/orthopedic biomaterials must be designed rationally to elicit specific, timely, and desirable responses from surrounding cells/tissues; for example, such biomaterials should support and enhance osteoblast adhesion (a crucial function for anchorage-dependent cells). In the past, integrin-binding peptides have been immobilized on substrates to partially control osteoblast adhesion; the present study focused on the design, synthesis, and bioactivity of the novel peptide sequence Lys-Arg-Ser-Arg that selectively enhances heparan sulfate-mediated osteoblast adhesion mechanisms. Osteoblast, but not endothelial cell or fibroblast, adhesion was enhanced significantly (p < 0.05) on substrates modified with Lys-Arg-Ser-Arg peptides, indicating that these peptides may be osteoblast- or bone cell specific. Blocking osteoblast cell-membrane receptors with various concentrations of soluble Arg-Gly-Asp-Ser peptides did not inhibit subsequent cell adhesion on substrates modified with Lys-Arg-Ser-Arg peptides, providing evidence that osteoblasts interact with Arg-Gly-Asp-Ser and with Lys-Arg-Ser-Arg peptides via distinct (i.e., integrin- and proteoglycan-mediated) mechanisms, each uniquely necessary for osteoblast adhesion. The present study constitutes an example of rational design/selection of bioactive peptides, confirms that osteoblast adhesion to substrates can be controlled selectively and significantly by immobilized peptides, and elucidates criteria and strategies for the design of proactive dental/orthopedic implant biomaterials.

Mini-review: Proactive biomaterials and bone tissue engineering.

Recent advances in cell isolation and culture procedures, combined with growing understanding and use of molecular biology and biochemistry techniques, have resulted in the establishment of a new field of biological/biomedical research: cellular and tissue engineering. In the biomaterials field, cell and tissue bioengineers are investigating the development of proactive biomaterials (for example, bioceramics, chemically modified implant metals, and biodegradable tissue scaffolds) which utilize cellular- or molecular-level methods of manipulating cell/tissue behavior in order to encourage clinically desirable biological events at the tissue-implant interface. In vitro investigations utilizing osteoblasts, osteoclasts, and appropriate precursor cells, combined with long-term (i.e., years) tissue engineering studies in vivo are needed to enhance current understanding of the many mechanisms involved in bone formation and regulation. Such understanding will allow the development of proactive biomaterials for use in bone, which can elicit specific, timely, and clinically desirable responses from surrounding cells and tissues. (c) 1996 John Wiley & Sons, Inc.

Conditions which promote mineralization at the bone-implant interface: a model in vitro study.

This in vitro study was an investigation of osteoblast functions on glass substrates modified with the bioactive peptide Arg-Gly-Asp-Ser (RGDS) in the absence and presence of recombinant human Osteogenic Protein-1 (OP-1); control substrates were plain glass, glass modified with amine groups, and glass modified with the non-adhesive peptide Arg-Asp-Gly-Ser. In serum-free cell culture medium, osteoblasts adhered in greater numbers (P < 0.1) to glass modified with RGDS, compared to adhesion on all other substrate types tested in the present study. In the presence of serum proteins, osteoblasts adhered similarly to all substrate types examined, in the absence or presence of 100 ng ml-1 OP-1. The presence of 100 ng ml-1 OP-1 inhibited (P < 0.1) 72 h proliferation of sparsely seeded (2500 cells cm-2) cultures on all substrates examined in the present study. OP-1 (100 ng ml-1) promoted 21 day mineralization on all substrates examined; in addition, mineralization was further enhanced in osteoblast cultures grown on glass modified with the adhesive peptide RGDS. The present study establishes conditions which can be utilized in the design of dental/orthopaedic biomaterials which elicit timely, specific responses from surrounding bone tissue.

Enhanced endothelialization of substrates modified with immobilized bioactive peptides.

This in vitro study examined the effects of soluble basic fibroblast growth factor and transforming growth factor-beta on bovine pulmonary artery endothelial cell interactions with surfaces containing the covalently-bound adhesive peptide tyrosine-isoleucine-glycine-serinearginine- glycine, or YIGSRG. The combination of adhesive peptide and soluble basic fibroblast growth factor (1 x 10(-9) g/ml) had no discernible effect on cell attachment, but resulted in significant increases in cell proliferation (p < 0.01; Duncan's multiple range test and Scheffé's test) and population motility (p < 0.05; Duncan's multiple range test) compared to all culture conditions examined in this study. Transforming growth factor-beta (1 x 10(-10) g/ml) had no stimulatory effect on cellular functions. The results of this study provide evidence that advanced biomaterials for vascular implantation could combine the influences of adhesive peptides and mitogenic chemical growth factors in order to promote endothelialization.