Collagen is commonly used as a tissue-engineering scaffold, yet its in vivo applications are limited by a deficiency in mechanical strength. The purpose of this work was to explore the utilization of a unique enzymatic crosslinking procedure aimed at improving the mechanical properties of collagen-based scaffold materials. Type I bovine collagen gel was crosslinked by transglutaminase, which selectively mediates the chemical reaction between glutamine and lysine residues on adjacent protein fibers, thus providing covalent amide bonds that serve to reinforce the three-dimensional matrix. The degree of crosslinking was verified by thermal analysis and amine group content. The denaturation temperature of crosslinked collagen reached a maximum of 66 +/- 1 degrees C. The chemical reaction was confirmed to be noncytotoxic with respect to bone marrow stromal cells acquired from New Zealand White rabbits. Tube-shaped cellular constructs fashioned from crosslinked collagen and bone marrow stromal cells were found to have burst pressures significantly higher than their noncrosslinked analogs (71 +/- 4 mmHg vs. 46 +/- 3 mmHg; p < 0.01). Thus, the transglutaminase mediated reaction served to successfully strengthen collagen gels while remaining benign toward cells.
A stabilized, phosphatidylcholine-containing polymeric surface was produced by in-situ polymerization of a self-assembled lipid monolayer on an alkylated substrate. The phospholipid monomer 1-palmitoyl-2-[12-(acryloyloxy)dodecanoyl]-sn-glycero-3-phosphorylcholine was synthesized, prepared as unilamellar vesicles, and fused onto alkylated glass. Free-radical polymerization was carried out in aqueous solution at 70 °C and characterized using either the water-soluble initiator 2,2‘-azobis(2-methylpropionamidine) dihydrochloride (AAPD) or an oil-soluble initiator 2,2‘-azobis(isobutyronitrile) (AIBN). Under optimized conditions, the supported monolayer displayed advancing and receding water contact angles of 64 and 44°, respectively. Angle-dependent ESCA results confirmed the presence of phosphorus and nitrogen and were consistent with theoretical predictions for close-packed monolayer formation with near-normal alignment of lipid chains. In the absence of network formation, polymeric films demonstrated acceptable stability under static conditions in water and air, as well as in the presence of a high shear flow environment. Blood compatibility was assessed in a baboon arteriovenous shunt model, which revealed miminal platelet deposition over a 2 h observation period.
A stable, substrate-supported phospholipid film was created by in-situ photopolymerization of an acrylate functionalized lipid assembly. The lipid film was generated on alkylated substrates by vesicle fusion and polymerized by irradiation with visible light, using eosin Y/triethanolamine as the photoinitiating species. Optimal experimental conditions were determined with respect to vesicle fusion time and duration of irradiation. The resulting polymeric lipid film was characterized by contact angle measurements, angle-resolved ESCA, and polarized external reflectance infrared spectroscopy. Static stability and desorption studies indicate enhanced stability of the photopolymerized system when compared with a heat-initiated analogue prepared by classical free-radical techniques.
A stabilized, membrane-mimetic film was produced on a polyelectrolyte multiplayer (PEM) by in-situ photopolymerization of an acrylate functonalized phospholipid assembly at a solid-liquid interface. The phospholipid monomer was synthesized, prepared as unilamellar vesicles, and fused onto close-packed octadecyl chains as part of an amphiphilic terpolymer anchored onto the PEM by electrostatic interactions. The lipid film displayed an advancing contact angle of ∼ 60°, elemental composition, as determined by X-ray photoelectron spectroscopy, was in agreement with that anticipated for a lipid membrane. Data obtained from both high-resolution scanning electron microscopy and ellipsometry were consistent with the formation of a supported lipid monolayer. In addition, polarized external reflection infrared spectroscopy revealed significant acyl chain ordering induced on lipid fusion and polymerization. Doping the lipid assembly with a fluorescein terminated polymerizable lipid provided visible confirmation of film formation and its stability under a variety of conditions, including shear rates of 2000 sec -1 . Transport studies demonstrated that the addition of a lipid film significantly reduced barrier permeability for compounds in excess of 70 kD. The ability to coat microbeads (d ∼ 300 µm) with a robust membrane-mimetic film, while preserving encapsulated cell viability is illustrated, thereby establishing a new strategy for modulating the physiochemical and biological properties of immunoisolation barriers for cell transplantation.
The logical assembly of tissue-engineered bone is ultimately directed by the clinical status of the patient. The basic elements for tissue-engineered bone should include signaling molecules, cells, and extracellular matrix. The assembly of these basic elements may need to be modified by tissue engineers to account for patient variables of age, gender, health, systemic conditions, habits, and anatomical implant. Moreover, different regions of the body will have different functional loads and vascularity. This review discusses several basic options that may be necessary to engineer bone, including spatial and temporal assembly of signaling factors, cells, and biomimetic extracellular matrices. Moreover, the importance of the health care status of the patient who may be receiving the tissue-engineered composition is emphasized.
We report the design and synthesis of bifunctional phospholipid conjugates, which contain a polymerizable acrylate group and a terminal linker, such as biotin or N-(epsilon-maleimidocaproyl (EMC), to facilitate bioconjugation reactions. The lipid conjugate can be used to generate a multifunctional substrate-supported phospholipid film that is further stabilized via in-situ photocopolymerization.
A stable, protein C activating membrane-mimetic film was produced on a polyelectrolyte multilayer (PEM) by in-situ photopolymerization of a phospholipid assembly containing thrombomodulin (TM). The monoacrylated phospholipid monomer was initially synthesized and prepared as unilamellar vesicles with varying molar concentrations of TM. Notably, in mixed-lipid systems, K m values for protein C activation increased in direct proportion to the mole fraction of polymerizable lipid, which was likely due to reduced membrane mobility after photopolymerization. Membrane-mimetic films were also constructed on planar substrates with predictable surface concentrations of catalytically active TM. Significantly, at a TM surface concentration of 170 fmol/cm2, the rate of protein C activation was comparable to that measured for a variety of confluent endothelial cell monolayers. Serial measurements of contact angles and protein C activation confirmed short-term film stability under a variety of in vitro conditions. Moreover, 125I labeling of TM demonstrated little change in TM surface concentration over periods of up to 28 days. Significantly, polymeric lipid membranes functionalized with thrombomodulin efficiently inhibited thrombin generation. We believe that the design of membrane-mimetic films that have the capacity to activate the protein C pathway will provide a useful strategy for generating “actively” antithrombogenic surfaces.
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