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Research
  1. Queen Mary University of London
  2. Research
  3. Publications

Publications: Dr Swati Midha

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Hopkins T, Midha S, Grossemy S, Screen HRC, Wann AKT, Knight MM ( 2025 ) . Engineering growth factor gradients to drive spatiotemporal tissue patterning in organ-on-a-chip systems . Journal of Tissue Engineering vol. 16 ,
Santos-Beato P, Midha S, Pitsillides AA, Miller A, Torii R, Kalaskar DM ( 2022 ) . Biofabrication of the osteochondral unit and its applications: Current and future directions for 3D bioprinting . Journal of Tissue Engineering vol. 13 ,
Ajam Y, Midha S, Tan ACW, Blunn G, Kalaskar DM ( 2021 ) . Design and In Vivo Testing of Novel Single-Stage Tendon Graft Using Polyurethane Nanocomposite Polymer for Tendon Reconstruction . Journal of Plastic Reconstructive & Aesthetic Surgery vol. 75 , ( 4 ) 1467 - 1475 .
Topsakal A, Midha S, Yuca E, Tukay A, Sasmazel HT, Kalaskar DM, Gunduz O ( 2021 ) . Study on the cytocompatibility, mechanical and antimicrobial properties of 3D printed composite scaffolds based on PVA/ Gold nanoparticles (AuNP)/ Ampicillin (AMP) for bone tissue engineering . Materials Today Communications vol. 28 ,
Wadhwa S, Roy S, Mittal N, John AT, Midha S, Mohanty S, Vasanthan KS, Mathur A et al. ( 2021 ) . Self – aligned mesoporous titania nanotubes – reduced graphene oxide hybrid surface: A potential scaffold for osteogenesis . International Journal of Materials Research (formerly Zeitschrift fuer Metallkunde) vol. 112 , ( 7 ) 584 - 590 .
Ulag S, Uysal E, Bedir T, Sengor M, Ekren N, Ustundag CB, Midha S, Kalaskar DM et al. ( 2021 ) . Recent developments and characterization techniques in 3D printing of corneal stroma tissue . Polymers for Advanced Technologies vol. 32 , ( 8 ) 3287 - 3296 .
Selim OA, Lakhani S, Midha S, Mosahebi A, Kalaskar DM ( 2021 ) . Three-Dimensional Engineered Peripheral Nerve: Toward a New Era of Patient-Specific Nerve Repair Solutions . Tissue Engineering Part B Reviews vol. 28 , ( 2 ) 295 - 335 .
Chauhan A, Midha S, Kumar R, Meena R, Singh P, Jha SK, Kuanr BK ( 2021 ) . Rapid tumor inhibition via magnetic hyperthermia regulated by caspase 3 with time-dependent clearance of iron oxide nanoparticles . Biomaterials Science vol. 9 , ( 8 ) 2972 - 2990 .
Midha S, sybill D ( 2020 ) . Advances in Dental Implantology using Nanomaterials and Allied Technology Applications . Advances in Dental Implantology using Nanomaterials and Allied Technology Applications , Springer Nature
Midha S, Jain KG, Bhaskar N, Kaur A, Rawat S, Giri S, Basu B, Mohanty S ( 2020 ) . Tissue-specific mesenchymal stem cell-dependent osteogenesis in highly porous chitosan-based bone analogs . Stem Cells Translational Medicine vol. 10 , ( 2 ) 303 - 319 .
Kaur A, Midha S, Giri S, Mohanty S ( 2019 ) . Functional Skin Grafts: Where Biomaterials Meet Stem Cells . Stem Cells International vol. 2019 , ( 1 )
Midha S, Dalela M, Sybil D, Patra P, Mohanty S ( 2019 ) . Advances in three‐dimensional bioprinting of bone: Progress and challenges . Journal of Tissue Engineering and Regenerative Medicine vol. 13 , ( 6 ) 925 - 945 .
Kanhed S, Awasthi S, Midha S, Nair J, Nisar A, Patel AK, Pandey A, Sharma R et al. ( 2018 ) . Microporous Hydroxyapatite Ceramic Composites as Tissue Engineering Scaffolds: An Experimental and Computational Study . Advanced Engineering Materials vol. 20 , ( 7 )
Pandey A, Midha S, Sharma RK, Maurya R, Nigam VK, Ghosh S, Balani K ( 2018 ) . Antioxidant and antibacterial hydroxyapatite-based biocomposite for orthopedic applications . Materials Science and Engineering C vol. 88 , 13 - 24 .
Midha S, Chawla S, Chakraborty J, Chameettachal S, Ghosh S ( 2018 ) . Differential Regulation of Hedgehog and Parathyroid Signaling in Mulberry and Nonmulberry Silk Fibroin Textile Braids . ACS Biomaterials Science & Engineering vol. 4 , ( 2 ) 595 - 607 .
Chawla S, Midha S, Sharma A, Ghosh S ( 2018 ) . Silk‐Based Bioinks for 3D Bioprinting . Advanced Healthcare Materials vol. 7 , ( 8 )
Midha S, ghosh S ( 2017 ) . Silk-based bioinks for 3D bioprinting . Regenerative Medicine: Laboratory to Clinic , Springer
Midha S, Chameettachal S, Dey E, Ghosh S ( 2017 ) . Nonmulberry Silk Braids Direct Terminal Osteocytic Differentiation through Activation of Wnt-Signaling . ACS Biomaterials Science & Engineering vol. 3 , ( 6 ) 1062 - 1074 .
Chameettachal S, Midha S, Ghosh S ( 2016 ) . Regulation of Chondrogenesis and Hypertrophy in Silk Fibroin-Gelatin-Based 3D Bioprinted Constructs . ACS Biomaterials Science & Engineering vol. 2 , ( 9 ) 1450 - 1463 .
Midha S, Tripathi R, Geng H, Lee PD, Ghosh S ( 2016 ) . Elucidation of differential mineralisation on native and regenerated silk matrices . Materials Science and Engineering C vol. 68 , 663 - 674 .
Midha S, Murab S, Ghosh S ( 2016 ) . Osteogenic signaling on silk-based matrices . Biomaterials vol. 97 , 133 - 153 .
Nara S, Chameettachal S, Midha S, Murab S, Ghosh S ( 2016 ) . Preservation of biomacromolecular composition and ultrastructure of a decellularized cornea using a perfusion bioreactor . RSC Advances vol. 6 , ( 3 ) 2225 - 2240 .
Melke J, Midha S, Ghosh S, Ito K, Hofmann S ( 2015 ) . Silk fibroin as biomaterial for bone tissue engineering . Acta Biomaterialia vol. 31 , 1 - 16 .
Sahu N, Baligar P, Midha S, Kundu B, Bhattacharjee M, Mukherjee S, Mukherjee S, Maushart F et al. ( 2015 ) . Nonmulberry Silk Fibroin Scaffold Shows Superior Osteoconductivity Than Mulberry Silk Fibroin in Calvarial Bone Regeneration . Advanced Healthcare Materials vol. 4 , ( 11 ) 1709 - 1721 .
Chameettachal S, Murab S, Vaid R, Midha S, Ghosh S ( 2015 ) . Effect of visco‐elastic silk–chitosan microcomposite scaffolds on matrix deposition and biomechanical functionality for cartilage tissue engineering . Journal of Tissue Engineering and Regenerative Medicine vol. 11 , ( 4 ) 1212 - 1229 .
Nara S, Chameettachal S, Midha S, Singh H, Tandon R, Mohanty S, Ghosh S ( 2015 ) . Strategies for faster detachment of corneal cell sheet using micropatterned thermoresponsive matrices . Journal of Materials Chemistry B vol. 3 , ( 20 ) 4155 - 4169 .
Midha S, Kim TB, van den Bergh W, Lee PD, Jones JR, Mitchell CA ( 2013 ) . Preconditioned 70S30C bioactive glass foams promote osteogenesis in vivo . Acta Biomaterialia vol. 9 , ( 11 ) 9169 - 9182 .
Midha S, van den Bergh W, Kim TB, Lee PD, Jones JR, Mitchell CA ( 2012 ) . Bioactive Glass Foam Scaffolds are Remodelled by Osteoclasts and Support the Formation of Mineralized Matrix and Vascular Networks In Vitro . Advanced Healthcare Materials vol. 2 , ( 3 ) 490 - 499 .
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