Haribabu V, Girigoswami K, Sharmiladevi P, Girigoswami A. Sharmiladevi P, Girigoswami K, Haribabu V, Girigoswami A. Efficient wormlike micelles for the controlled delivery of anticancer drugs. Sharmiladevi P, Breghatha M, Dhanavardhini K, Priya R, Girigoswami K, Girigoswami A. Membrane-encapsulated camouflaged nanomedicines in drug delivery. Excitation wavelength independent carbon decorated ferrite nanodots for multimodal diagnosis and stimuli responsive therapy. Sharmiladevi P, Akhtar N, Haribabu V, Girigoswami K, Chattopadhyay S, Girigoswami A. Camouflaged nanosilver with excitation wavelength dependent high quantum yield for targeted theranostic. Girigoswami A, Yassine W, Sharmiladevi P, Haribabu V, Girigoswami K. Influence of divalent cation on morphology and drug delivery efficiency of mixed polymer nanoparticles. 2021 21(1):12–26.ĭeepika R, Girigoswami K, Murugesan R, Girigoswami A. A review on role of nanosensors in detecting cellular miRNA expression in colorectal cancer. ZnO nanoflower based sensitive nano-biosensor for amyloid detection. 2019 19: 101124.Īkhtar N, Metkar SK, Girigoswami A, Girigoswami K. Cerium oxide nanocluster based nanobiosensor for ROS detection. Thendral V, Dharshni T, Ramalakshmi M, Girigoswami A, Girigoswami K. Diagnostic biosensors in medicine- a review. Nanobiosensors and fluorescence based biosensors: an overview. Scaffolding strategies for tissue engineering and regenerative medicine applications. Pina S, Ribeiro VP, Marques CF, Maia FR, Silva TH, Reis RL, Oliveira JM. Nanoparticles in tissue engineering: applications, challenges and prospects. Hasan A, Morshed M, Memic A, Hassan S, Webster TJ, Marei HE. Chitosan: application in tissue engineering and skin grafting. Introduction to tissue engineering, Tissue engineering for artificial organs: regenerative medicine, smart diagnostics and personalized medicine. Papers of particular interest, published recently, have been highlighted as: Osteoblast precursor cells MG-63 cell lines: Human osteoblastic cells MC3T3 cell lines: Wharton’s jelly–derived mesenchymal stem cell microtissue ALP:Īdipose tissue–derived mesenchymal stem cells hFOB cells: Human dental pulp–derived stem cells CMC: Poly(vinyl alcohol)-gellan gum nanofiber SEM:įourier transformation infrared spectroscopy hDPSCs: Human coronary artery endothelial cells PHAs: Polymorphonuclear leukocytes BMP-2 peptide: This article portrays the functional scaffolds used in different kinds of tissue engineering such as bone, liver, cartilage, vascular tissue, skin and cardiac tissue, etc., and an overview of various types of materials used in scaffolding for the tissue engineering applications and future aspects is discussed. Natural bioscaffolds have also been used for growing cells and regenerative biology. Different synthesis methods are being employed to engineer the scaffolds, such as electrospinning, layer-by-layer assembly, 3D printing, particle leaching etc. Nanoscaffolding is known to be a clinical cycle used to regrow bone and tissue, including appendages and organs likewise, it has been utilized to regrow the skin, but it has not been utilized yet for the development of complex organs like the heart etc. Pubmed and Google Scholar are the search engines used to sort out relevant papers on nanoscaffolds and their application in tissue engineering and regenerative medicine. Signals, cells, and scaffolds are triad components of tissue engineering that combine to produce functional tissue and organs. The emerging field of tissue engineering aims to recover injured tissues by consolidating cells from the host body or donor’s body with exceptionally porous scaffold biomaterials that can act as a template for tissue recovery, to control the development of new tissue. Consistently, a huge number of surgeries are performed to supplant tissue which is damaged through infection or injury.
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