Advance of Nano-Composite Electrospun Fibers in Periodontal Regeneration

Yu, Zhuang; Lin, Kaili; Yu, Haisheng

doi:10.3389/fchem.2019.00495

Cited by 70 publications

(67 citation statements)

References 108 publications

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“…Previous works indicated that the use of guided membranes without osteoinductive molecules was generally ineffective for highly mineralized bone regeneration, and thus, osteoinductive molecules have been combined with them. 56,57 Despite many promising results, inflammatory responses often occur during surgery, which results in insufficient mineralization and delayed tissue regeneration. 58 As demonstrated on previous studies, lactoferrin may be a candidate with dual functions for the enhancement of in vivo bone regeneration and suppression of inflammation reactions, however, they have never been studied as an immobilized platform.…”

Section: Discussionmentioning

confidence: 99%

Bioactive Membrane Immobilized with Lactoferrin for Modulation of Bone Regeneration and Inflammation

Lee

et al. 2020

Tissue Engineering Part A

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Guided bone regeneration refers to the process in which bone defects could be regenerated by facilitated healing through the use of membranes, potentially with the delivery of osteoinductive molecules, however, the regeneration often failed due to inflammation during bone formation. In this study, we developed a membrane immobilized with lactoferrin to modulate both bone regeneration and inflammatory responses. Lactoferrin was immobilized on electrospun nanofibers (LF50) by exploiting an adhesive polydopamine coating method. When human adipose-derived stem cells (hADSCs) were seeded onto the nanofibers, the LF50 significantly increased the osteogenic differentiation. For example, the gene expression of osteopontin was 6.9 -2.3 times greater in the cells on LF50 than the cells on unmodified nanofibers without lactoferrin. In addition, the gene expression of tumor necrosis factor-alpha (TNF-a) of the macrophage cell line (RAW264.7) cultured on the LF50 was 0.3 -0.1 times reduced, indicating the lactoferrin was able to reduce inflammatory response. With implantation of nanofibers on in vivo mouse calvarial defects, the LF50 resulted in 60.9% -4.5% of new bone formation, which was six times greater than the results of other groups. Furthermore, when the fibers were implanted onto the in vivo mouse subcutaneous model challenged with lipopolysaccharide and interferon-g, the area of inflammatory tissue was significantly reduced in the LF50 implanted group as 0.6 -0.1 mm 2 as compared with the control group (1.1 -0.1 mm 2 ). Taken together, the lactoferrin immobilization onto the nanofiber by polydopamine chemistry may be an effective delivery method for improving bone regeneration while regulating the inflammation.In vivo critical-sized bone reconstruction remains challenging due to the severe inflammation, which would be an unavoidable problem during surgical process. Therefore, the present study aims to develop a guided nanofibrous membrane immobilized with lactoferrin, which has dual functions with osteoinduction and anti-inflammation. The lactoferrinimmobilized fibers demonstrated significantly enhanced in vitro osteogenic differentiation of adipose-derived stem cells as well as decreased polarization of macrophage to M1 with relatively reduced amount than that reported from previous reports. We also found that the membrane improved in vivo bone regeneration and decreased inflammatory tissue formation. Taken together, this system would be a new platform for successful bone regeneration.

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Section: Discussionmentioning

confidence: 99%

Bioactive Membrane Immobilized with Lactoferrin for Modulation of Bone Regeneration and Inflammation

Lee

et al. 2020

Tissue Engineering Part A

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“…1 C). 43 Solution electrospinning fibers are inorganized nanofibers with smaller pores, while melt electrospinning fibers are organized microfibers with larger pores. 40 …”

Section: New Tissue Engineering Technologiesmentioning

confidence: 99%

Advanced technologies in periodontal tissue regeneration based on stem cells: Current status and future perspectives

Zeng

Yang

Huang

2021

Journal of Dental Sciences

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Periodontitis is a progressive inflammation disease, the clinical management of which remains a challenge. The traditional management may control periodontal inflammation, but failed to regenerate functional periodontium. This review summarizes the most advancing regenerative techniques regarding stem cell culture and scaffold fabrication, such as cell sheeting, spheroid culture, electrospinning and 3D printing. The applications of different techniques manifest tremendous potential of regenerating the complete and functional periodontium. Albeit promising, new technologies have met with their own drawbacks such as insufficient vascularization and precision, which necessitate deeper modification. Thus, this review also points out the potential perspectives and methods aiming at their disadvantages, illuminating the directions of future researches to successful clinical scenarios.

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“…For example, the PLGA 75:25 (75% LA and 25% GA) demonstrated more amorphous structures, a lower hydrophilicity, and slower degradation than PLGA 50:50 [ 116 , 117 ]. As a result of the higher hydrophilicity of the amorphous PLGA copolymer with a higher ratio of PGA (e.g., PLGA 50:50), more water absorption is possible which results in faster hydrolytic degradation rates [ 116 , 118 ]. Therefore, the hydrolysis rates may be dependent on different ratios of LA/GA during fabrication, and the copolymerization process could be used to manufacture optimal drug delivery systems with degradation kinetics [ 119 , 120 ].…”

Section: Synthetic Biopolymers For Periodontal Hard Tissue Regenermentioning

confidence: 99%

“…Rather than 3D scaffolding architectures for bone regeneration, the PLGA biopolymer has been mainly considered and utilized to create nano-/micro-particles to deliver biologics such as growth factors, proteins, drugs, or cells to target tissues [ 78 , 111 , 122 , 123 , 124 , 125 , 126 ]. Moreover, PLGA-based, resorbable barrier membranes have been manufactured for guided bone regeneration (GBR) techniques, which prevent soft tissue infiltration and induce bone formation in defect sites in periodontal tissue engineering [ 118 , 127 , 128 , 129 , 130 ].…”

Section: Synthetic Biopolymers For Periodontal Hard Tissue Regenermentioning

confidence: 99%

Tooth-Supporting Hard Tissue Regeneration Using Biopolymeric Material Fabrication Strategies

Kim

Park

2020

Molecules

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The mineralized tissues (alveolar bone and cementum) are the major components of periodontal tissues and play a critical role to anchor periodontal ligament (PDL) to tooth-root surfaces. The integrated multiple tissues could generate biological or physiological responses to transmitted biomechanical forces by mastication or occlusion. However, due to periodontitis or traumatic injuries, affect destruction or progressive damage of periodontal hard tissues including PDL could be affected and consequently lead to tooth loss. Conventional tissue engineering approaches have been developed to regenerate or repair periodontium but, engineered periodontal tissue formation is still challenging because there are still limitations to control spatial compartmentalization for individual tissues and provide optimal 3D constructs for tooth-supporting tissue regeneration and maturation. Here, we present the recently developed strategies to induce osteogenesis and cementogenesis by the fabrication of 3D architectures or the chemical modifications of biopolymeric materials. These techniques in tooth-supporting hard tissue engineering are highly promising to promote the periodontal regeneration and advance the interfacial tissue formation for tissue integrations of PDL fibrous connective tissue bundles (alveolar bone-to-PDL or PDL-to-cementum) for functioning restorations of the periodontal complex.

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Advance of Nano-Composite Electrospun Fibers in Periodontal Regeneration

Cited by 70 publications

References 108 publications

Bioactive Membrane Immobilized with Lactoferrin for Modulation of Bone Regeneration and Inflammation

Bioactive Membrane Immobilized with Lactoferrin for Modulation of Bone Regeneration and Inflammation

Advanced technologies in periodontal tissue regeneration based on stem cells: Current status and future perspectives

Tooth-Supporting Hard Tissue Regeneration Using Biopolymeric Material Fabrication Strategies

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