Electrospinning of nano/micro scale poly (L-lactic acid) aligned fibers and their potential in neural tissue engineering F Yang, R Murugan, S Wang, S Ramakrishna Biomaterials 26 (15), 2603-2610, 2005 | 2302 | 2005 |
A review on nanomaterials for environmental remediation MM Khin, AS Nair, VJ Babu, R Murugan, S Ramakrishna Energy & Environmental Science 5 (8), 8075-8109, 2012 | 1472 | 2012 |
Development of nanocomposites for bone grafting R Murugan, S Ramakrishna Composites Science and technology 65 (15-16), 2385-2406, 2005 | 980 | 2005 |
Fabrication of nano-structured porous PLLA scaffold intended for nerve tissue engineering F Yang, R Murugan, S Ramakrishna, X Wang, YX Ma, S Wang Biomaterials 25 (10), 1891-1900, 2004 | 773 | 2004 |
Design strategies of tissue engineering scaffolds with controlled fiber orientation R Murugan, S Ramakrishna Tissue engineering 13 (8), 1845-1866, 2007 | 571 | 2007 |
Bioresorbable composite bone paste using polysaccharide based nano hydroxyapatite R Murugan, S Ramakrishna Biomaterials 25 (17), 3829-3835, 2004 | 549 | 2004 |
Nano-featured scaffolds for tissue engineering: a review of spinning methodologies R Murugan, S Ramakrishna Tissue engineering 12 (3), 435-447, 2006 | 503 | 2006 |
Nanobiomaterial applications in orthopedics EM Christenson, KS Anseth, JJJP van den Beucken, CK Chan, B Ercan, ... Journal of orthopaedic research 25 (1), 11-22, 2006 | 476 | 2006 |
Gradient biomaterials for soft-to-hard interface tissue engineering A Seidi, M Ramalingam, I Elloumi-Hannachi, S Ostrovidov, ... Acta biomaterialia 7 (4), 1441-1451, 2011 | 445 | 2011 |
Reactions in high-temperature aqueous media AR Katritzky, DA Nichols, M Siskin, R Murugan, M Balasubramanian Chemical reviews 101 (4), 837-892, 2001 | 309 | 2001 |
Engineered contractile skeletal muscle tissue on a microgrooved methacrylated gelatin substrate V Hosseini, S Ahadian, S Ostrovidov, G Camci-Unal, S Chen, H Kaji, ... Tissue Engineering Part A 18 (23-24), 2453-2465, 2012 | 283 | 2012 |
Skeletal muscle tissue engineering: methods to form skeletal myotubes and their applications S Ostrovidov, V Hosseini, S Ahadian, T Fujie, SP Parthiban, ... Tissue Engineering Part B: Reviews 20 (5), 403-436, 2014 | 278 | 2014 |
Dielectrophoretically aligned carbon nanotubes to control electrical and mechanical properties of hydrogels to fabricate contractile muscle myofibers J Ramón‐Azcón, S Ahadian, M Estili, X Liang, S Ostrovidov, H Kaji, ... Advanced materials 25 (29), 4028-4034, 2013 | 269 | 2013 |
Cartilage-like tissue engineering using silk scaffolds and mesenchymal stem cells S Hofmann, S Knecht, R Langer, DL Kaplan, G Vunjak-Novakovic, ... Tissue engineering 12 (10), 2729-2738, 2006 | 250 | 2006 |
Development of decellularized scaffolds for stem cell‐driven tissue engineering MR Deepti Rana, Hala Zreiqat, Nadia Benkirane‐Jessel, Seeram Ramakrishna Journal of tissue engineering and regenerative medicine 11 (4), 942–965, 2017 | 249 | 2017 |
Hybrid hydrogels containing vertically aligned carbon nanotubes with anisotropic electrical conductivity for muscle myofiber fabrication S Ahadian, J Ramón-Azcón, M Estili, X Liang, S Ostrovidov, H Shiku, ... Scientific reports 4 (1), 4271, 2014 | 244 | 2014 |
Nanoporous hydroxy-carbonate apatite scaffold made of natural bone R Murugan, S Ramakrishna, KP Rao Materials Letters 60 (23), 2844-2847, 2006 | 189 | 2006 |
Aqueous mediated synthesis of bioresorbable nanocrystalline hydroxyapatite R Murugan, S Ramakrishna Journal of crystal growth 274 (1), 209-213, 2005 | 169 | 2005 |
Production of ultra-fine bioresorbable carbonated hydroxyapatite R Murugan, S Ramakrishna Acta Biomaterialia 2 (2), 201-206, 2006 | 166 | 2006 |
Processing nanoengineered scaffolds through electrospinning and mineralization suitable for biomimetic bone tissue engineering. S Liao, R Murugan, CK Chan, S Ramakrishna Journal of the mechanical behavior of biomedical materials 1 (3), 252, 2008 | 158 | 2008 |