Pavan Kumar Srivas

Carbon nanodots from date molasses: new nanolights for the in vitro scavenging of reactive oxygen species

Most of the nanoimaging tools like quantum dots and metallic nanoparticles are shown to have different levels of cytotoxicity via various mechanisms. However carbon nanodots (CNDs) are a new group of ultra small nano structures (average 4-6 nm) which is potential candidate of next generation optical imaging. Being carbonaceous in origin, CNDs possess excellent luminescence and photostability with significantly less cytotoxicity. In present study, we have synthesized carbon nano-dots from date molasses by microwave irradiation at ∼pH 11. The synthesized carbon nanodots were characterized using UV-Vis spectroscopy, fluorescence spectroscopy, TEM, XRD analysis, FTIR study and Zeta potential measurement. The average sizes of the dots were found to be 5-7 nm. A clear band emission was visible around 480 nm when an excitation beam of 415 nm was incident. For biological applicability, MTT assay and hemocompatibility studies were performed. The results exhibited the material to be highly cytocompatible within the application limit. Upon immediate exposure to CNDs, no significant changes to cellular surface morphology were observed via AFM imaging. Significant hemolysis or blood cell aggregation was not observed after incubation of CNDs with blood. After labelling with CNDs, MG-63 cells were found to be unbleached up to several hours even on exposure to light. We are reporting first time in this study the free radical scavenging property of CNDs in ex vivo and in vitro models. Antioxidant activity was measured ex vivo via potassium permanganate assay and DPPH assay. In vitro superoxide inhibition activity was measured both by spectroscopy and under microscope by NBT reduction assay. Hydroxyl free radical inhibition activity was measured via DCFH-DA Assay. The results were comparable with scavenging activity of standard antioxidant molecules (BHT and l-ascorbic acid). A novel assay for quantitative analysis of cellular oxidative stress was also proposed. Therefore, this material could be useful for long-term live cell imaging and cell tracking in a scaffold with minimal cytotoxicity and oxidative stress.

A Simple Approach for an Eggshell-Based 3D-Printed Osteoinductive Multiphasic Calcium Phosphate Scaffold

Natural origin bioceramics are widely used for bone grafts. In the present study, an eggshell-derived bioceramic scaffold is fabricated by 3D printing as a potential bone-graft analogue. The eggshell, a biological waste material, was mixed with a specific ratio of phosphoric acid and chitosan to form a precursor toward the fabrication of an osteoinductive multiphasic calcium phosphate scaffold via a coagulation-assisted extrusion and sintering for a multiscalar hierarchical porous structure with improved mechanical properties. Physicochemical characterization of the formed scaffolds was carried out for phase analysis, surface morphology, and mechanical properties. A similar scaffold was prepared using a chemically synthesized calcium phosphate powder that was compared with the natural origin one. The higher surface area associated with the interconnected porosity along with multiple phases of the natural origin scaffold facilitated higher cell adhesion and proliferation compared to the chemically synthesized one. Further, the natural origin scaffold displayed relatively higher cell differentiation activity, as is evident by protein and gene expression studies. On subcutaneous implantation for 30 days, promising vascular tissue in-growth was observed, circumventing a major foreign body response. Collagen-rich vascular extracellular matrix deposition and osteocalcin secretion indicated bonelike tissue formation. Finally, the eggshell-derived multiphasic calcium phosphate scaffold displayed improvement in the mechanical properties with higher porosity and osteoinductivity compared to the chemically derived apatite and unveiled a new paradigm for utilization of biological wastes in bone-graft application.

Accelerating full thickness wound healing using collagen sponge of mrigal fish (Cirrhinus cirrhosus) scale origin

The potentiality of collagen sponge as a skin substitute, derived from mrigal (Cirrhinus cirrhosus) scale has been explored in this study. Acid soluble collagen (ASC) and pepsin soluble collagen (PSC) from the scale of mrigal were isolated and characterized. The yields of ASC and PSC were ∼3% and ∼7% based on the dry weight of scale while the hydroxyproline content was ∼90mg/g. Scanning electron microscope revealed progressive demineralization with EDTA on time dependent scale. Further, the D-Spacing in fibril bundles were calculated to be ∼67nm. Fourier transform infrared and circular dichroism spectra confirmed extracted protein to be collagen I, where both ASC and PSC comprised of two different α-chains (α1 and α2). The denaturation temperature (Td) of the collagen solution was 35°C closer to Td of mammalian collagen. In vitro cell culture studies on the extracted collagen sponge showed efficient cell growth and proliferation. Additionally, co-culture with fibroblast and keratinocyte cells showed development of stratified epidermal layer in vitro. Faster wound healing potential of the extracted collagen in a rat model proved its applicability as a dermal substitute.

Influence of Porosity and Pore-Size Distribution in Ti6Al4 V Foam on Physicomechanical Properties, Osteogenesis, and Quantitative Validation of Bone Ingrowth by Micro-Computed Tomography

Cementless fixation for orthopedic implants aims to obviate challenges associated with bone cement, providing long-term stability of bone prostheses after implantation. The application of porous titanium and its alloy-based implants is emerging for load-bearing applications due to their high specific strength, low stiffness, corrosion resistance, and superior osteoconductivity. In this study, coagulant-assisted foaming was utilized for the fabrication of porous Ti6Al4 V using egg-white foam. Samples with three different porosities of 68.3%, 75.4%, and 83.1% and average pore sizes of 92, 178, and 297 μm, respectively, were prepared and subsequently characterized for mechanical properties, osteogenesis, and tissue ingrowth. A microstructure-mechanical properties relationship study revealed that an increase of porosity from 68.3 to 83.1% increased the average pore size from 92 to 297 μm with the subsequent reduction of compresive strength by 85% and modulus by 90%. Samples with 75.4% porosity and a 178 μm average pore size produced signifcant osteogenic effects on human mesenchymal stem cells, which was further supported by immunocytochemistry and real-time polymerase chain reaction data. Quantitative assessment of bone ingrowth by micro-computed tomography revealed that there was an approximately 52% higher bone formation and more than 90% higher bone penetration at the center of femoral defects in rabbit when implanted with Ti6Al4 V foam (75.4% porosity) compared to the empty defects after 12 weeks. Hematoxylin and eosin (H&E) and Masson trichrome (MT) staining along with energy-dispersive X-ray mapping on the sections obtained from the retrieved bone samples support bone ingrowth into the implanted region.

Simultaneous hydrothermal bioactivation with nano-topographic modulation of porous titanium alloys towards enhanced osteogenic and antimicrobial responses

Post-implantation failure associated with insufficient host tissue integration at the bone-implant interface and aseptic loosening is a major concern in orthopaedics as well as in dentistry. To overcome the failure in early stages of implantation, prosthetic design combining the mechanisms of porosity guided bone ingrowth along with topographic manipulation of osteogenic cells over bacterial colonization would be an ideal choice, although achieving such a goal is highly challenging. In this study, facile rapid hydrothermal synthesis of nanostructures with simultaneous deposition of hydroxyapatite on the titanium alloy surface was demonstrated by using an aqueous sodium tripolyphosphate and calcium hydroxide mixture. Nanostructures with wire-like morphology exhibited significantly higher osteogenic related gene expression (COL I, OPN, and OCN) through differentiation of adipose derived mesenchymal stem cells as well as the bactericidal response against S. aureus and E. coli as compared to other nanotopographic features. The same also exhibited elongated cell morphology with the highest expression of paxillin towards cell boundaries as compared to the polished surface with flattened cell morphology and localized expression of paxillin around the nucleus. Implantation of treated porous Ti6Al4V samples representing a multiscalar hierarchy with wire-like nanostructures accelerated osteochondral healing in rabbits without any major signs of infection. Also, significantly higher bone formation was observed within the defects implanted with treated porous Ti6Al4V (44.0%) as compared to that of untreated porous samples (36.9%) as well as empty defects (19.6%).