Beyond drug delivery: metal-organic framework-derived nanosystems for bone regeneration under complicated pathological microenvironments
Conspectus: The development of tactics to effectively manage various bone illnesses, including bone abnormalities, bone infections, fractures, osteoarthritis, osteoporosis, and malignancies, has become a significant public health concern for achieving optimal bone repair outcomes. Conventionally, bi...
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Medicine, Health and Life Sciences Drug delivery Bone regeneration Zhao, Yue Xiong, Yuan Zhao, Yanli Beyond drug delivery: metal-organic framework-derived nanosystems for bone regeneration under complicated pathological microenvironments |
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Conspectus: The development of tactics to effectively manage various bone illnesses, including bone abnormalities, bone infections, fractures, osteoarthritis, osteoporosis, and malignancies, has become a significant public health concern for achieving optimal bone repair outcomes. Conventionally, bisphosphonates and monoclonal antibody medications have shown partial clinical efficacy in bone regeneration. However, issues such as medication resistance, life-threatening off-target side effects, and poor bioavailability continue to affect the majority of patients. Additionally, surgical interventions like subchondral bone microfracture, lavage, debridement, and shaving are primarily effective for minor bone defects. For severe bone defects, the gold standard treatment involves implanting autologous or allogeneic bone grafts. Nevertheless, these grafts come with challenges, such as donor site complications, immune rejection, infections, and limited tissue availability. Recent years have seen the rapid development of new therapeutic strategies that have significantly revolutionized the course of bone regeneration. Metal-organic frameworks (MOFs) are a class of porous materials consisting of metal-metal clusters and organic ligands. Over the past few decades, MOF-based nanosystems have been extensively applied as versatile drug delivery systems for transporting small molecules, genes, peptides, and proteins owing to their distinct coordination network, porous structure, feasible surface modification, and adjustable porosity. Notably, the versatile nanostructure and composition of MOFs allow customization of their metal cations and defect locations within the porous structure to meet the complex requirements of the bone tissue microenvironment. Additionally, MOF-based nanosystems can be harnessed with corresponding functional components, thus achieving selective depletion of overproduced danger signals, blockage of the receptor for the pleiotropic inflammatory molecules, and delivery of therapeutic agents to target sites, hence boosting its effectiveness in bone regeneration. In this Account, we systematically highlight the fundamental aspects of MOF-based nanosystem design with a specific focus on critical factors such as chemical composition, shape, size, and surface chemistry. Subsequently, we review recent achievements of MOF-based nanosystems beyond drug delivery, specifically their utilization in bone regeneration under complex pathological conditions. Given the complicated characteristics of bone regeneration that require a multifaceted and dynamic approach, these strategies exemplify the innovative efforts needed to overcome the challenges posed by this complex disease. With significant strides in understanding the molecular mechanisms underlying bone defects, coupled with advances in bioengineering techniques, more efficient MOF-based nanosystems will be designed and applied in bone regeneration in the future. This progress will bridge the gap between basic research and clinical applications, ultimately enhancing the therapeutic effectiveness of treatments for bone regeneration in complicated pathological microenvironments. |
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School of Chemistry, Chemical Engineering and Biotechnology |
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School of Chemistry, Chemical Engineering and Biotechnology Zhao, Yue Xiong, Yuan Zhao, Yanli |
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Article |
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Zhao, Yue Xiong, Yuan Zhao, Yanli |
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Zhao, Yue |
| title |
Beyond drug delivery: metal-organic framework-derived nanosystems for bone regeneration under complicated pathological microenvironments |
| title_short |
Beyond drug delivery: metal-organic framework-derived nanosystems for bone regeneration under complicated pathological microenvironments |
| title_full |
Beyond drug delivery: metal-organic framework-derived nanosystems for bone regeneration under complicated pathological microenvironments |
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Beyond drug delivery: metal-organic framework-derived nanosystems for bone regeneration under complicated pathological microenvironments |
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Beyond drug delivery: metal-organic framework-derived nanosystems for bone regeneration under complicated pathological microenvironments |
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beyond drug delivery: metal-organic framework-derived nanosystems for bone regeneration under complicated pathological microenvironments |
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2025 |
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https://hdl.handle.net/10356/182963 |
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1826362298833305600 |
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sg-ntu-dr.10356-1829632025-03-11T06:58:12Z Beyond drug delivery: metal-organic framework-derived nanosystems for bone regeneration under complicated pathological microenvironments Zhao, Yue Xiong, Yuan Zhao, Yanli School of Chemistry, Chemical Engineering and Biotechnology Medicine, Health and Life Sciences Drug delivery Bone regeneration Conspectus: The development of tactics to effectively manage various bone illnesses, including bone abnormalities, bone infections, fractures, osteoarthritis, osteoporosis, and malignancies, has become a significant public health concern for achieving optimal bone repair outcomes. Conventionally, bisphosphonates and monoclonal antibody medications have shown partial clinical efficacy in bone regeneration. However, issues such as medication resistance, life-threatening off-target side effects, and poor bioavailability continue to affect the majority of patients. Additionally, surgical interventions like subchondral bone microfracture, lavage, debridement, and shaving are primarily effective for minor bone defects. For severe bone defects, the gold standard treatment involves implanting autologous or allogeneic bone grafts. Nevertheless, these grafts come with challenges, such as donor site complications, immune rejection, infections, and limited tissue availability. Recent years have seen the rapid development of new therapeutic strategies that have significantly revolutionized the course of bone regeneration. Metal-organic frameworks (MOFs) are a class of porous materials consisting of metal-metal clusters and organic ligands. Over the past few decades, MOF-based nanosystems have been extensively applied as versatile drug delivery systems for transporting small molecules, genes, peptides, and proteins owing to their distinct coordination network, porous structure, feasible surface modification, and adjustable porosity. Notably, the versatile nanostructure and composition of MOFs allow customization of their metal cations and defect locations within the porous structure to meet the complex requirements of the bone tissue microenvironment. Additionally, MOF-based nanosystems can be harnessed with corresponding functional components, thus achieving selective depletion of overproduced danger signals, blockage of the receptor for the pleiotropic inflammatory molecules, and delivery of therapeutic agents to target sites, hence boosting its effectiveness in bone regeneration. In this Account, we systematically highlight the fundamental aspects of MOF-based nanosystem design with a specific focus on critical factors such as chemical composition, shape, size, and surface chemistry. Subsequently, we review recent achievements of MOF-based nanosystems beyond drug delivery, specifically their utilization in bone regeneration under complex pathological conditions. Given the complicated characteristics of bone regeneration that require a multifaceted and dynamic approach, these strategies exemplify the innovative efforts needed to overcome the challenges posed by this complex disease. With significant strides in understanding the molecular mechanisms underlying bone defects, coupled with advances in bioengineering techniques, more efficient MOF-based nanosystems will be designed and applied in bone regeneration in the future. This progress will bridge the gap between basic research and clinical applications, ultimately enhancing the therapeutic effectiveness of treatments for bone regeneration in complicated pathological microenvironments. National Research Foundation (NRF) This research work was supported by the National Natural Science Foundation of China (22105131) and the Singapore National Research Foundation under its Competitive Research Programme (NRF-CRP26-2021-0002). 2025-03-11T06:58:11Z 2025-03-11T06:58:11Z 2024 Journal Article Zhao, Y., Xiong, Y. & Zhao, Y. (2024). Beyond drug delivery: metal-organic framework-derived nanosystems for bone regeneration under complicated pathological microenvironments. Accounts of Materials Research, 5(12), 1532-1543. https://dx.doi.org/10.1021/accountsmr.3c00263 2643-6728 https://hdl.handle.net/10356/182963 10.1021/accountsmr.3c00263 2-s2.0-85205902403 12 5 1532 1543 en NRF‐CRP26‐2021‐0002 Accounts of Materials Research © 2024 Accounts of Materials Research. Co-published by ShanghaiTech University and American Chemical Society. All rights reserved. |