Semiconducting silicon nanowires for biomedical applications

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Bibliographic Details
Other Authors: Coffer, Jeffery, (Editor)
Format: eBook
Language: English
Published: Duxford, United Kingdom : Woodhead Publishing, [2022]
Edition: Second edition.
Series: Woodhead Publishing series in biomaterials.
Subjects:
ISBN: 9780323851312
0323851312
9780128213513
0128213515
Physical Description: 1 online resource (1 volume) : illustrations (black and white, and color)

Cover

Table of contents

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001 kn-on1269212387
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040 |a OPELS  |b eng  |e rda  |e pn  |c OPELS  |d OCLCO  |d OCLCF  |d YDX  |d YDXIT  |d OCLCO  |d OCLCQ  |d SFB  |d K6U  |d OCLCQ  |d OCLCO  |d OCLCL 
020 |a 9780323851312  |q (electronic book) 
020 |a 0323851312  |q (electronic book) 
020 |z 9780128213513 
020 |z 0128213515 
035 |a (OCoLC)1269212387  |z (OCoLC)1268325420  |z (OCoLC)1287276663  |z (OCoLC)1287869709 
245 0 0 |a Semiconducting silicon nanowires for biomedical applications /  |c edited by Jeffery L. Coffer. 
250 |a Second edition. 
264 1 |a Duxford, United Kingdom :  |b Woodhead Publishing,  |c [2022] 
300 |a 1 online resource (1 volume) :  |b illustrations (black and white, and color) 
336 |a text  |b txt  |2 rdacontent 
337 |a computer  |b c  |2 rdamedia 
338 |a online resource  |b cr  |2 rdacarrier 
490 1 |a Woodhead Publishing series in biomaterials 
500 |a Previous edition: 2014. 
500 |a Includes index. 
504 |a Includes bibliographical references and index. 
505 0 |a Front cover -- Half title -- Full title -- Copyright -- Contents -- Contributors -- About the Editor -- Foreword -- Chapter One -- An overview of semiconducting silicon nanowires for biomedical applications -- 1.1 I ntroduction -- 1.2 Historical origins -- 1.3 The structure of this book -- 1.4 Final comments -- References -- Chapter Two -- Growth and characterization of silicon nanowires for biomedical applications -- 2.1 Introduction -- 2.2 Synthesis methods -- 2.2.1 Chemical etching of silicon wafers -- 2.2.2 Chemical vapor deposition for silicon nanowire growth -- 2.2.2.1 Growth of intrinsic (undoped) silicon nanowires -- 2.2.2.2 Growth of p-type or n-type silicon nanowires -- 2.2.2.3 Growth of millimeter-long silicon nanowires -- 2.2.2.4 Growth of axial silicon nanowire heterostructures -- 2.2.2.5 Growth of radial Si NW heterostructures -- 2.2.2.6 Growth of kinked or zigzag Si NWs -- 2.2.2.7 Growth of branched silicon nanowires -- 2.2.3 Solution-liquid-solid growth of silicon nanowires -- 2.3 Characterization methods -- 2.3.1 Electron microscopy techniques -- 2.3.2 Raman spectroscopy -- 2.3.3 Electrical transport measurement -- 2.4 Example: Synthesis of semiconductor Si NWs by the CVD method -- 2.5 Conclusion -- Future trends -- References -- Chapter Three -- Surface modification of silicon nanowires for biosensing -- 3 .1 Introduction -- 3 .2 Fabrication of silicon nanowires -- 3 .3 Chemical activation/passivation of silicon nanowires -- 3.3.1 Modification of native oxide SiO x /SiNWs -- 3.3.2 Modification of hydrogen-terminated silicon nanowires -- 3 .4 Modification of native oxide layer -- 3.4.1 Silanization reaction -- 3.4.1.1 Control of wetting properties by introduction of alkyl or ­perfluoroalkyl chains on silicon nanowires -- 3.4.1.2 Amine-terminated silicon nanowires ( Fig. 3.2 ). 
505 8 |a 3.4.1.3 Thiol-terminated silicon nanowires ( Figs. 3.2 -- 3.3 ) -- 3.4.1.4 Epoxy-terminated silicon nanowires -- 3.4.1.5 Aldehyde-terminated silicon nanowires -- 3.4.1.6 Vinyl-terminated silicon nanowires -- 3.4.1.7 Modification with carboxylic acid/organosilane reagents -- 3.4.2 Post-functionalization -- 3.4.3 Heterobifunctional cross-linkers -- 3.4.4 Reaction with organophosphates ( Figs. 3.2 -- 3.7 ) -- 3. 5 Modification of hydrogen-terminated silicon nanowires -- 3.5.1 Hydrosilylation reaction -- 3.5.2 Deprotection -- 3.5.3 Post-modification/cross-linking -- 3.5.4 Halogenation/alkylation followed by Grignard reaction -- 3.5.5 Electrografting on hydrogen-terminated silicon nanowires -- 3.5.6 Arylation via aryldiazonium salt -- 3 .6 Site-specific immobilization strategy of biomolecules on silicon nanowires -- 3.6.1 Native chemical ligation -- 3.6.2 "Click" chemistry -- 3 .7 Control of non-specific interactions -- 3. 8 Photochemistry -- 3 .9 Inorganic functionalization -- 3 .10 Conclusion -- References -- Chapter Four -- Biocompatibility of semiconducting silicon nanowires -- 4 .1 Introduction -- 4 .2 In vitro biocompatibility of silicon nanowires -- 4.2.1 Cytotoxicity -- 4.2.2 Osseointegration -- 4.2.3 Hemocompatibility -- 4. 3 In vivo biocompatibility of silicon nanowires -- 4. 4 Methodology issues -- 4.4.1 Improper material characterization -- 4.4.2 Modus operandi issues -- 4. 5 Future trends -- 4.5.1 Lack of data about the biocorona -- 4.5.2 Genotoxicity profiling -- 4.5.3 Potential production of reactive oxygen species -- 4. 6 Conclusion -- References -- Chapter Five -- Functional silicon nanowires for cellular binding and internalization -- 5. 1 Developing a nano biomodel system for rational design in nanomedicine. 
505 8 |a 5 .2 Non-linear optical characterization and surface functionalization of silicon nanowires -- 5.2.1 Nonilinear optical imaging of silicon nanowires -- 5.2.2 Functionalization of silicon nanowires -- 5 .3 Applications: In vivo imaging and in vitro cellular interaction of functional Si NWs -- 5.3.1 Intravital imaging of silicon nanowires circulating in blood vessels -- 5.3.2 In vitro cellular response to silicon nanowires -- 5 .4 Understanding internalization pathways for silicon nanowires -- 5 .5 Conclusions and future trends -- References -- Chapter Six -- Functional semiconducting silicon nanowires and their composites as tissue scaffolds -- 6.1 Introduction -- 6.2 NW surface etching processes to induce biomineralization -- 6.3 NW surface functionalization strategies to induce biomineralization -- 6.3.1 Electrochemically assisted surface functionalization -- 6.3.2 Covalent surface functionalization of Si NWs for osteocompatibility -- 6.4 Construction of Si NW -- polymer scaffolds: mimicking trabecular bone -- 6.4.1 Si NW transfer onto highly porous polymer surfaces -- 6.4.2 Uniform NW transfer onto porous polymer surfaces with horizontally-oriented NWs -- 6.4.3 Vertical Si NW arrays on patterned polymer substrates -- 6.5 The role of Si NW orientation on cellular attachment, proliferation, and differentiation in the nanocomposite -- 6.5.1 Cell attachment assays with MSCs -- 6.6 Viability assays of MSCs on Si NW/PCL composites -- 6.7 Differentiation of MSC on Si NW/PCL composites -- 6.8 Recent advances in neural-based tissue engineering -- 6.9 Conclusions and prospects for the future -- Acknowledgement -- References -- Chapter Seven -- Mediated differentiation of stem cells by engineered silicon nanowires -- 7.1 Introduction -- 7.2 Methods for silicon nanowire fabrication/ in vitro experiments. 
505 8 |a 7.2.1 Electroless metal deposition method -- 7.2.2 Biological cell culture process -- 7.2.2.1 Isolation of human bone marrow-derived mesenchymal stem cells -- 7.2.2.2 Cellular viability -- 7.2.2.3 Gene expression and immunofluorescence staining -- 7.2.2.4 Cell fixation process -- 7.2.3 Material characterization -- 7.3 Regulated differentiation for human mesenchymal stem cells -- 7.4 Silicon nanowires fabricated by an electroless metal deposition method and their controllable spring constants -- 7.5 M ediated differentiation of stem cells by engineered silicon nanowires -- 7.6 C onclusions and future trends -- Acknowledgements -- References -- Chapter Eight -- Nanoneedle devices for biomedicine -- 8.1 Introduction -- 8.2 Drug delivery -- 8.2.1 NN-mediated delivery strategies -- 8.3 NN interface with cell membrane -- 8.4 Bioelectronics -- 8.5 Sensing, spectroscopy, and trapping -- 8.6 Conclusion -- References -- Chapter Nine -- Therapeutic platforms based on silicon nanotubes -- 9.1 Introduction -- 9.2 Computational studies of single-walled silicon nanotubes -- 9.3 Fabrication and characterization of silicon nanotubes -- 9.4 Chemical modification strategies of Si NT surfaces with implications in therapeutics -- 9.5 Biodegradation properties of silicon nanotubes -- 9.6 Biocompatibility of silicon nanotubes -- 9.7 Nanotube interior filling with superparamagnetic nanoparticles for potential magnetic field-assisted drug delivery -- 9.8 Formation of a nanohybrid composed of Si NTs and metal nanoparticles with relevant anticancer properties -- 9.9 Conclusions -- Acknowledgement -- References -- Chapter Ten -- Cellular nanotechnologies: Orchestrating cellular processes by engineering silicon nanowires architectures -- 10.1 Introduction -- 10.2 Engineering of tunable vertically aligned nanostructure arrays. 
505 8 |a 10.3 Surface functionalization of Si NW arrays for intracellular delivery applications -- 10.4 The influence of Si NW array geometries on fundamental cell behavior -- 10.5 Vertically aligned nanostructure mediated intracellular signaling -- 10.5.1 Plasma membrane curvature-mediated intracellular signaling -- 10.5.2 Nuclear membrane curvature-mediated intracellular signaling -- 10.5.3 The effect of nanostructure on Rho-family GTPase signaling -- 10.5.4 The effect of nanostructure tip diameter on gene expression -- 10.6 Vertically aligned nanostructure mediated intracellular delivery -- 10.6.1 Silicon nanowire-mediated intracellular delivery in vitro -- 10.6.2 Silicon nanowire-mediated intracellular delivery in vivo -- 10.6.3 Underlying mechanism of vertically aligned nanostructure mediated intracellular delivery -- 10.7 Vertically aligned nanostructure mediated electroporation -- 10.7.1 Intracellular delivery -- 10.7.2 Intracellular recording -- 10.8 Conclusion -- References -- Chapter Eleven -- Nanowire array fabrication for high throughput screening in the biosciences -- 11.1 In troduction -- 11.2 Fa brication methods -- 11.2.1 Fabrication of silicon nanowire field-effect transistors for HTS in biosciences -- 11.2.2 Fabrication of silicon nanowire field effect transistors via "top-down" methods -- 11.2.2.1 Fabrication of silicon nanowire field effect transistors via "bottom-up" methods -- 11.2.2.2 Fabrication of Si NW FET arrays via superlattice nanowire pattern transfer "SNAP" method -- 11.2.3 Surface modification of Si NW FETs for HTS in the biosciences -- 11.2.4 Integration of Si NW FETs with microfluidic devices for HTS in real time measurements -- 11.3 Examples/applications -- 11.3.1 DNA hybridization -- 11.3.2 Detection of multiple viruses and small molecules-proteins interactions. 
506 |a Plný text je dostupný pouze z IP adres počítačů Univerzity Tomáše Bati ve Zlíně nebo vzdáleným přístupem pro zaměstnance a studenty 
590 |a Knovel  |b Knovel (All titles) 
650 0 |a Biomedical materials. 
650 0 |a Nanosilicon. 
650 0 |a Nanowires. 
655 7 |a elektronické knihy  |7 fd186907  |2 czenas 
655 9 |a electronic books  |2 eczenas 
700 1 |a Coffer, Jeffery,  |e editor. 
776 0 8 |i Print version:  |t Semiconducting silicon nanowires for biomedical applications.  |b Second edition.  |d Oxford : Woodhead Publishing, 2021  |z 9780128213513  |w (OCoLC)1263797212 
830 0 |a Woodhead Publishing series in biomaterials. 
856 4 0 |u https://proxy.k.utb.cz/login?url=https://app.knovel.com/hotlink/toc/id:kpSSNBAE0A/semiconducting-silicon-nanowires?kpromoter=marc  |y Full text