Page 86 - IJB-8-2
P. 86

CNT/PCL Nanocomposite for Tissue Engineering
           6.   Yu  MF,  Lourie  O,  Dyer  MJ, et  al.,  2000,  Strength  and   of  Multi-Walled  Carbon  Nanotubes  Into  Electrospun  PCL/
               Breaking  Mechanism  of Multiwalled  Carbon  Nanotubes   Gelatin  Scaffold: The  Influence  on  the  Physical,  Chemical
               Under Tensile Load. Science, 287:637–40.            and  Thermal  Properties  and  Cell  Response  for  Tissue
               https://doi.org/10.1126/science.287.5453.637        Engineering. Mater Technol, 35:39–49.
           7.   Szymański T, Mieloch AA, Richter M, et al., 2020, Utilization      https://doi.org/10.1080/10667857.2019.1651539
               of Carbon Nanotubes in Manufacturing of 3D Cartilage and   18.  Wu  T,  Chen  X,  Sha  J,  et  al.,  2019,  Fabrication  of  Shish-
               Bone Scaffolds. Materials (Basel), 13:4039.         Kebab-Structured  Carbon Nanotube/Poly(Ε-Caprolactone)
           8.   Patel  DK,  Dutta  SD,  Ganguly  K,  et al.,  2021,  Enhanced   Composite  Nanofibers  for  Potential  Tissue  Engineering
               Osteogenic  Potential  of  Unzipped  Carbon  Nanotubes  for   Applications. Rare Met, 38:64–72.
               Tissue Engineering. J Biomed Mater Res A, 109:1869–80.     https://doi.org/10.1007/s12598-017-0965-y
               https://doi.org/10.1002/jbm.a.37179             19.  Zou Y, Zhang C, Wang P, et al., 2020, Electrospun Chitosan/
           9.   Edwards SL, Werkmeister JA, Ramshaw JA, 2009, Carbon   Polycaprolactone Nanofibers Containing Chlorogenic Acid-
               Nanotubes in Scaffolds for Tissue Engineering. Expert Rev   Loaded  Halloysite  Nanotube  for  Active  Food  Packaging.
               Med. Dev, 6:499–505.                                Carbohydr Polym, 247:116711.
           10.  Haniu H, Saito N, Matsuda Y, et al., 2012, Basic Potential      https://doi.org/10.1016/j.carbpol.2020.116711
               of  Carbon  Nanotubes  in  Tissue  Engineering  Applications.   20.  Yu W, Liu C, Fan S, 2021, Advances of CNT-Based Systems
               J Nanomater, 2012:343747.                           in Thermal Management. Nano Res, 14:2471–90.
           11.  Soni SK, Thomas B, Kar VR, 2020, A Comprehensive Review   21.  Konstantopoulos G, Maroulas P, Dragatogiannis DA, et al.,
               on  CNTs  and  CNT-Reinforced  Composites:  Syntheses,   2021, The Effect of Interfacial Resistance and Crystallinity
               Characteristics  and  Applications.  Mater Today Commun,   on Heat Transfer Mechanism in Carbon Nanotube Reinforced
               25:101546.                                          Polyethylene. Mater Des, 199:109420.
           12.  Stocco  TD,  Antonioli  E,  Romagnolli  ML,  et al.,  2020,      https://doi.org/10.1016/J.MATDES.2020.109420
               Aligned Biomimetic Scaffolds Based on Carbon Nanotubes-  22.  Avramenko TG, Khutoryanskaya NV, Naumenko SM, et al.,
               Reinforced Polymeric Nanofibers for Knee Meniscus Tissue   2019, Effect of Carbon Nanofillers on Processes of Structural
               Eng Mater Lett, 264:127351.                         Relaxation in the Polymer Matrixes. In: Proceedings of the
               https://doi.org/10.1016/j.matlet.2020.127351        Springer Proceedings in Physics. Vol. 221. Cham: Springer,
           13.  Lebedev SM, 2020, PCL-CNT Nanocomposites Prepared by   p293–305.
               Melt Compounding and Evaluation of Their Basic Properties.   23.  Carreau  PJ,  1972,  Rheological  Equations  from  Molecular
               Polym Compos, 41:1830–40.                           Network Theories. Trans Soc Rheol, 16:99–127.
               https://doi.org/10.1002/pc.25501                    https://doi.org/10.1122/1.549276
           14.  Abdal-Hay A, Taha M, Mousa HM, et al., 2019, Engineering   24.  Yasuda  K,  1979,  Investigation  of  the  Analogies  between
               of Electrically-Conductive  Poly(Ε-Caprolactone)/Multi-  Viscometric and Linear Viscoelastic Properties of Polystyrene
               Walled Carbon Nanotubes Composite Nanofibers for Tissue   Fluids, Massachusetts Institute of Technology.
               Engineering Applications. Ceram Int, 45:15736–40.  25.  Pitt CG, Chasalow FI, Hibionada YM, et al., 1981, Aliphatic
               https://doi.org/10.1016/j.ceramint.2019.04.206      Polyesters.  I.  The  Degradation  of  Poly(ϵ‐Caprolactone)  In
           15.  Zadehnajar P, Akbari B, Karbasi S, et al., 2019, Preparation   Vivo. J Appl Polym Sci, 26:3779–87.
               and Characterization of Poly  ε-Caprolactone-Gelatin/     https://doi.org/10.1002/app.1981.070261124
               Multi-Walled  Carbon  Nanotubes  Electrospun  Scaffolds  for   26.  Chen J, Liu B, Gao X, et al., 2018, A Review of the Interfacial
               Cartilage Tissue Engineering Applications. Int J Polym Mater   Characteristics  of Polymer  Nanocomposites  Containing
               Polym Biomater, 69:326–37.                          Carbon Nanotubes. RSC Adv, 8:28048–85.
               https://doi.org/10.1080/00914037.2018.1563088   27.  Evans W, Prasher R, Fish J, et al., 2008, Effect of Aggregation
           16.  Jahanmard  F,  Eslaminejad  MB,  Amani-Tehran  M, et  al.,   and Interfacial Thermal Resistance on Thermal Conductivity
               2020,  Incorporation  of  F-MWCNTs  into  Electrospun   of  Nanocomposites  and  Colloidal  Nanofluids.  Int J Heat
               Nanofibers  Regulates  Osteogenesis  Through  Stiffness  and   Mass Transf, 51:1431–8.
               Nanotopography. Mater Sci Eng C, 106:110163.        https://doi.org/10.1016/j.ijheatmasstransfer.2007.10.017
               https://doi.org/10.1016/j.msec.2019.110163      28.  Klonos  PA,  Peoglos  V,  Bikiaris  DN,  et  al.,  2020,
           17.  Zadehnajar P, Karbasi S, Akbari B, et al., 2020, Incorporation   Rigid  Amorphous  Fraction  and  Thermal  Diffusivity  in

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