Pradeep Kumar scite author profile

This letter describes a simple surface modification strategy based on a single-step electrochemical anodization towards generating dual micro- and nano-rough horizontally-aligned TiO nanopores on the surface of clinically utilized micro-grooved titanium implants. Primary macrophages, osteoblasts and fibroblasts were cultured on the nano-engineered implants, and it was demonstrated that the modified surfaces selectively reduced the proliferation of macrophages (immunomodulation), while augmenting the activity of osteoblasts (osseo-integration) and fibroblasts (soft-tissue integration). Additionally, the mechanically robust nanopores also stimulated osteoblast and fibroblast adhesion, attachment and alignment along the direction of the pores/grooves, while macrophages remained oval-shaped and sparsely distributed. This study for the first time reports the use of cost-effectively prepared nano-engineered titanium surface via anodization, with aligned multi-scale micro/nano features for selective cellular bioactivity, without the use of any therapeutics.

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Anodized anisotropic titanium surfaces for enhanced guidance of gingival fibroblasts

Gulati

Moon

Kumar

et al. 2020

Materials Science and Engineering: C

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A composite chitosan-gelatin bi-layered, biomimetic macroporous scaffold for blood vessel tissue engineering

Badhe

Bijukumar

Chejara

et al. 2017

Carbohydrate Polymers

115

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Additively manufactured biphasic construct loaded with BMP-2 for vertical bone regeneration: A pilot study in rabbit

Kumar

Hashimi

Saifzadeh

et al. 2018

Materials Science and Engineering: C

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Vertical bone augmentation of the jaws is required when the height of bone is insufficient at the site of dental implant placement. In this proof of concept study, we investigated the potential of a biphasic polycaprolactone construct combined with a hyaluronic acid based hydrogel loaded with recombinant human bone morphogenetic growth factor-2 (BMP-2) for vertical bone regeneration. The biphasic scaffold consisted of an outer shell manufactured by fused deposition modelling, mimicking native cortical bone and providing mechanical and space maintenance properties essential for bone formation. Within this shell, a 90% porous melt electrospun microfibrous mesh mimicking the architecture of cancellous bone was incorporated in order to facilitate hydrogel loading and subsequent osteogenesis and angiogenesis. The in vitro performances of the biphasic construct demonstrated that BMP-2 was released in a sustained manner over several weeks and that cell viability was maintained in the hydrogel over 21 days. qRT-PCR demonstrated the upregulation of bone markers such as osteopontin, osteocalcin and collagen 1A1 at day 3 and 14 in the constructs loaded with BMP2. In vivo assessment of the biphasic scaffold was performed using a dose of 30 μg of BMP-2 in a rabbit calvarial vertical bone augmentation model. The histology and micro-CT analysis of the elevated space demonstrated that the hydrogel and the presence of BMP-2 enabled bone formation. However, this was limited to the immediate vicinity of the calvarial bone. The amount of newly formed bone was relatively small which was likely due to poor vascularisation of the extraskeletal space. The utilisation of this biomimetic biphasic construct with excellent space maintenance properties can be of interest in dentistry although the in vivo model requires refinement to demonstrated appropriate efficacy.

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Surface Modification of 3D Printed Polycaprolactone Constructs via a Solvent Treatment: Impact on Physical and Osteogenic Properties

Kosik-Kozioł

Graham

Jaroszewicz

et al. 2018

ACS Biomater. Sci. Eng.

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One promising strategy to reconstruct bone defects relies on 3D printed porous structures. In spite of several studies having been carried out to fabricate controlled, interconnected porous constructs, the control over surface features at, or below, the microscopic scale remains elusive for 3D polymeric scaffolds. In this study, we developed and refined a methodology which can be applied to homogeneously and reproducibly modify the surface of polymeric 3D printed scaffolds. We have demonstrated that the combination of a polymer solvent and the utilization of ultrasound was essential for achieving appropriate surface modification without damaging the structural integrity of the construct. The modification created on the scaffold profoundly affected the macroscopic and microscopic properties of the scaffold with an increased roughness, greater surface area, and reduced hydrophobicity. Furthermore, to assess the performance of such materials in bone tissue engineering, human mesenchymal stem cells (hMSC) were cultured in vitro on the scaffolds for up to 7 days. Our results demonstrate a stronger commitment toward early osteogenic differentiation of hMSC. Finally, we demonstrated that the increased in the specific surface area of the scaffold did not necessarily correlate with improved adsorption of protein and that other factors, such as surface chemistry and hydrophilicity, may also play a major role.

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Pradeep Kumar

Titania nanopores with dual micro-/nano-topography for selective cellular bioactivity

Anodized anisotropic titanium surfaces for enhanced guidance of gingival fibroblasts

A composite chitosan-gelatin bi-layered, biomimetic macroporous scaffold for blood vessel tissue engineering

Additively manufactured biphasic construct loaded with BMP-2 for vertical bone regeneration: A pilot study in rabbit

Surface Modification of 3D Printed Polycaprolactone Constructs via a Solvent Treatment: Impact on Physical and Osteogenic Properties

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