연구동향 분석

생체조직공학을 위한 2차원 물질 기반 복합나노섬유의 제조 및 특성평가 = Synthesis and Characterization of Two-dimensional Materials Incorporated Polymeric Composite Nanofibers for Biomedical Applications

아와시가네쉬 2020년

논문상세정보
인용/피인용
' 생체조직공학을 위한 2차원 물질 기반 복합나노섬유의 제조 및 특성평가 = Synthesis and Characterization of Two-dimensional Materials Incorporated Polymeric Composite Nanofibers for Biomedical Applications' 의 주제별 논문영향력
논문영향력 선정 방법
논문영향력 요약
주제
  • 2d materials
  • Polycaprolactone
  • Tissue engineering
  • Zein
  • composite nanofibers
  • electrospinning
동일주제 총논문수 논문피인용 총횟수 주제별 논문영향력의 평균
387 0

0.0%

' 생체조직공학을 위한 2차원 물질 기반 복합나노섬유의 제조 및 특성평가 = Synthesis and Characterization of Two-dimensional Materials Incorporated Polymeric Composite Nanofibers for Biomedical Applications' 의 참고문헌

  • characterization and biomedical application of two-nozzle electrospun polycaprolactone/zein-calcium lactate composite nonwoven mat
    60 ( [2016]
  • biocompatible and biodegradable high-performance graphitic carbon nitride ,
    563 ( [2020]
  • [8] O.V. Salata, Applications of nanoparticles in biology and medicine, Journal of Nanobiotechnology 2(1) (2004) 3.
  • [7] G.M. Whitesides, The 'right' size in nanobiotechnology, Nature Biotechnology 21(10) (2003) 1161-1165.
  • [77] R. Asmatulu, W.S. Khan, Chapter 7 - Electrospun nanofibers for filtration applications, in: R. Asmatulu, W.S. Khan (Eds.), Synthesis and Applications of Electrospun Nanofibers, Elsevier2019, pp. 135-152.
  • [54] M.V.e. al., Electrospinning and Drug Delivery, (10.5772/intechopen.86181) (2019).
    10.5772/intechopen.86181 [2019]
  • [47] A. Kakoria, S. Sinha-Ray, A Review on Biopolymer-Based Fibers via Electrospinning and Solution Blowing and Their Applications, Fibers 6(3) (2018) 45.
  • [42] I. Alghoraibi, Different methods for nanofibers design and fabrication, 2018.
  • [3] A. Hübler, O. Osuagwu, Digital Quantum Batteries: Energy and Information Storage in Nano Vacuum Tube Arrays, Complexity 15 (2010) 48-55.
  • [37] F. Poletto, R. Beck, S. Guterres, A. Pohlmann, Polymeric Nanocapsules:Concepts and Applications, 2011, pp. 49-68.
    pp . 49-68 . [2011]
  • [30] M. Moreno Raja, P.Q. Lim, Y.S. Wong, G.M. Xiong, Y. Zhang, S. Venkatraman, Y. Huang, Chapter 18 - Polymeric Nanomaterials: Methods of Preparation and Characterization, in: S.S. Mohapatra, S. Ranjan, N. Dasgupta, R.K. Mishra, S. Thomas (Eds.), Nanocarriers for Drug Delivery, Elsevier2019, pp. 557-653.
  • [2] R. Saini, S. Saini, S. Sharma, Nanotechnology: the future medicine, JCutan Aesthet Surg 3(1) (2010) 32-33.
    3 ( 1 ) ( [2010]
  • [23] K. Müller, E. Bugnicourt, M. Latorre, M. Jorda, Y. Echegoyen Sanz, J.M. Lagaron, O. Miesbauer, A. Bianchin, S. Hankin, U. Bölz, G. Pérez, M. Jesdinszki, M. Lindner, Z. Scheuerer, S. Castelló, M. Schmid, Review on the Processing and Properties of Polymer Nanocomposites and Nanocoatings and Their Applications in the Packaging, Automotive and Solar Energy Fields, Nanomaterials 7(4) (2017) 74.
  • [232] S. Lyu, D. Untereker, Degradability of polymers for implantable biomedical devices, Int J Mol Sci 10(9) (2009) 4033-4065.
  • [229] P. Piyasin, R. Yensano, S. Pinitsoontorn, Size-Controllable Melt-Electrospun Polycaprolactone (PCL) Fibers with a Sodium Chloride Additive, Polymers 11(11) (2019) 1768.
  • [223] F.J. O'Brien, Biomaterials & scaffolds for tissue engineering, Materials Today 14(3) (2011) 88-95.
  • [199] H. Fong, I. Chun, D.H. Reneker, Beaded nanofibers formed during electrospinning, Polymer 40(16) (1999) 4585-4592.
  • [195] M.K. Joshi, A.P. Tiwari, H.R. Pant, B.K. Shrestha, H.J. Kim, C.H. Park, C.S. Kim, In Situ Generation of Cellulose Nanocrystals in Polycaprolactone Nanofibers: Effects on Crystallinity, Mechanical Strength, Biocompatibility, and Biomimetic Mineralization, ACS Applied Materials & Interfaces 7(35) (2015) 19672-19683.
  • [193] G. Guan, S. Zhang, S. Liu, Y. Cai, M. Low, C.P. Teng, I.Y. Phang, Y. Cheng, K.L. Duei, B.M. Srinivasan, Y. Zheng, Y.-W. Zhang, M.-Y. Han, Protein Induces Layer-by-Layer Exfoliation of Transition Metal Dichalcogenides, Journal of the American Chemical Society 137(19) (2015) 6152-6155.
  • [162] A. Szuplewska, D. Kulpińska, A. Dybko, A.M. Jastrzębska, T. Wojciechowski, A. Rozmysłowska, M. Chudy, I. Grabowska-Jadach, W. Ziemkowska, Z. Brzózka, A. Olszyna, 2D Ti2C (MXene) as a novel highly efficient and selective agent for photothermal therapy, Materials Science and Engineering: C 98 (2019) 874-886.
  • [15] M. Grzelczak, J. Vermant, E.M. Furst, L.M. Liz-Marzán, Directed Self-Assembly of Nanoparticles, ACS Nano 4(7) (2010) 3591-3605.
  • [159] J.I. Paredes, S. Villar-Rodil, Biomolecule-assisted exfoliation and dispersion of graphene and other two-dimensional materials: a review of recent progress and applications, Nanoscale 8(34) (2016) 15389-15413.
  • [158] D. Nepal, K.E. Geckeler, Proteins and Carbon Nanotubes: Close Encounter in Water, Small 3(7) (2007) 1259-1265.
  • [155] J.N. Coleman, M. Lotya, A. O’Neill, S.D. Bergin, P.J. King, U. Khan, K. Young, A. Gaucher, S. De, R.J. Smith, I.V. Shvets, S.K. Arora, G. Stanton, H.-Y. Kim, K. Lee, G.T. Kim, G.S. Duesberg, T. Hallam, J.J. Boland, J.J. Wang, J.F. Donegan, J.C. Grunlan, G. Moriarty, A. Shmeliov, R.J. Nicholls, J.M. Perkins, E.M. Grieveson, K. Theuwissen, D.W. McComb, P.D. Nellist, V. Nicolosi, Two-Dimensional Nanosheets Produced by Liquid Exfoliation of Layered Materials, Science 331(6017) (2011) 568-571.
  • [138] C. DeArmitt, R. Rothon, Particulate Fillers, Selection, and Use in Polymer Composites, in: S. Palsule (Ed.), Encyclopedia of Polymers and Composites, Springer Berlin Heidelberg, Berlin, Heidelberg, 2014, pp. 1-19.
  • [131] A. Atiqah, M.N.M. Ansari, Chapter 6 - Nanostructure–Polymer Composites for Soft-Tissue Engineering, in: S.K. Swain, M. Jawaid (Eds.), Nanostructured Polymer Composites for Biomedical Applications, Elsevier2019, pp. 105-115.
  • [130] G.D. Mogoşanu, A.M. Grumezescu, Natural and synthetic polymers for wounds and burns dressing, International Journal of Pharmaceutics 463(2) (2014) 127-136.
  • [125] K. Bula, T. Jesionowski, A. Krysztafkiewicz, J. Janik, The effect of filler surface modification and processing conditions on distribution behaviour of silica nanofillers in polyesters, Colloid and Polymer Science 285(11) (2007) 1267-1273.
  • [123] Grafting of Gelatin on Electrospun Poly(caprolactone) Nanofibers to Improve Endothelial Cell Spreading and Proliferation and to Control Cell Orientation, Tissue Engineering 11(7-8) (2005) 1149-1158.
  • [10] H.Gleiter, NANOSTRUCTURED MATERIALS, Acta Metall Sin 33(2) (1997) 165-174.
    33 ( 2 ) ( [1997]
  • [103] A. Memic, T. Abudula, H.S. Mohammed, K. Joshi Navare, T. Colombani, S.A. Bencherif, Latest Progress in Electrospun Nanofibers for Wound Healing Applications, ACS Applied Bio Materials 2(3) (2019) 952-969.
  • ZnO nanoparticle-decorated two-dimensional titanium carbide with enhanced supercapacitive performance
    6 ( 92 ) ( [2016]
  • Z. Issaabadi , Chapter 1 An Introduction to Nanotechnology , in : M. Nasrollahzadeh , S.M . Sajadi , M. Sajjadi , Z. Issaabadi , M. Atarod ( Eds . )
    pp . 1-27 .
  • Wet-Chemical Synthesis and Consolidation of Stoichiometric Bismuth Telluride Nanoparticles for Improving the Thermoelectric Figure-of-Merit
    5 ( 14 ) ( [2013]
  • Wafer-Scale Fabrication of Nanopore Devices for Single-Molecule DNA Biosensing using MoS2 ,
  • Versatile Cutting Method for Producing Fluorescent Ultrasmall MXene Sheets
    11 ( 11 ) ( [2017]
  • Unraveling the mechanical strength of biomaterials used as a bone scaffold in oral and maxillofacial defects
    15 ( 2 ) [2018]
  • Ultrathin MXene-Micropattern-Based Field-Effect Transistor for Probing Neural Activity
    28 ( 17 ) ( [2016]
  • Ultralight MXene-based aerogels with high electromagnetic interference shielding performance ,
    7 ( 3 ) ( 2019 ) 474-478 .
  • Two-dimensional transition metal carbides and nitrides ( MXenes ) for biomedical applications
    47 ( 14 ) ( [2018]
  • Two-Dimensional Nanocrystals Produced by Exfoliation of Ti3AlC2 .
    23 ( 37 ) ( [2011]
  • Turn-on Persistent Luminescence Probe Based on Graphitic Carbon Nitride for Imaging Detection of Biothiols in Biological Fluids
    85 ( 24 ) ( [2013]
  • Tuning of reversible actuation via copolymerization of ROMP-based semicrystalline polymers
    156 [2018]
  • Towards understanding the salt-intercalation exfoliation of graphite into graphene
    7 ( 82 ) ( [2017]
  • Titanium carbide ( Ti3C2Tx ) MXene : A novel precursor to amphiphilic carbide-derived graphene quantum dots for fluorescent ink , light-emitting composite and bioimaging
    118 ( [2017]
  • Tissue engineering in the development of replacement technologies
    745 ( [2012]
  • Ti3C2 MXene quantum dots/TiO2 inverse opal heterojunction electrode platform for superior photoelectrochemical biosensing
    289 ( [2019]
  • Ti 3 C 2 MXene : a promising microwave absorbing material
    [2018]
  • The effect of filler surface modification and processing conditions on distribution behaviour of silica nanofillers in polyesters ,
    285 ( [2007]
  • The design of scaffolds for use in tissue engineering . Part I
    7 ( 6 ) ( [2001]
  • The Chemistry of Organic Nanomaterials
    44 ( 35 ) ( [2005]
  • Tetrahydro curcumin loaded PCL-PEG electrospun transdermal nanofiber patch : Preparation , characterization , and in vitro diffusion evaluations
    44 ( [2018]
  • Synthesis of polycaprolactone : a review
    38 ( 12 ) ( [2009]
  • Synthesis of nylon 6–clay hybrid by montmorillonite intercalated with ϵ-caprolactam ,
    31 ( 4 ) ( [1993]
  • Synthesis of continuous boron nitride nanofibers by solution coating electrospun template fibers
    20 ( 34 ) ( [2009]
  • Synthesis of MXene/DNA/Pd/Pt nanocomposite for sensitive detection of dopamine
    816 (189-194 [2018]
  • Synthesis and thermal stability of two-dimensional carbide MXene Ti3C2
    B 191 (33-40 . [2015]
  • Synthesis and characterization of gold/silica hybrid nanoparticles incorporated gelatin methacrylate conductive hydrogels for H9C2 cardiac cell compatibility study ,
    177 ( [2019]
  • Synthesis , characterizations , and biocompatibility evaluation of polycaprolactone–MXene electrospun fibers
    586 ( [2020]
  • Surfactant mediated liquid phase exfoliation of graphene
    2 ( 1 ) ( [2015]
  • Surface modification of polymer nanofibres by plasma treatment
    245 ( 1 ) ( [2005]
  • Surface modification and functionalization through the self-assembled monolayer and graft polymerization ,
    113 ( 1 ) ( [2005]
  • Surface modification and drug delivery applications of MoS2 nanosheets with polymers through the combination of mussel inspired chemistry and SET-LRP
    82 ( [2018]
  • Surface hydrolysis of fibrous poly ( ε-caprolactone ) scaffolds for enhanced osteoblast adhesion and proliferation ,
    15 ( 5 ) ( [2007]
  • Surface Modification of Polymeric Scaffolds for Tissue Engineering Applications ,
    4 ( 2 ) ( [2018]
  • Surface Modification of PLLA Nano-scaffolds with Laminin Multilayer by LbL Assembly for Enhancing Neurite Outgrowth ,
    13 ( 11 ) ( [2013]
  • Surface Energy Engineering for Tunable Wettability through Controlled Synthesis of MoS2
    14 ( 8 ) ( [2014]
  • Solvent Structuring and Its Effect on the Polymer Structure and Processability : TheCase of Water–Acetone Poly-ε-caprolactone Mixtures
    118 ( 46 ) ( [2014]
  • Solid-State Method Synthesis of SnO₂-Decorated g-C₃N₄ Nanocomposites with Enhanced Gas-Sensing Property to Ethanol ,
    10 ( 6 ) ( [2017]
  • Smart nanomaterials in pharmaceutical analysis
    13 ( 1 ) ( [2020]
  • Smart electrospun nanofibersContaining PCL/gelatin/graphene oxide for application in nerve tissue engineering
    C 103 ( [2019]
  • Scaffolds in tissue engineering bone andCartilage
    21 ( 24 ) ( [2000]
  • S.S. Rohiwal ,Chapter 2 Synthesis and Bioconjugation of Hybrid Nanostructures for Biomedical Applications , in : R. Ashok Bohara , N. Thorat ( Eds . ) , Hybrid Nanostructures forCancer Theranostics , Elsevier2019
    pp . 17-41 .
  • Review-Effect of Fillers on Mechanical Properties of Polymer MatrixComposites
    5 ( 10 , Part 3 ) ( [2018]
  • Review on Electrospun Nanofibers Scaffold and Biomedical Applications
    24 ( [2010]
  • Review ofChemical Vapor Deposition of Graphene and Related Applications
    46 ( 10 ) ( [2013]
  • Respirable nanocarriers as a promising strategy for antitubercular drug delivery
    187 ( [2014]
  • Recent advances in food-packing , pharmaceutical and biomedical applications of zein and zein-based materials
    15 ( 12 ) ( [2014]
  • Recent advances in electrospunCarbon nanofibers and their application in electrochemical energy storage
    76 ( [2016]
  • R. Ramaseshan , Electrospun nanofibers : solving global issues
    9 ( 3 ) ( [2006]
  • Preparation of ε-polylysine/chitosan nanofibers for food packaging against Salmonella onChicken , Food Packaging and Shelf Life
    17 ( [2018]
  • Preparation andCharacterization of ß-lactoglobulin/poly ( ethylene oxide ) magnetic nanofibers for biomedical applications
    [2019]
  • Preparation andCharacterization of aligned porous PCL/zein scaffolds as drug delivery systems via improved unidirectional freeze-drying method
    68 ( [2016]
  • Preparation and formation mechanism of ZnS semiconductor nanowires made by the electrochemical deposition method
    17 ( 2 ) ( [2005]
  • PolyvinylpyrrolidoneComposite nanofibers as efficient substrates for surface-assisted laser desorption/ionization mass spectrometry
    448 ( [2020]
  • Polypyrrole/Agarose-Based ElectronicallyConductive and Reversibly Restorable Hydrogel
    8 ( [2014]
  • Polymeric nanocapsules : An emerging drug delivery system
    9 ( [2018]
  • Polycaprolactone/carboxymethylChitosan nanofibrous scaffolds for bone tissue engineering application
    115 ( [2018]
  • Polycaprolactone scaffold modified with galactosylatedChitosan for hepatocyteCulture
    20 ( 3 ) ( [2012]
  • Plasma-treated electrospun nanofibers as a template for the electrostatic assembly of silver nanoparticles
    42 ( 13 ) ( [2018]
  • Plasma treatment of electrospun PCL random nanofiber meshes ( NFMs ) for biological property improvement
    101A ( 4 ) ( [2013]
  • PCL and PCL-Based Materials in Biomedical Applications
    29 ( [2017]
  • P. Kesharwani , Chapter 5 - Polymeric Micelles for Drug Targeting and DeliveryNanotechnology-Based Approaches for Targeting and Delivery of Drugs and Genes
    pp . 167-202
  • Optimum parameters for freeze-drying decellularized arterial scaffolds ,
    19 ( 12 ) ( [2013]
  • One-step Solution Processing of Ag , Au and Pd @ MXene Hybrids for SERS
    6 ( [2016]
  • O. Kamigaito , Nylon 6–Clay Hybrid
    171 ( [1989]
  • O. Cramariuc , Fiber diameter in electrospinning process
    71 ( 3 ) ( [2013]
  • Novel zein-based multilayer wound dressing membranes with controlled release of gentamicin
    107 [2018]
  • Novel bone scaffolds of electrospun polycaprolactone fibers filled with nanoparticles
    6 ( 2 ) ( [2006]
  • New forms of electrospun nanofiber materials for biomedical applications ,
    8 ( 17 ) ( [2020]
  • Nanotechnology : The “ Top-Down ” and
    [2012]
  • Nanostructured conductive polymers for advanced energy storage
    44 ( 19 ) ( [2015]
  • Nanoparticles meet electrospinning : recent advances and future prospects
    43 ( 13 ) ( [2014]
  • Nanomaterials in Tissue Engineering
    pp . 301-334
  • Nanofibrous Tubular Membrane for Blood Hemodialysis
    186 ( 2 ) ( [2018]
  • Nano Focus : MXenes poised to improve wearable artificial kidney options ,
    44 ( 1 ) ( [2019]
  • Multilayered Titanium Carbide MXene Film for Guided Bone Regeneration
    14 ( [2019]
  • MoS2 @ polydopamine-Ag nanosheets with enhanced antibacterial activity for effective treatment of Staphylococcus aureus biofilms and wound infection
    10 ( 35 ) ( [2018]
  • Metal oxides nanoparticles via sol–gel method : a review on synthesis , characterization and applications
    31 ( 5 ) ( [2020]
  • Metal Oxide Nanostructures in Food Applications : Quality Control and Packaging
    6 ( [2018]
  • Materials , and Mechanobiology of Biodegradable Scaffolds for Bone Tissue Engineering
    [2015]
  • Macrophage phenotype and remodeling outcomes in response to biologic scaffolds with and without a cellular component
    30 ( 8 ) ( [2009]
  • MXene Ti3C2Tx for phase change composite with superior photothermal storage capability ,
    7 ( 23 ) ( [2019]
  • MXene : a promising photocatalyst for water splitting ,
    4 ( 29 ) ( [2016]
  • M.S . Jhon , N.-E. Lee , Nanocomposite nanofibers of poly ( d , l-lactic-co-glycolic acid ) and graphene oxide nanosheets
    42 ( 12 ) ( [2011]
  • Langmuir films and uniform , large area , transparent coatings of chemically exfoliated MoS2 single layers
    5 ( 43 ) ( [2017]
  • Isolation of nanofibers from soybean source and their reinforcing capability on synthetic polymers ,
    67 ( 11 ) ( [2007]
  • Iron oxide-based superparamagnetic polymeric nanomaterials : Design , preparation , and biomedical application
    36 ( 1 ) ( [2011]
  • Investigating the properties of electrospun nanofibers made of hybride polymer containing anticoagulant drugs
    228 ( 2020 ) 115397 .
  • Interwoven Aligned Conductive Nanofiber Yarn/Hydrogel Composite Scaffolds for Engineered 3D Cardiac Anisotropy ,
    11 ( 6 ) ( [2017]
  • Injectable 2D MoS2 -Integrated Drug Delivering Implant for Highly Efficient NIR-Triggered Synergistic Tumor Hyperthermia
    27 ( 44 ) ( [2015]
  • In-vitro and in-vivo study of superabsorbent PVA/Starch/g-C3N4/Ag @ TiO2 NPs hydrogel membranes for wound dressing ,
    130 ( 2020 ) 109650 .
  • In-situ synthesis of AgNPs in the natural/synthetic hybrid nanofibrous scaffolds : Fabrication , characterization and antimicrobial activities
    65 ( [2017]
  • In vitro studies on cytotoxicity of delaminated Ti3C2 MXene ,
    339 ( [2017]
  • High visible light sensitive MoS2 ultrathin nanosheets for photoelectrochemical biosensing
    92 ( [2017]
  • Guidelines for Synthesis and Processing of Two-Dimensional Titanium Carbide ( Ti3C2T x MXene )
    29 ( 18 ) ( [2017]
  • Growth of spherical boron oxynitride nanoparticles with smooth and petalled surfaces during a chemical vapour deposition process
    18 ( 35 ) ( [2016]
  • Group IV Graphene- and Graphane-Like Nanosheets
    115 ( 27 ) ( [2011]
  • Graphitic carbon nitride polymers : promising catalysts or catalyst supports for heterogeneous oxidation and hydrogenation
    17 ( 2 ) ( [2015]
  • Graphene-based Polymer Nanocomposites
    52 ( 1 ) ( [2011]
  • Graphene oxide-enriched poly ( ε-caprolactone ) electrospun nanocomposite scaffold for bone tissue engineering applications
    32 ( 3 ) ( [2016]
  • Graphene : a versatile nanoplatform for biomedical applications
    4 ( 13 ) ( [2012]
  • Glowing Graphene Quantum Dots and Carbon Dots : Properties , Syntheses , and Biological Applications
    11 ( 14 ) ( [2015]
  • Functionalized MoS2-nanosheets for targeted drug delivery and chemo-photothermal therapy
    Biointerfaces 173 ( 2019 ) 101-108 .
  • Functional nanofibers for environmental applications
    18 ( 44 ) ( [2008]
  • Fibrous polymer nanomaterials for biomedical applications and their transport by fluids : an overview
    14 ( 42 ) ( [2018]
  • Facile synthesis of self-aligned gold nanoparticles by crack templated reduction lithography
    7 ( 22 ) ( [2017]
  • Facile synthesis of ZnO flowers modified graphene like MoS2 sheets for enhanced visible-light-driven photocatalytic activity and antibacterial properties
    682 ( [2016]
  • Facile preparation of sulfonic groups functionalized Mxenes for efficient removal of methylene blue
    45 ( 14 ) ( [2019]
  • Facile polyester surface functionalization via hydrolysis and cell-recognizing peptide attachment
    55 ( 11 ) ( [2006]
  • Facile Strategy on Hydrophilic Modification of Poly ( ε-caprolactone ) Scaffolds for Assisting Tissue-Engineered Meniscus Constructs In Vitro
    11 ( 2020 ) 471-471 .
  • Fabrication and photocatalytic activity enhanced mechanism of direct Z-scheme g-C3N4/Ag2WO4 photocatalyst .
    391 (175-183 [2017]
  • Fabrication and characterization of poly ( vinyl alcohol ) /chitosan blend nanofibers produced by electrospinning method
    67 ( 3 ) ( [2007]
  • Fabrication and characterization of PCL/zein/gum arabic electrospun nanocomposite scaffold for skin tissue engineering
    C 93 ( [2018]
  • FABRICATION OF ELECTROSPUN POLYACRYLONITRILE AND POLYURATHANE NANOFIBERS FOR SOUND ABSORPTION
    [2013]
  • Enhanced Photoresponsive Ultrathin Graphitic-Phase C3N4 Nanosheets for Bioimaging
    135 ( 1 ) ( [2013]
  • Enhanced Osteogenesis by Molybdenum Disulfide Nanosheet Reinforced Hydroxyapatite Nanocomposite Scaffolds ,
    5 ( 9 ) ( [2019]
  • Engineering hydrogels as extracellular matrix mimics
    5 ( 3 ) ( [2010]
  • Electrostatic self-assembly of polysaccharides into nanofibers
    182-188 [2017]
  • Electrospun-modified nanofibrous scaffolds for the mineralization of osteoblast cells
    85A ( 2 ) ( [2008]
  • Electrospun polylactic acid nanofiber membranes as substrates for biosensor assemblies
    279 ( 1 ) ( [2006]
  • Electrospun poly ( ɛ-caprolactone ) /gelatin nanofibrous scaffolds for nerve tissue engineering
    29 ( 34 ) ( [2008]
  • Electrospun nanofibrous membrane for electrodialysis
    1209 (012008 [2019]
  • Electrospun nanofiber reinforced composites : a review
    9 ( 20 ) ( [2018]
  • Electrospun nanofiber fabrication as synthetic extracellular matrix and its potential for vascular tissue engineering
    10 ( 7-8 ) ( [2004]
  • Electrospun nanofiber : Emerging reinforcing filler in polymer matrix composite materials
    75 ( [2017]
  • Electrospun conductive nanofibrous scaffolds for engineering cardiac tissue and 3D bioactuators ,
    59 ( [2017]
  • Electrospun chitosan-based nanofibers and their cellular compatibility
    26 ( 31 ) ( [2005]
  • Electrospun cellulose acetate butyrate/polyethylene glycol ( CAB/PEG ) composite nanofibers : A potential scaffold for tissue engineering
    Biointerfaces 188 ( [2020]
  • Electrospun Nanofibers for Air Filtration Applications ,
    75 ( [2014]
  • Electrospun MXene/carbon nanofibers as supercapacitor electrodes
    7 ( 1 ) 269-277 .
  • Electrospinning with partially carbonization in air : Highly porous carbon nanofibers optimized for high-performance flexible lithium-ion batteries
    13 ( [2015]
  • Electrospinning process and applications of electrospun fibers
    35 ( 2 ) ( [1995]
  • Electrospinning process : Versatile preparation method for biodegradable and natural polymers and biocomposite systems applied in tissue engineering and drug delivery
    296 ( [2014]
  • Electrospinning of food proteins and polysaccharides
    68 ( [2017]
  • Electrospinning of chitosan dissolved in concentrated acetic acid solution
    26 ( 27 ) ( [2005]
  • Electrospinning of Polymer Nanofibers : Effects on Oriented Morphology , Structures and Tensile Properties
    70 ( 5 ) ( [2010]
  • Electrospinning of Nanofibers for Tissue Engineering Applications
    495708 . [2013]
  • Electrospinning of Nanofibers : Reinventing the Wheel ?
    16 ( 14 ) ( [2004]
  • Electrospinning in water and in situ crosslinking of hyaluronic acid / cyclodextrin nanofibers : Towards wound dressing with controlled drug release
    207 ( [2019]
  • Electrospinning design of functional nanostructures for biosensor applications
    5 ( 9 ) ( [2017]
  • Electrospinning and electrospraying techniques : Potential food based applications
    38 [2014]
  • Electrospinning and Electrospun Nanofibers : Methods , Materials , and Applications
    119 ( 8 ) ( [2019]
  • Electrospinning Directly Synthesized Porous TiO2 Nanofibers Modified by Graphitic Carbon Nitride Sheets for Enhanced Photocatalytic Degradation Activity under Solar Light Irradiation ,
    32 ( 24 ) ( [2016]
  • Electrodeposition of Ca–P coatings on biodegradable Mg alloy : In vitro biomineralization behavior
    6 ( 5 ) ( [2010]
  • Efficient Antibacterial Membrane based on Two-Dimensional Ti C T ( x ) ( MXene ) Nanosheets
    7 ( 1 ) ( [2017]
  • Efficient Antibacterial Membrane based on Two-Dimensional Ti ( 3 ) C ( 2 ) T ( x ) ( MXene ) Nanosheets
    7 ( 1 ) ( [2017]
  • Effects of GO and rGO incorporated nanofibrous scaffolds on the proliferation of Schwann cells
    5 ( 2 ) ( [2019]
  • Effect of the nano/microscale structure of biomaterial scaffolds on bone regeneration
    12 ( 1 ) ( [2020]
  • Effect of porosity and surface hydrophilicity on migration of epithelial tissue over synthetic polymer
    50 ( 4 ) ( [2000]
  • Drug Delivery Applications of Core-Sheath Nanofibers Prepared by Coaxial Electrospinning : A Review
    11 ( 7 ) ( [2019]
  • Disintegration of water drops in an electric field
    280 ( 1382 [1964]
  • Development of polyamide-6,6/chitosan electrospun hybrid nanofibrous scaffolds for tissue engineering application
    148 ( [2016]
  • Designing electrospun nanofiber mats to promote wound healing–a review .
    1 ( 36 ) ( [2013]
  • Defective Black TiO2 Synthesized via Anodization for Visible-Light Photocatalysis ,
    6 ( 3 ) ( [2014]
  • Current Concepts in Scaffolding for Bone Tissue Engineering
    6 ( 2 ) ( [2018]
  • Crystallization of poly ( ε-caprolactone ) in its immiscible blend with polylactide : insight into the role of annealing histories
    6 ( 44 ) ( [2016]
  • Core-Sheath Nanofibers as Drug Delivery System for Thermoresponsive Controlled Release
    106 ( 5 ) ( [2017]
  • Construction and functional assessment of zein thin film incorporating spindle-like ZnO crystals
    7 ( [2017]
  • Conductive nanofibrous composite scaffolds based on in-situ formed polyaniline nanoparticle and polylactide for bone regeneration
    514 ( [2018]
  • Composite Materials for Biomedical Applications : A Review
    JABB 1 ( [2003]
  • Comparison of random and aligned PCL nanofibrous electrospun scaffolds on cardiomyocyte differentiation of human adipose-derived stem cells
    17 ( 11 ) ( [2014]
  • Chpater 7 - Polymer Nanoparticles , in : A. Villaverde ( Ed . ) , Progress in Molecular Biology and Translational Science
    pp . 299-323 .
  • Chitosan based nanofibers in bone tissue engineering
    104 ( [2017]
  • Chemo-Rheological Behavior of Aqueous Titanium Carbide Suspension and Evaluation of the Gelcasted Green Body Properties
    20 ( [2017]
  • Characterization of protein adsorption on stretched polyurethane nanofibers prepared by electrospinning
    7 ( [2017]
  • Characterization of gelatin/zein nanofibers by hybrid electrospinning
    75 ( [2018]
  • Characterization , drug loading and antibacterial activity of nanohydroxyapatite/polycaprolactone ( nHA/PCL ) electrospun membrane
    7 ( 4 ) ( [2017]
  • Chapter 3 - Electrospun nanofibers for biomedical applications , in : R. Shegokar ( Ed . ) , Delivery of Drugs , Elsevier2020
    pp . 53-74 .
  • Chapter 11 - Electrospinning of collagen nanofiber scaffolds for tissue repair and regeneration , in : D. Ficai , A.M. Grumezescu ( Eds . ) , Nanostructures for Novel Therapy
    pp . 281-311 .
  • Chapter 1 - Introduction to Nanomaterials : Basic Properties , Synthesis , and Characterization
    pp . 1-19
  • Catalytic activity of trypsin entrapped in electrospun poly ( ϵ-caprolactone ) nanofibers
    08월 18일 [2015]
  • Carbon-based two-dimensional layered materials for photocatalytic CO2 reduction to solar fuels
    3 ( [2016]
  • Carbon nanotube-polymer interactions in nanocomposites : A review
    72 ( [2011]
  • CHAPTER 10 Zein : Structure , Production , Film Properties and Applications
    pp . 204-218
  • Bottom-up preparation techniques for nanocrystals of lipophilic drugs
    28 ( 5 ) ( [2011]
  • Bottom-Up and Top-Down Approaches to the Synthesis of Monodispersed Spherical Colloids of Low Melting -Point Metals
    4 ( 10 ) ( [2004]
  • Bone tissue engineering : a review in bone biomimetics and drug delivery strategies
    25 ( 6 ) ( [2009]
  • Biomimetic nanofibrous scaffolds for bone tissue engineering
    32 ( 36 ) ( [2011]
  • Biomimetic materials for tissue engineering
    60 ( 2 ) ( [2008]
  • Biomimetic conducting polymer-based tissue scaffolds
    24 ( [2013]
  • Biomaterials for bone tissue engineering scaffolds : a review
    9 ( 45 ) ( [2019]
  • Bioinspired structural materials
    14 ( 1 ) ( [2015]
  • Biodegradable polymer scaffolds for tissue engineering , Bio/technology
    12 ( 7 ) ( 1994 ) 689-93 .
  • Atomic layer deposition for nanomaterial synthesis and functionalization in energy technology
    4 ( 2 ) ( [2017]
  • Applications of Polymers in the Biomedical Field
    Biosciences ( CTBEB ) 4 [2017]
  • An investigation into the factors governing the oxidation of two-dimensional Ti3C2 MXene
    11 ( 17 ) ( [2019]
  • Advancements in Electrospinning of Polymeric Nanofibrous Scaffolds for Tissue Engineering
    20 ( 4 ) ( [2013]
  • Accelerated Bone Regeneration by Two-Photon Photoactivated Carbon Nitride Nanosheets ,
    11 ( 1 ) ( [2017]
  • A review of key challenges of electrospun scaffolds for tissue-engineering applications ,
    10 ( 9 ) ( 2016 ) 715-738 .
  • A review of fibrin and fibrin composites for bone tissue engineering
    12 ( [2017]
  • A Summary of Electrospun Nanofibers as Drug Delivery System : Drugs Loaded and Biopolymers Used as Matrices ,
    15 ( 10 ) ( [2018]
  • 92 ] R. Das , Chapter 12 - Application of nanobioceramics in bone tissue engineering , in : A.M. Grumezescu ( Ed . ) , Nanobiomaterials in Hard Tissue Engineering
    pp . 353-379
  • 5.4 - Fibrous Materials , in : M. Ebara ( Ed . )
    pp . 267-278 .
  • 3D biodegradable scaffolds of polycaprolactone with silicate-containing hydroxyapatite microparticles for bone tissue engineering : High-resolution tomography and in vitro study
    8 ( [2018]
  • 2D titanium carbide ( MXene ) for wireless communication
    4 ( 9 ) ( [2018]
  • 2D metal carbides and nitrides ( MXenes ) for energy storage
    2 ( [2017]
  • 2D materials for next generation healthcare applications
    551 ( 1 ) ( [2018]
  • 2D Ultrathin MXene-Based Drug-Delivery Nanoplatform for Synergistic Photothermal Ablation and Chemotherapy of Cancer
    7 ( 9 ) ( [2018]
  • 2 - Synthesis of polymeric nanomaterials for biomedical applications , in : A.K . Gaharwar , S. Sant , M.J. Hancock , S.A. Hacking ( Eds . ) , Nanomaterials in Tissue Engineering
    pp . 27-63
  • , S. Danti ,Ciprofloxacin-loaded polymeric nanoparticles incorporated electrospun fibers for drug delivery
    Delivery and Translational Research 10 ( 3 ) (
  • , R.A. Surmenev , 3D biodegradable scaffolds of polycaprolactone with silicate-containing hydroxyapatite microparticles for bone tissue engineering : high-resolution tomography
    study , Scientific Reports 8 ( 1 ) (