Exosome-Functionalized, Drug-Laden Bone Substitute along with an Antioxidant Herbal Membrane for Bone and Periosteum Regeneration in Bone Sarcoma.

Developing advanced methods for effective bone reconstructive strategies in case of critical bone defects caused by tumor resection, trauma, and other implant-related complications remains a challenging problem in orthopedics. In the clinical management of bone diseases, there is a paradigm shift in using local drugs at the injury site; however, the dead space created during the surgical debridement of necrotic bone and soft tissues (periosteum and underlying muscle) leads to ineffective bone formation, thereby leading to secondary complications, and thus calls for better regenerative approaches. In this study, we have utilized an exosome-functionalized doxorubicin-loaded biodegradable nanocement (NC)-based carrier along with a Cissus quadrangularis (CQ) extract-laden antioxidant herbal membrane for simultaneously managing the periosteum as well as bone formation in the tumor resection model of osteosarcoma. We initially evaluated the efficacy of scaffolds for in vitro mineralization and bone formation. To examine the in vivo effectiveness, we developed a human osteosarcoma cell line (Saos-2)-induced tumor xenograft model with a critical-sized bone defect. The findings revealed that doxorubicin released from NC was successful in killing the tumor cells and was present even after 30 days of implantation. Additionally, the incorporation of exosomes aided the bone formation, resulting in around a 2.6-fold increase in the bone volume compared to the empty group as evaluated by micro-CT. The herbal membrane assisted in the development of periosteum and mineralizing bone callous as validated through histological and immunofluorescence analysis. Thus, our findings describe a one-step biomaterial-based cell-free approach to regenerate bone in osteosarcoma and prevent further fracture due to the complete development of periosteum and lost bone.

Exosome-Functionalized Ceramic Bone Substitute Promotes Critical-Sized Bone Defect Repair in Rats.

Ceramic biomaterials are promising alternatives to bone autografts. However, limited bioactivity affects their performance. Therefore, bioactive molecules and cells are often added to enhance their performance. Exosomes have emerged as cell-secreted vesicles, delivering proteins, lipids, and nucleic acids in a paracrine/endocrine fashion. We studied two complementary aspects required for exosome activity/therapy using purified exosomes: first, the intracellular uptake of labeled exosomes and second, the influence of delivered exosomes on cell behavior. Origin-specific differences in the characteristics of purified exosomes, quantification of time-dependent intracellular uptake of PKH-26-labeled exosomes by mesenchymal stem cells (MSCs) and preosteoblasts, and influence on cell behavior were evaluated. Furthermore, exosomes from osteoblasts and MSCs cultured under normal and osteogenic environments were isolated. There is little data available on the concentration and dose of exosomes required for bone regeneration. Therefore, equal amounts of quantified exosomes were implanted in vivo in rat tibia critical defects using a calcium sulfate-nano-hydroxyapatite nanocement (NC) bone filler as the carrier. Bone regeneration was quantified using micro-computed tomography and histology. Along with inducing early maturation and mineral deposition by primary preosteoblasts in vitro, exosome treatment also demonstrated a positive effect on bone mineralization in vivo. Our study concludes that providing a local delivery of exosomes loaded onto a slowly resorbing NC bone filler can provide a potential alternate to autografts as a bone substitute.

Enhanced bone mineralization using hydroxyapatite-based ceramic bone substitute incorporating Withania somnifera extracts.

Withania somnifera (ashwagandha) is used in Indian traditional medicine for its various health benefits. Withaferin-A, a steroidal lactone present in this herb, has shown proteosomal inhibition-based enhancement of bone mineralization. In the present work, chitosan microparticles blended with total methanolic root extract of W. somnifera were incorporated as a porogen in calcium phosphate-based hydroxyapatite bone filler. The controlled release of bioactive molecules enabled enhanced proliferation and differentiation of pre-osteoblasts. Microparticle percentages were optimized to have a minimum effect on the setting time, mechanical strength and degradability of hydroxyapatite bone filler. In vitro cell adhesion, proliferation and differentiation were evaluated to determine the biocompatibility of the composites. On the basis of the desirable results obtained, we provide a preliminary rationale for the use of methanolic extract-blended chitosan microparticle-impregnated calcium phosphate filler for enhanced bone regeneration.

Orthobiologics with phytobioactive cues: A paradigm in bone regeneration.

Bone injuries occur due to various traumatic and disease conditions. Healing of bone injury occurs via a multi-stage intricate process. Body has the potential to rectify most of the bone injuries but some severe traumatic cases with critical size defects may require interventions. Autografts are still considered the "gold standard" for fracture healing but due to limitations associated with it, new alternatives are warranted. The field of orthobiologics has provided novel approaches using scaffolds, bioactive molecules, stem cells for the treatment of bone defects. Phyto-bioactives have been widely used in alternative medicine and folklore practices for curing bone ailments. It is believed that different bioactive constituents in plants work synergistically to give the therapeutic efficacy. Bioactives in plants extracts act upon different signal transduction pathways aiding in bone healing. The present review focuses on the use, chemical composition, mode of delivery, mechanism of action, and possible future strategies of three medicinal plants popularly used in traditional medicine for bone healing: Cissus quadrangularis, Withania somnifera and Tinospora cordifolia. Plants extracts seem to be a natural and non-toxic therapeutic alternative in treating bone injuries. Most of the studies on bone healing for these plants have reported oral administration of the extracts and presented them as a safe alternative without any side effects despite giving higher doses. Forthcoming studies could be directed towards the local delivery of extracts at the defect site. Unification of herbal extracts and orthobiologics could be an interesting direction in the field of bone healing in future. The present review intends to provide a bird's eye view of different strategies used in bone healing, mechanisms involved and future direction of advancements using phytobioactives and orthobiologics.

Endogenous Platelet-Rich Plasma Supplements/Augments Growth Factors Delivered via Porous Collagen-Nanohydroxyapatite Bone Substitute for Enhanced Bone Formation.

Polymer (acrylate) and ceramic bone cements are extensively used as bone void fillers and for implant fixation in orthopedics. These materials have micro- to nonporous architectures. Postimplantation, they may cause hypoxic and exothermic injuries to already compromised damage site. These materials also have limited interaction with surrounding tissue. In this work we have developed composite collagen-nanohydroxyapatite (CS) bone filler, mimicking porous architecture of trabecular bone. It was functionalized with clinically available bone active agents like bone morphogenetic protein-2 (rhBMP-2) and zoledronic acid (ZA). We investigated synergistic effects of the bone active molecules and endogenous platelet rich plasma (PRP), a source of growth factors on mineralization. Porous CS and collagen/gelatin/chiotosan polymer scaffold (SC) (without nanohydroxyapatite) were synthesized using cryogelation. PRP (10 µL) (∼5 × 106 cells), rhBMP-2 (5 µg) and ZA (10 µg) were used to functionalize scaffolds. Bone formation was evaluated at ectopic sites in abdominal pouch and 4.0 mm critical defect in tibia metaphysis of rats. Tissue mineralization was evaluated by micro-CT and histological analysis 12 weeks postimplantation. In vitro cell based studies revealed, PRP functionalization enhances osteoblast proliferation and activity on scaffolds. In vivo BMP+ZA+PRP functionalized scaffolds had higher amount (28 mm3) of mineralized tissue formation as compared to empty defect (20 mm3), suggesting that PRP can augment the osteoinductive properties of functionalized scaffolds both in vitro and in vivo. Enhanced cell infiltration and mineralization can be achieved via CS in comparison to SC, implying their use as porous bone void fillers and substitutes for autografts.

Guided tissue engineering for healing of cancellous and cortical bone using a combination of biomaterial based scaffolding and local bone active molecule delivery.

A metaphyseal bone defect due to infection, tumor or fracture leads to loss of cancellous and cortical bone. An animal model separating the cancellous and cortical healing was used with a combination of a macroporous gelatin-calcium sulphate-hydroxyapatite (Gel-CaS-HA) biomaterial as a cancellous defect filler, and a thin collagen membrane (CM) guiding cortical bone regeneration. The membrane was immobilized with bone morphogenic protein-2 (rhBMP-2) to enhance the osteoinductive properties. The Gel-CaS-HA cancellous defect filler contained both rhBMP-2 and a bisphosphonate, (zoledronate = ZA) to prevent premature callus resorption induced by the pro-osteoclast effect of rhBMP-2 alone. In the first part of the study, the CM delivering both rhBMP-2 and ZA was tested in a muscle pouch model in rats and the co-delivery of rhBMP-2 and ZA via the CM resulted in higher amounts of bone compared to rhBMP-2 alone. Secondly, an established tibia defect model in rats was used to study cortical and cancellous bone regeneration. The defect was left empty, filled with Gel-CaS-HA alone, Gel-CaS-HA immobilized with ZA or Gel-CaS-HA immobilized with rhBMP-2+ZA. Functionalization of the Gel-CaS-HA scaffold with bioactive molecules produced significantly more bone in the cancellous defect and its surroundings but cortical defect healing was delayed likely due to the protrusion of the Gel-CaS-HA into the cortical bone. To guide cortical regeneration, the cortical defect was sealed endosteally by a CM with or without rhBMP-2. Subsequently, the cancellous defect was filled with Gel-CaS-HA containing ZA and rhBMP-2+ZA. In the groups where the CM was doped with rhBMP-2, significantly higher number of cortices bridged. The approach to guide cancellous as well as cortical bone regeneration separately in a metaphyseal defect using two bioactive molecule immobilized biomaterials is promising and could improve the clinical care of patients with metaphyseal defects.