Bone tissue engineering via application of a collagen/hydroxyapatite 4D-printed biomimetic scaffold for spinal fusion

Hwangbo, Hanjun; Lee, Hyeongjin; Roh, Eun Ji; Kim, Won Jin; Joshi, Hari Prasad; Kwon, Su Yeon; Choi, Un Yong; Han, Inbo; Kim, GeunHyung

doi:10.1063/5.0035601

Cited by 56 publications

(32 citation statements)

References 35 publications

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“…As such, G/H scaffolds fabricated in this study have a much lower modulus compared to natural bones. Similarly, previous reports have suggested that the main limitation of collagen or gelatin based hydroxyapatite is the low mechanical strength 8 . Lin et al, have reported that the 3D printed collagen/hydroxyapatite has the range of 0.09 ~ 0.15 MPa in the elastic modulus 39 , and Zhang et al, also reported that bulk gelatin/hydroxyapatite scaffolds have 0.2 MPa of maximum strength 60 .…”

Section: Resultsmentioning

confidence: 70%

“…Using the 3D printing method, the 3D specific architecture of the artificial bone matrix can be easily achieved. The controllability of pore geometries and internal pore structures can also provide sufficient spatial space for forming new blood vessels that are required to regenerate volumetric bone tissue and metabolic activities between the construct and the environment 8 . The highly personalizable strengths of the 3D printing can be adapted to bone defects with various types of structures, such as fully interconnected pore structure 9 , hierarchical structure 10 , fibrous structure 11 , and cell- or growth factors- laden structure 12 for bone tissue engineering.…”

Section: Introductionmentioning

confidence: 99%

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Highly elastic 3D-printed gelatin/HA/placental-extract scaffolds for bone tissue engineering

et al. 2022

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Bioengineering scaffolds have been improved to achieve efficient regeneration of various damaged tissues. In this study, we attempted to fabricate mechanically and biologically activated 3D printed scaffold in which porous gelatin/hydroxyapatite (G/H) as a matrix material provided outstanding mechanical properties with recoverable behavior, and human placental extracts (hPE) embedded in the scaffold were used as bioactive components. Methods: Various cell types (human adipose-derived stem cells; hASCs, pre-osteoblast; MC3T3-E1, human endothelial cell line; EA.hy926, and human dermal fibroblast; hDFs) were used to assess the effect of the hPE on cellular responses. High weight fraction (~ 70 wt%) of hydroxyapatite (HA) in a gelatin solution supplemented with glycerol was used for the G/H scaffold fabrication, and the scaffolds were immersed in hPE for the embedding (G/H/hPE scaffold). The osteogenic abilities of the scaffolds were investigated in cultured cells (hASCs) assaying for ALP activity and expression of osteogenic genes. For the in vivo test, the G/H and G/H/hPE scaffolds were implanted in the rat mastoid obliteration model. Results: The G/H/hPE scaffold presented unique elastic recoverable properties, which are important for efficient usage of implantable scaffolds. The effects of G/H and G/H/hPE scaffold on various in vitro cell-activities including non-toxicity, biocompatibility, and cell proliferation were investigated. The in vitro results indicated that proliferation (G/H = 351.1 ± 13.3%, G/H/hPE = 430.9 ± 8.7% at day 14) and expression of osteogenic markers ( ALP : 3.4-fold, Runx2 : 3.9-fold, BMP2 : 1.7-fold, OPN : 2.4-fold, and OCN : 4.8-fold at day 21) of hASCs grown in the G/H/hPE scaffold were significantly enhanced compared with that in cells grown in the G/H scaffold. In addition, bone formation was also observed in an in vivo model using rat mastoid obliteration. Conclusion: In vitro and in vivo results suggested that the G/H/hPE scaffold is a potential candidate for use in bone tissue engineering.

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Section: Resultsmentioning

confidence: 70%

Section: Introductionmentioning

confidence: 99%

Highly elastic 3D-printed gelatin/HA/placental-extract scaffolds for bone tissue engineering

et al. 2022

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“…These scaffolds showcased a 95.77% shape memory effect in the presence of a thermal stimulus, and its in vitro cytocompatibility and hydrophilic nature make it a potential candidate for customized biomedical applications. In a recent study, 116 a hierarchical biomimetic collagen/hydroxyapatite scaffold was prepared. The microchannels present in each strut of the biomimetic scaffold demonstrate significant in vitro osteogenic activity and increased bone formation and blood vessel ingrowth in vivo for spinal fusion in a mouse.…”

Section: D Resorbable Hap-based Scaffoldsmentioning

confidence: 99%

Multifunctional Hydroxyapatite Composites for Orthopedic Applications: A Review

George

Nayak

Singh

et al. 2022

ACS Biomater. Sci. Eng.

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Being a bioactive material, hydroxyapatite (HAp) is regarded as one of the most attractive ceramic biomaterials for bone and hard-tissue replacement and regeneration. Despite its substantial biocompatibility, osteoconductivity, and compositional similarity to that of bone, the employment of HAp is still limited in orthopedic applications due to its poor mechanical (low fracture toughness and bending strength) and antibacterial properties. These significant challenges lead to the notion of developing novel HAp-based composites via different fabrication routes. HAp, when efficaciously combined with functionally graded materials and antibacterial agents, like Ag, ZnO, Co, etc., form composites that render remarkable crack resistance and toughening, as well as enhance its bactericidal efficacy. The addition of different materials and a fabrication method, like 3D printing, greatly influence the porosity of the structure and, in turn, control cell adhesion, thereby enabling biological fixation of the material. This article encompasses an elaborate discussion on different multifunctional HAp composites developed for orthopedic applications with particular emphasis on the incorporation of functionally graded materials and antibacterial agents. The influence of 3D printing on the fabrication of HAp-based scaffolds, and the different in vitro and in vivo studies conducted on these, have all been included here. Furthermore, the present review not only provides insights and broad understanding by elucidating recent advancements toward 4D printing but also directs the reader to future research directions in design and application of HAp-based composite coatings and scaffolds.

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“…Microchannel-guided formation of aligned units has been utilized in a broad range of target tissues, including bone, nervous tissues, and vasculatures ( Daly et al, 2018 ; Huang et al, 2018 ; Lee et al, 2020 ; Hwangbo et al, 2021 ). Sacrificial hydrogels—deposited as a temporary structure for structural support or generation of certain structures—are often removed by variations in temperature once the crosslinking of the engineered construct is complete; therefore, they have been widely adopted in 3D bioprinting for establishing built-in channels.…”

Section: D Biofabrication Technologies In Skeletal Muscle Engineeringmentioning

confidence: 99%

Recent Trends in Biofabrication Technologies for Studying Skeletal Muscle Tissue-Related Diseases

Cho

Jang

2021

Front. Bioeng. Biotechnol.

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In native skeletal muscle, densely packed myofibers exist in close contact with surrounding motor neurons and blood vessels, which are embedded in the fibrous connective tissue. In comparison to conventional two-dimensional (2D) cultures, the three-dimensional (3D) engineered skeletal muscle models allow structural and mechanical resemblance with native skeletal muscle tissue by providing geometric confinement and physiological matrix stiffness to the cells. In addition, various external stimuli applied to these models enhance muscle maturation along with cell–cell and cell–extracellular matrix interaction. Therefore, 3D in vitro muscle models can adequately recapitulate the pathophysiologic events occurring in tissue–tissue interfaces inside the native skeletal muscle such as neuromuscular junction. Moreover, 3D muscle models can induce pathological phenotype of human muscle dystrophies such as Duchenne muscular dystrophy by incorporating patient-derived induced pluripotent stem cells and human primary cells. In this review, we discuss the current biofabrication technologies for modeling various skeletal muscle tissue-related diseases (i.e., muscle diseases) including muscular dystrophies and inflammatory muscle diseases. In particular, these approaches would enable the discovery of novel phenotypic markers and the mechanism study of human muscle diseases with genetic mutations.

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Bone tissue engineering via application of a collagen/hydroxyapatite 4D-printed biomimetic scaffold for spinal fusion

Cited by 56 publications

References 35 publications

Highly elastic 3D-printed gelatin/HA/placental-extract scaffolds for bone tissue engineering

Highly elastic 3D-printed gelatin/HA/placental-extract scaffolds for bone tissue engineering

Multifunctional Hydroxyapatite Composites for Orthopedic Applications: A Review

Recent Trends in Biofabrication Technologies for Studying Skeletal Muscle Tissue-Related Diseases

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