W. Richard Bowen and Nidal Hilal 4

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28 1. BAsIC PRINCIPLEs OF ATOMIC FORCE MICROsCOPy [79] I. Dulinska, M. Targosz, W. Strojny, M. Lekka, P. Czuba, W. Balwierz, M. Szymonski, Stiffness of normal and pathological erythrocytes studied by means of atomic force microscopy, J. Biochem. Biophys. Meth. 66 (2006) 1–11. [80] A.L. Weisenhorn, P. Maivald, H.-J. Butt, P.K. Hansma, Measuring adhesion, attraction and repulsion between surfaces in liquids with an atomic force microscope, Phys. Rev. B 45 (19) (1992) 11226–11233. [81] C.J. Roberts, What can we learn from atomic force microscopy adhesion measurements with single drug particles?, Eur. J. Pharm. Sci. 24 (2005) 153–157. [82] M. Kapple, H.-J. Butt, The colloidal probe technique and its application to adhesion force measurements, Part. Part. Syst. Charact. 19 (2002) 129–143. [83] W.R. Bowen, N. Hilal, R.W. Lovitt, C.J. Wright, An atomic force microscopy study of the adhesion of a silica sphere to a silica surface – effects of surface cleaning, Colloids Surf. A: Physicochem Eng. Aspects 157 (1999) 117–125. [84] J.K. Eve, N. Patel, S.Y. Luk, S.J. Ebbens, C.J. Roberts, A study of single drug particle adhesion interactions using atomic force microscopy, Int. J. Pharm. 238 (2002) 17–27. [85] L. Xu, B.E. Logan, Analysis of bacterial adhesion using a gradient force analysis method and colloid probe microscopy, Langmuir 20 (2004) 8817–8822. [86] N.A. Burnham, D.D. Dominguez, R.L. Mowery, R.J. Colton, Probing the surface forces of monolayer films with an atomic force microscope, Phys. Rev. Lett. 64 (16) (1990) 1931–1934. [87] M. Davies, A. Brindley, X. Chen, M. Marlow, S.W. Doughty, I. Shrubb, C.J. Roberts, Characterization of drug particle surface energetics and Young’s modulus by atomic force microscopy, Pharm. Res. 22 (7) (2005) 1158–1166. [88] G. Gillies, M. Kapple, H.-J. Butt, Surface and capillary forces encountered by zinc sulfide microspheres in aqueous electrolyte, Langmuir 21 (2005) 5882–5886. [89] P.G. Hartley, F. Grieser, P. Mulvaney, G.W. Stevens, Surface forces and deformation at the oil–water interface probed using AFM force measurement, Langmuir 15 (1999) 7282–7289. [90] S. Allen, X. Chen, J. Davies, M.D. Davies, A.C. Dawkes, J.C. Edwards, C.J. Roberts, J. Sefton, S.J.B. Tendler, P.M. Williams, Detection of antigen–antibody binding events with the atomic force microscope, Biochemistry 36 (1997) 7457–7463. [91] R.B. Best, D.J. Brockwell, J.L. Toca-Herrerra, A.W. Blake, D.A. Smith, S.E. Radford, J. Clarke, Force mode atomic force microscopy as a tool for protein folding studies, Anal. Chim. Acta 479 (2003) 87–105. [92] J. Clarke, P.M. Williams, Unfolding induced by mechanical force, in: J. Buchner and T. Kiefhaber (Ed.), Protein Folding Handbook, Part 1, Wiley-VCH, 2005, pp. 1111–1142. [93] M. Rief, M. Gautel, F. Oesterhelt, J.M. Fernandez, H.E. Gaub, Reversible unfolding of individual titin immunoglobulin domains by AFM, Science 276 (1997) 1109–1113. [94] M.J. Higgins, R. Proksch, J.E. Sader, M. Polcik, S. McEndoo, J.P. Cleveland, S.P. Jarvis, Noninvasive determination of optical lever sensitivity in atomic force microscopy, Rev. Sci. Instrum. 77 (2006) 013701. [95] J.P. Cleveland, S. Manne, D. Bocek, P.K. Hansma, A nondestructive method for determining the spring constant of cantilevers for scanning force microscopy, Rev. Sci. Instrum. 64 (2) (1993) 403–405. [96] J.E. Sader, Parallel beam approximation for v-shaped atomic force microscopy cantilevers, Rev. Sci. Instrum. 66 (9) (1995) 4583–4586. [97] C.T. Gibson, D.J. Johnson, C. Anderson, C. Abell, T. Rayment, Method to determine the spring constant of atomic force microscope cantilevers, Rev. Sci. Instrum. 75 (2) (2004) 565–567. [98] J.E. Sader, I. Larson, P. Mulvaney, L.R. White, Method for the calibration of atomic force microscopy cantilevers, Rev. Sci. Instrum. 66 (7) (1995) 3789–3798. [99] J.E. Sader, Frequency response of cantilever beams immersed in viscous fluids with applications to the atomic force microscope, J. Appl. Phys. 84 (1) (1998) 64–76.
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Page 2 and 3: Butterworth-Heinemann is an imprint
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Page 6 and 7: xii Preface them from hostile condi
Page 8 and 9: xiv About thE Editors Professor Nid
Page 10 and 11: xvi List of Contributors Dr Daniel
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78 2. MEASUREMENT OF PARTICLE ANd S
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80 2. MEASUREMENT OF PARTICLE ANd S
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82 3. QUANTIFICATION OF PARTICLE-BU
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100 3. QUANTIFICATION OF PARTICLE-B
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C H A P T E R 4 Investigating Membr
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4.2 THE RANgE OF POssIbILITIEs FOR
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4.2 THE RANgE OF POssIbILITIEs FOR
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4.3 CORREsPONdENCE bETwEEN sURFACE
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4.3 CORREsPONdENCE bETwEEN sURFACE
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4.4 IMAgINg IN LIqUId ANd THE dETER
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4.4 IMAgINg IN LIqUId ANd THE dETER
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4.5 EFFECTs OF sURFACE ROUgHNEss ON
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4.6 ‘vIsUALIsATION’ OF THE REjE
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4.7 THE UsE OF AFM IN MEMbRANE dEvE
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Dfractional 0.18 0.16 0.14 0.12 0.1
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4.8 CHARACTERIsATION OF METAL sURFA
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At pH 5.5, dissolution began to occ
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REFERENCEs 137 [4] W.R. Bowen, N. H
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C H A P T E R 5 AFM and Development
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5.2 MEAsUREMENT OF ADHEsION OF COLL
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5.2 MEAsUREMENT OF ADHEsION OF COLL
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The antibacterial activity of initi
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5.3 MODIFICATION OF MEMBRANEs 147 t
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5.3 MODIFICATION OF MEMBRANEs 149 B
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Force (nN m -1 ) Loading force (mN
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5.3 MODIFICATION OF MEMBRANEs 153 p
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Adhesion force (mN m -1 ) 10 8 6 4
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Adhesion force (mN m -1 ) 20 15 10
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Adhesion force (mN m -1 ) 10 8 6 4
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5.3 MODIFICATION OF MEMBRANEs 161 F
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5.4 MODIFICATION OF MEMBRANEs wITH
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5.4 MODIFICATION OF MEMBRANEs wITH
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Å 200 100 0 5.4 MODIFICATION OF ME
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AbbrEvIAtIonS And SyMbolS NOM Natur
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REFERENCEs 171 [29] W.R. Bowen, T.A
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174 6. NANOSCALE ANALySIS Of PHARMA
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196 7. MICRO/NANOENgINEERINg ANd AF
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246 9. APPLICATION OF ATOMIC FORCE
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276 10. FuTuRE PRosPECTs most AFM s
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278 10. FuTuRE PRosPECTs targeted d
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A Actin stress fiber, 197 Adhesion,
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Natural organic matter, 140 Negativ
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