Growth factors are endogenous proteins capable of stimulating new bone formation, but their clinical benefit for systemic stimulation of bone mass has not been demonstrated. The critical challenge is to deliver a significant dose of the proteins to bone after intravenous injection. This challenge may be overcome by derivatizing proteins with ligands that exhibit a high bone affinity (e.g., bisphosphonates). To demonstrate the feasibility of this approach, 1-amino-1,1-diphosphonate methane (aminoBP) was conjugated to a model protein, albumin. The conjugation was performed by (1) converting the amino group of aminoBP to a thiol group using 2-iminothiolane, (2) derivatizing the albumin amino groups with a thiol-reactive sulfosuccinimidyl-4-(N-maleimidomethyl)-1-cyclohexane carboxylate, and (3) reacting the derivatized albumin with thiolated aminoBP. Typically, 1-4 aminoBP molecules per albumin were obtained. The conjugated albumin exhibited a high affinity to hydroxyapatite that was proportional to the extent of conjugation. The conjugates were shown to exhibit a high affinity to bone matrix in vitro in a serum-containing medium. Once bound to bone matrix, the conjugates were found to desorb more slowly than the unmodified albumin, especially from bone whose organic matrix was removed by ashing. In conclusion, conjugation of bisphosphonates to albumin was shown to impart a high bone affinity to the protein, and such conjugates can be potentially targeted to bone.
This study was carried out to engineer N-isopropylacrylamide (NiPAM) polymers that contain protein-reactive N-acryloxysuccinimide (NASI) and hydrophobic alkylmethacrylates (AMAs). These thermoreversible, protein-conjugating polymers hold potential for retention of therapeutic proteins at an application site where tissue regeneration is desired. The lower critical solution temperatures (LCST) of the polymers were effectively controlled by the AMA mole content. The AMAs with longer side-chains were more effective in lowering the LCST. Polymers without NASI exhibited a stable LCST in phosphate buffer and in serum over a 10-day study period. The LCST of polymers containing NASI was found to increase over time in phosphate buffer, but not in serum-containing medium. The LCST increase in phosphate buffer was proportional to the AMA content. The feasibility of localizing a therapeutic protein, recombinant human bone morphogenetic protein-2 (rhBMP-2), to a site of application was explored in a rat intramuscular injection model. The results indicated that polymers capable of conjugating to rhBMP-2 were most effective in localizing the protein irrespective of the LCST (13-25 degrees C). For polymers with no NASI groups, a lower LCST resulted in a better rhBMP-2 localization. We conclude that thermosensitive polymers can be engineered for delivery of therapeutic proteins to improve their therapeutic efficacy.
Recombinant human bone morphogenetic protein 2 (rhBMP-2) is currently in clinical studies as part of an implantable device that contains a biomaterial carrier. Implant retention of rhBMP-2 by the biomaterial carrier is important for the osteoinductive activity. To control in situ retention of rhBMP-2, thermoreversible polymers were synthesized and characterized, and their compatibility with rhBMP-2-induced osteoinduction was investigated. The results indicated that polymers with a controlled "solubility <--> insolubility" transition temperature could be prepared from N-isopropylacrylamide, ethylmethacrylate, and N-acryloxysuccinimide (NASI). NASI-containing polymers were able to conjugate to rhBMP-2 without additional cross-linkers. Implantation in the rat ectopic model, where alkaline phosphatase and calcium deposition were utilized as markers of osteoinductive activity, indicated that rhBMP-2 mixed with the polymers were effective for osteoinduction. Moreover, rhBMP-2 conjugated to the chosen polymers was as effective as native rhBMP-2 in inducing ALP activity and calcium deposition. We conclude that thermoreversible polymers are compatible with rhBMP-2-induced osteogenesis and can serve as novel biomaterials for rhBMP-2 delivery.
Temperature‐sensitive polymers were prepared for in vivo delivery of recombinant human Bone Morphogenetic Protein‐2 (rhBMP‐2). The polymers were designed to overcome a critical limitation of current rhBMP‐2 delivery systems, namely to provide a mechanism for in situ retention of the protein. The polymers were based on N‐isopropylacrylamide (NiPAM). Ethyl methacrylate (EMA) and N‐acryloxysuccinimide (NASI) were incorporated into the NiPAM polymer to reduce the lower critical solution temperature and to conjugate to proteins, respectively. To test capacity of polymers to retain rhBMP‐2, rhBMP‐2 were labeled with 125I, formulated with the polymers and were either implanted with a collagen sponge or injected directly into an intramuscular site in rats. The results indicated that implantation with a relatively low polymer concentration (3.9 mg/mL) did not result in significant rhBMP‐2 retention, but increasing the polymer concentration (28.7 mg/mL) gave a better retention with NiPAM/NASI polymers. In the injectable mode, NiPAM/NASI and NiPAM/EMA gave ∼ 200‐fold better retention after 9 days in vivo. We conclude that synthetic, temperature‐sensitive polymers can be engineered to sequester and retain osteoinductive proteins at a site of administration. Devices with an enhanced osteopotency should result by delivering rhBMP‐2 with the prepared biomaterials.
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