Browsing by Author "Ameer, JM"

Now showing 1 - 4 of 4
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    Fabrication of co-cultured tissue constructs using a dual cell seeding compatible cell culture insert with a clip-on scaffold for potential regenerative medicine and toxicological screening application
    (Journal of Science: Advanced Materials and Devices, 2020-06) Ameer, JM; Ramesh Babu, V; Vinod, D; Nishad, KV; Sabareeswaran, A; Anil Kumar, PR; Kasoju, N
    Tissue engineering is emerging as a modern medicine fascination towards the establishment of human tissue banks; yet, these approaches typically involve cultures of only one type of cell and, therefore, do not recapitulate the native tissue physiology in toto. Co-culture models, comprised of different cell types, can potentially create the next level of complexity. However, conventional approaches involving multiple cell types and cell culture inserts do have limitations. To this end, here we demonstrate a novel cell culture insert that allows the use of any custom-made scaffold, free-flow of fluids/gases, dual cell seeding on either sides of the insert, easy stacking of multiple inserts and resizing it to any multi-well plate format as well as culture dishes. To prove the concept, electrospun silk fibroin scaffold was clipped onto the insert and was used for co-culturing of keratinocytes and fibroblast cells. The results indicated a successful fabrication of spatially organized skin tissue constructs having epidermal and dermal equivalent histology. Cell-laden inserts were stacked and used for simulated transportation studies. However, the conditions need further fine-tuning. All together, the results indicated that the novel cell culture insert with silk fibroin scaffold could be used as a facile, versatile and scalable approach to fabricate and transport 3D co-cultured tissue constructs in vitro, including but not limited to skin. The resultant tissue constructs can be explored for therapeutic applications, for instance as artificial skin substitute in wound healing, and for toxicological applications, for instance as reconstructed skin tissue model in skin irritation testing.
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    A gold nano particle coated porcine cholecyst-derived bio scaffold for cardiac tissue engineering
    (Colloids and surfaces: B Biointerfaces, 2017-06) Nair, RS; Ameer, JM; Alison, MR; Anilkumar, TV
    Extracellular matrices of xenogeneic origin have been extensively used for biomedical applications, despite the possibility of heterogeneity in structure. Surface modification of biologically derived biomaterials using nanoparticles is an emerging strategy for improving topographical homogeneity when employing these scaffolds for sophisticated tissue engineering applications.Recently, as a tissue engineering scaffold, cholecyst derived extracellular matrix (C-ECM) has been shown to have several advantages over extracellular matrices derived from other organs such as jejunum and urinary bladder. This study explored the possibility of adding gold nanoparticles, which have a large surface area to volume ratio on C-ECM for achieving homogeneity in surface architecture, a requirement for cardiac tissue engineering. In the current study, gold nanoparticles (AuNPs) were synthesized and functionalised for conjugating with a porcine cholecystic extracellular matrix scaffold. The conjugation of nanoparticles to C-ECM was achieved by 1-ethyl-3-(3-dimethyl aminopropyl)-carbodiimide/N-hydroxysuccinimide chemistry and further characterized by Fourier transform infrared spectroscopy, environmental scanning electron microscopy, energy dispersive X-ray spectroscopy and thermogravimetric analysis. The physical properties of the modified scaffold were similar to the original C-ECM. Biological properties were evaluated by using H9c2 cells, a cardiomyoblast cell line commonly used for cellular and molecular studies of cardiac cells. The modified scaffold was found to be a suitable substrate for the growth and proliferation of the cardiomyoblasts. Further, the non-cytotoxic nature of the modified scaffold was established by direct contact cytotoxicity testing and live/dead staining. Thus, the modified C-ECM appears to be a potential biomaterial for cardiac tissue engineering.
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    Optically Clear Silk Fibroin Films with Tunable Properties for Potential Corneal Tissue Engineering Applications: A Process–Property–Function Relationship Study
    (ACS Omega, 2022-08) Beena, M; Ameer, JM; Kasoju, N
    Owing to the shortage of donor corneas and issues associated with conventional corneal transplantation, corneal tissue engineering has emerged as a promising therapeutic alternative. Biocompatibility and other attractive features make silk fibroin a biomaterial of choice for corneal tissue engineering applications. The current study presents three modes of silk fibroin film fabrication by solvent casting with popular solvents, viz. aqueous (aq), formic acid (FA), and hexafluoroisopropanol (HFIP), followed by three standard modes of postfabrication annealing with water vapor, methanol vapor, and steam, and systematic characterization studies including corneal cell culture in vitro. The results indicated that silk fibroin films made from aq, FA, and HFIP solvents had surface roughness (Rq) of 1.39, 0.32, and 0.13, contact angles of 73°, 85°, and 89°, water uptake% of 58, 29, and 27%, swelling ratios of 1.58, 1.3, and 1.28, and water vapor transmission% of 39, 26, and 22%, respectively. The degradation rate was in the order of aq > HF > FA, whereas the tensile strength was in the order of aq < HF < FA. Further, the results of the annealing process indicated notable changes in morpho-topographical, physical, degradation, and tensile properties. However, the films showed no detectable changes in chemical composition and remained optically clear with >90% transmission in the visible range, irrespective of fabrication and postfabrication processing conditions. The films were noncytotoxic against L929 cells and were cytocompatible with rabbit cornea-derived SIRC cells in vitro. The study demonstrated the potential of fine-tuning various properties of silk fibroin films by varying the fabrication and postfabrication processing conditions.
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    Strategies to tune electrospun scaffold porosity for effective cell response in tissue engineering
    (J. Funct. Biomater, 2019-07) Ameer, JM; Anilkumar, PR; Kasoju, N
    Tissue engineering aims to develop artificial human tissues by culturing cells on a scaffold in the presence of biochemical cues. Properties of scaffold such as architecture and composition highly influence the overall cell response. Electrospinning has emerged as one of the most affordable, versatile, and successful approaches to develop nonwoven nano/microscale fibrous scaffolds whose structural features resemble that of the native extracellular matrix. However, dense packing of the fibers leads to small-sized pores which obstruct cell infiltration and therefore is a major limitation for their use in tissue engineering applications. To this end, a variety of approaches have been investigated to enhance the pore properties of the electrospun scaffolds. In this review, we collect state-of-the-art modification methods and summarize them into six classes as follows: approaches focused on optimization of packing density by (a) conventional setup, (b) sequential or co-electrospinning setups, (c) involving sacrificial elements, (d) using special collectors, (e) post-production processing, and (f) other specialized methods. Overall, this review covers historical as well as latest methodologies in the field and therefore acts as a quick reference for those interested in electrospinning matrices for tissue engineering and beyond