Polydopamine coating promotes early osteogenesis in 3D printing porous Ti6Al4V scaffolds

Li, Lan; Li, Yixuan; Lijun, Yang; Yu, Fei; Zhang, Kaijia; Jin, Jing; Shi, Jianping; Zhu, Linli; Liang, Huixin; Wang, Xingsong; Jiang, Qing

doi:10.21037/atm.2019.04.79

Cited by 45 publications

(35 citation statements)

References 63 publications

(73 reference statements)

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“…Researchers further explored HA in the form of composites, with studies reporting improved bone ingrowth for HA doped with magnesium, 49 polydopamine, 45 silicon, 59 or strontium 59 compared to uncoated controls, though the silicon and strontium groups did not show the same improvement when compared to undoped HA coatings 59 . Aside from HA, polydopamine coatings, 48,52 titanium copper and titanium copper nitride films, 37 growth factor‐doped fibrin glue, 51 and strontium‐laden nanotube coatings 55 also showed success in increasing 3DP pTi bioactivity. Instead of coatings, one study by Li et al used surface heat treatments to induce material phase transformations, 53 reporting that samples treated at 950 and 1000°C were associated with higher rates of bone formation, thicker bone trabeculae, and greater push‐out loads 53 .…”

Section: Discussionmentioning

confidence: 99%

A systematic review of preclinical in vivo testing of 3D printed porous Ti6Al4V for orthopedic applications, part I: Animal models and bone ingrowth outcome measures

et al. 2021

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For Ti6Al4V orthopedic and spinal implants, osseointegration is often achieved using complex porous geometries created via additive manufacturing (AM). While AM porous titanium (pTi) has shown clinical success, concerns regarding metallic implants have spurred interest in alternative AM biomaterials for osseointegration. Insights regarding the evaluation of these new materials may be supported by better understanding the role of preclinical testing for AM pTi. We therefore asked: (a) What animal models have been most commonly used to evaluate AM porous Ti6Al4V for orthopedic bone ingrowth; (b) What were the primary reported quantitative outcome measures for these models; and (c) What were the bone ingrowth outcomes associated with the most frequently used models? We performed a systematic literature search and identified 58 articles meeting our inclusion criteria. We found that AM pTi was evaluated most often using rabbit and sheep femoral condyle defect (FCD) models. Additional ingrowth models including transcortical and segmental defects, spinal fusions, and calvarial defects were also used with various animals based on the study goals. Quantitative outcome measures determined via histomorphometry including ''bone ingrowth'' (range: 3.92–53.4% for rabbit/sheep FCD) and bone‐implant contact (range: 9.9–59.7% for rabbit/sheep FCD) were the most common. Studies also used 3D imaging to report outcomes such as bone volume fraction (BV/TV, range: 4.4–61.1% for rabbit/sheep FCD), and push‐out testing for outcomes such as maximum removal force (range: 46.6–3092 N for rabbit/sheep FCD). Though there were many commonalities among the study methods, we also found significant heterogeneity in the outcome terms and definitions. The considerable diversity in testing and reporting may no longer be necessary considering the reported success of AM pTi across all model types and the ample literature supporting the rabbit and sheep as suitable small and large animal models, respectively. Ultimately, more standardized animal models and reporting of bone ingrowth for porous AM materials will be useful for future studies.

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Section: Discussionmentioning

confidence: 99%

A systematic review of preclinical in vivo testing of 3D printed porous Ti6Al4V for orthopedic applications, part I: Animal models and bone ingrowth outcome measures

et al. 2021

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“…For bone regeneration, a scaffold should be biodegradable and biocompatible, as well as having osteoconductive, osteoinductive, and osteogenic properties ( 4 ). In addition, it is desirable that it provides an appropriate exchange of nutrients, promotes vascularization and bone ingrowth, and has a pore size ranging from 100 to 500 µm ( 5 ).…”

Section: Degradable Biomaterials For Bone Regeneration In Orthopedicsmentioning

confidence: 99%

Biomaterials for bone regeneration: an orthopedic and dentistry overview

Girón

Kerstner

Medeiros

et al. 2021

Braz J Med Biol Res

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Because bone-associated diseases are increasing, a variety of tissue engineering approaches with bone regeneration purposes have been proposed over the last years. Bone tissue provides a number of important physiological and structural functions in the human body, being essential for hematopoietic maintenance and for providing support and protection of vital organs. Therefore, efforts to develop the ideal scaffold which is able to guide the bone regeneration processes is a relevant target for tissue engineering researchers. Several techniques have been used for scaffolding approaches, such as diverse types of biomaterials. On the other hand, metallic biomaterials are widely used as support devices in dentistry and orthopedics, constituting an important complement for the scaffolds. Hence, the aim of this review is to provide an overview of the degradable biomaterials and metal biomaterials proposed for bone regeneration in the orthopedic and dentistry fields in the last years.

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“…[158] Although 100 μm is acceptable, a pore size of at least 300 μm is suggested for new bone formation, [159] and the pore size of 400 μm is optimal for vascularization during osteogenesis. [160] A specialized study showed that scaffold pore sizes larger than 390 μm with upper limit of 590 μm are more able to enhance bone tissue formation. [161] The strut thickness and microporosity can also affect the cell penetration and tissue ingrowth in the scaffold.…”

Section: Correlation Between Pore Characteristics and Scaffold Propertiesmentioning

confidence: 99%

How Does Scaffold Porosity Conduct Bone Tissue Regeneration?

et al. 2021

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Despite progresses in tissue healing, repairing large bone defects remains an unmet challenge. Tissue engineering (TE) using porous scaffolds offers great promise in providing solutions by which bone healing can be increased, and the need for further surgical intervention can be reduced. Nonetheless, the successful performance of a porous scaffold depends on key structural factors including porosity, pore size, geometry, and interconnectivity. Herein, recent advancements on this topic are reviewed and the effects of fabrication methods on making potential scaffolds for advanced bone regeneration are discussed.The upward trend of population aging, increased numbers of accidents, sport injuries, trauma, and bone tumor resection are increasing the demand for substitutes to regenerate and/or repair damaged skeletal and dental bones. [1] Bone tissue poses a simple yet highly organized ultracomposition in which each portion plays a pivotal role in moderating the elasticity and strength of the bone. [2] The intrinsically dynamic bone tissue structure allows the restoration of damaged parts via the self-healing process. [3] This remodeling process is dependent on the dynamic equilibrium between the bone-forming (osteoblast) and bone-resorbing cells (osteoclast) during mechanical stimulation. [4] Nevertheless, this healing process is not sufficient for repairing massive and critical bone defects; thus, there is a need for drastic healing accelerators and substitutive or supportive therapeutics. [5] Specially, the regenerating of large bone defects is a serious and challenging clinical issue. To address the issue, different types of bone graft substitutes such as autografts, allografts, and xenografts are used. [6] These grafts, however, come with certain drawbacks, including donor site morbidity and limited supply. Moreover, aged persons cannot provide rich bone tissue for their own tissue replacement due to osteoporosis. [7] To address the limitations associated with natural bone-derived substitutes, biomaterials have been developed during recent decades. [8] Engineering biomaterials made it possible to simulate the bone microenvironment and construct programmable scaffolds for purposeful therapeutic procedures. Bioactive ceramic materials are favorable for bone tissue engineering (BTE) due to their resemblance to the mineral phase of bone, and direct bonding with host bone tissue without the formation of fibrous tissue. In addition, the variety in the chemical composition of bioceramics, particularly silicate-based ceramics (SiCa), can contribute to adjustments in mechanical properties, bioactivity, and biodegradability.A fundamental constituent of engineering tissue is the scaffold, which acts as the structural template providing a suitable substrate for cell proliferation, differentiation, and attachment resulting in new tissue formation. In tissue engineering (TE), the scaffold serves as the structural guide and the substrate for cell anchorage. The scaffold also contributes to the remodeling of the extracellular mat...

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Polydopamine coating promotes early osteogenesis in 3D printing porous Ti6Al4V scaffolds

Cited by 45 publications

References 63 publications

A systematic review of preclinical in vivo testing of 3D printed porous Ti6Al4V for orthopedic applications, part I: Animal models and bone ingrowth outcome measures

A systematic review of preclinical in vivo testing of 3D printed porous Ti6Al4V for orthopedic applications, part I: Animal models and bone ingrowth outcome measures

Biomaterials for bone regeneration: an orthopedic and dentistry overview

How Does Scaffold Porosity Conduct Bone Tissue Regeneration?

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