Engineering vascularized and innervated bone biomaterials for improved skeletal tissue regeneration

Marrella, Alessandra; Lee, Tae Yong; Lee, Dong Hoon; Karuthedom, Sobha; Syla, Denata; Chawla, Aditya; Khademhosseini, Ali; Jang, Hae Lin

doi:10.1016/j.mattod.2017.10.005

Cited by 196 publications

(174 citation statements)

References 181 publications

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“…Bioactive glass (BG) with 3D structure can afford structural support of large bone defects and regulate biochemical and biophysical processes with high osteoinductivity and biocompatibility. [ 42–44 ] In the meantime, the well‐designed macropores and rough surface benefit osseointegration and vascularization with the adhesive cell–matrix interactions, [ 45 ] enhancing the penetration and attachment of osteoblasts and endothelial cells.…”

Section: Introductionmentioning

confidence: 99%

Engineering 2D Mesoporous Silica@MXene‐Integrated 3D‐Printing Scaffolds for Combinatory Osteosarcoma Therapy and NO‐Augmented Bone Regeneration

Yang

Yin

et al. 2020

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The rising concerns of the recurrence and bone deficiency in surgical treatment of malignant bone tumors have raised an urgent need of the advance of multifunctional therapeutic platforms for efficient tumor therapy and bone regeneration. Herein, the construction of a multifunctional biomaterial system is reported by the integration of 2D Nb2C MXene wrapped with S‐nitrosothiol (RSNO)‐grafted mesoporous silica with 3D‐printing bioactive glass (BG) scaffolds (MBS). The near infrared (NIR)‐triggered photonic hyperthermia of MXene in the NIR‐II biowindow and precisely controlled nitric oxide (NO) release are coordinated for multitarget ablation of bone tumors to enhance localized osteosarcoma treatment. The in situ formed phosphorus and calcium components degraded from BG scaffold promote bone‐regeneration bioactivity, augmented by sufficient blood supply triggered by on‐demand NO release. The tunable NO generation plays a crucial role in sequential adjuvant tumor ablation, combinatory promotion of coupled vascularization, and bone regeneration. This study demonstrates a combinatory osteosarcoma ablation and a full osseous regeneration as enabled by the implantation of MBS. The design of multifunctional scaffolds with the specific features of controllable NO release, highly efficient photothermal conversion, and stimulatory bone regeneration provides an intriguing biomaterial platform for the diversified treatment of bone tumors.

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Section: Introductionmentioning

confidence: 99%

Engineering 2D Mesoporous Silica@MXene‐Integrated 3D‐Printing Scaffolds for Combinatory Osteosarcoma Therapy and NO‐Augmented Bone Regeneration

Yang

Yin

et al. 2020

Small

107

118

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“…Bone tissue rich in blood vessels is subjected to continuous remodeling . However, it often fails when the healing capacity is compromised in many clinical situations such as osteoporosis and diabetes .…”

Section: Introductionmentioning

confidence: 99%

Sal B targets TAZ to facilitate osteogenesis and reduce adipogenesis through MEK‐ERK pathway

Wang

et al. 2019

J Cellular Molecular Medi

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Salvianolic acid B (Sal B), a major bioactive component of Chinese herb, was identified as a mediator for bone metabolism recently. The aim of this study is to investigate the underlying mechanisms by which Sal B regulates osteogenesis and adipogenesis. We used MC3T3‐E1 and 3T3‐L1 as the study model to explore the changes of cell differentiation induced by Sal B. The results indicated that Sal B at different concentrations had no obvious toxicity effects on cell proliferation during differentiation. Furthermore, Sal B facilitated osteogenesis but inhibited adipogenesis by increasing the expression of transcriptional co‐activator with PDZ‐binding motif (TAZ). Accordingly, TAZ knock‐down offset the effects of Sal B on cell differentiation into osteoblasts or adipocytes. Notably, the Sal B induced up‐expression of TAZ was blocked by U0126 (the MEK‐ERK inhibitor), rather than LY294002 (the PI3K‐Akt inhibitor). Moreover, Sal B increased the p‐ERK/ERK ratio to regulate the TAZ expression as well as the cell differentiation. In summary, this study suggests for the first time that Sal B targets TAZ to facilitate osteogenesis and reduce adipogenesis by activating MEK‐ERK signalling pathway, which provides evidence for Sal B to be used as a potential therapeutic agent for the management of bone diseases.

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“…The bone is fully vascularized and innervated where blood vessels and nerve bers closely interact [29]. Blood vessels and nerve bers, which exist throughout the entire bone, including the periosteum, bone marrow, and mineralized parts of the bone, are involved in bone formation and development [29,30]. Vascular and neural involvement is the basis for the construction of normal functional bone tissue during TEBG osteogenesis.…”

Section: Discussionmentioning

confidence: 99%

Schwann Cells Promote Prevascularization and Osteogenesis of Tissue-engineered Bone via Bone Marrow Mesenchymal Stem Cell-derived Endothelial Cells

Zhang

Jiang

et al. 2020

Preprint

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Background: Tissue-engineered bone grafts (TEBGs) that undergo vascularization and neurotization evolve into functioning bone tissue. Previously, we verified that implanting sensory nerve tracts into TEBGs promoted osteogenesis. However, the precise mechanisms and interaction between seed cells were not explored. In this study, we hypothesized that neurotization may influence the osteogenesis of TEBGs through vascularization. Methods: We cultured rat Schwann cells (SCs), aortic endothelial cells (AECs) and bone marrow-derived mesenchymal stem cells (BM-MSCs) and then obtained BM-MSC-derived induced endothelial cells (IECs) and induced osteoblasts (IOBs). IECs and AECs were cultured in SC-conditioned medium (SC-CM) to assess proliferation, migration, capillary-like tube formation and angiogenesis, and the vascular endothelial growth factor (VEGF) levels in the supernatants were detected. We established an indirect coculture model to detect the expression of nestin and VEGF receptors in IECs and tissue inhibitor of metalloproteinase (TIMP)-2 in SCs. Then, SCs, IECs and IOBs were labeled and loaded into a β-tricalcium phosphate scaffold to induce prevascularization, and the scaffold was implanted into a 6-mm-long defect of rat femurs. Three groups were set up according to the loaded cells: I, SCs and IECs (coculture for 3 days) plus IOBs; II, IECs (culture for 3 days) plus IOBs; III, IOBs. Nestin and TIMP-2 expression and osteogenesis of TEBGs were evaluated at 12 weeks post implantation through histological and radiological assessment.Results: We found that SC-CM promoted IEC proliferation, migration, capillary-like tube formation and angiogenesis, but no similar effects were observed for AECs. IECs expressed nestin extensively, while AECs barely expressed nestin, and SC-CM promoted the VEGF secretion of IECs. In the coculture model, SCs promoted nestin and VEGF receptor expression in IECs, and IECs inhibited TIMP-2 expression in SCs. The promotion of prevascularized TEBGs by SCs and IECs in group I augmented new bone formation at 6 and 12 weeks. Nestin expression was higher in group I than in the other groups, while TIMP-2 expression was lower at 12 weeks. Conclusions: This study demonstrated that SCs can promote TEBG osteogenesis via IECs and further revealed the mechanisms related to specific characteristics of IECs, providing preliminary cytological evidence for neurotization of TEBGs.

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Engineering vascularized and innervated bone biomaterials for improved skeletal tissue regeneration

Cited by 196 publications

References 181 publications

Engineering 2D Mesoporous Silica@MXene‐Integrated 3D‐Printing Scaffolds for Combinatory Osteosarcoma Therapy and NO‐Augmented Bone Regeneration

Engineering 2D Mesoporous Silica@MXene‐Integrated 3D‐Printing Scaffolds for Combinatory Osteosarcoma Therapy and NO‐Augmented Bone Regeneration

Sal B targets TAZ to facilitate osteogenesis and reduce adipogenesis through MEK‐ERK pathway

Schwann Cells Promote Prevascularization and Osteogenesis of Tissue-engineered Bone via Bone Marrow Mesenchymal Stem Cell-derived Endothelial Cells

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