Nanoparticles for in-vitro and in-vivo biosensing and imaging

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32 Bibliography [16] R.A. Zsigmondy. Properties of Colloids. Nobel Lecture., 11, 1926. [17] J. Turkevich. Colloidal Gold Part I: Historical and Preparative Aspects, Morphology and Structure. Gold Bull., 18(3):86–91, 1985. [18] G. Frens. Controlled Nucleation for the Regulation of the Particle Size in Monodisperse Gold Suspensions. Nature Phys. Sci., 241:19–22, 1973. [19] M. Brust; M. Walker; D. Bethell; D. J. Schiffrin and R. Whyman. Synthesis of Thiolderivatised Gold Nanoparticles in a Two-phase Liquid-Liquid System. J. Chem. Soc., pages 801–802, 1994. [20] Greenwood N.N.; Earnshaw A. Chemistry of the Elements. Elsevier Science: Oxford, 1997. [21] Daniel ; Astruc. Chemical Review, 104:293–346, 2004. [22] Zheng J.; Nicovich P.R.; Dickson R.M. Annual Review of Physical Chemistry, 58:409–431, 2007. [23] Kvitek L.; Prucek R. Journal of Material Science, 2005. [24] Lakowicz JR. Radiative decay engineering: biophysical and biomedical applications. Anal Biochem., 298:1–24, 2001. [25] Lakowicz JR; Shen Y.; DAuria S.; Malicka J.; Fang J.; Gryczynski Z.; Gryczynski I. Radiative decay engineering 2. Effects of silver island films on fluorescence intensity, lifetimes, and resonance energy transfer. Anal Biochem., 301:261–277, 2002. [26] Geddes C.D.; Aslan K.; Gryczynski I.; Malicka J.; Lakowicz JR. Radiative decay engineering. In: Geddes CD, Lakowicz JR (eds) Topics in Fluorescent Spectroscopy vol 8: Radiative Decay Engineering. Springer Science-Business Media, Inc, New York, page 405448, 2005. [27] Geddes C.D.; Aslan K.; Gryczynski I.; Malicka J.; Lakowicz JR. Noble-metal surfaces for metal enhanced fluorescence. In: Geddes CD, Lakowicz JR (eds) Topics in Fluorescent Spectroscopy vol 8: Radiative Decay Engineering. Springer Science- Business Media, Inc, New York, page 365401, 2005. [28] Lakowicz JR. Radiative decay engineering 5: metal-enhanced fluorescence and plasmon emission. Anal Biochem, 337:171194, 2005. [29] Prasad P.N. Nanophotonics. Wiley, 2004.
Chapter 1 33 [30] Bohren CF; Huffman DR. Absorption and Scattering of Light by Small Particles. John Wiley and Sons, Inc., New York,, page 530, 1983. [31] Link S. and El-Sayed M.A. J. phys. Chem. B, 103:4212, 1999. [32] Turkevich J.; Stevenson P.C.; Hillier J. Discuss. Faraday Soc., 11:55, 1951. [33] Turkevich J.; Garton G. and Stevenson P. C. J. Colloid Sci., Suppl., 1:26, 1954. [34] Link S. and El-Sayed M.A. J. phys. Chem. B, 103:8410, 1999. [35] Link S.; El-Sayed M.A. Shape and size dependence of radiative, non-radiative and photothermal properties of gold nanocrystals. Int. Reviews in Physical Chemistry, 19 (3):409–453, 2000. [36] Mie G. Articles on the optical characteristics of turbid tubes, especially colloidal metal solutions. Annalen Der Physik., 25 (3):377–445, 1908. [37] Kreibig U. and Vollmer M. Optical Properties of Metal Clusters. Berlin : Springer, 1995. [38] Papavassiliou G.C. Prog. solid st. Chem., 12:185, 1980. [39] Kerker M. The Scattering of Light and Other Electromagnetic Radiation (New York: Academic Press), 1969. [40] Ashcroft N.W. and Mermin N.D. Solid State Physics. Philadelphia, Pennsylvania: Saunders College, 1976. [41] P.B. Johnson and R.W. Christy. Optical-Constants Of Noble-Metals. Phys. Rev. B, 6(12):4370–4379, 1972. [42] Johanna Jacoba Penninkhof. Tunable plasmon resonances in anisotropic metal nanostructures. PhD Thesis, 2006. [43] Henglein A. J. phys. Chem., 97:8457, 1993. [44] S. Link and M.A. El-Sayed. Simulation of the Optical Absorption Spectra of Gold Nanorods as a Function of Their Aspect Ratio and the Effect of the Medium Dielectric Constant. J. Phys. Chem. B, 103:3073–3077, 1999. [45] U. Kreibig and C.V. Fragstein. The Limitation of Electron Mean Free Path in Small Silver Particles. Z. Phys., 224:307323, 1969. [46] Kittel C. Introduction to solid state physics. Wiley, 1996.
Page 1 and 2: UNIVERSITÀ DEGLI STUDI DI MILANO B
Page 3 and 4: CONTENTS 3 3.2 Dynamic Light scatte
Page 5 and 6: CONTENTS 5 5.15.2 Spectral characte
Page 7 and 8: Introduction In the last two decade
Page 9 and 10: Chapter 9 then we have applied the
Page 11 and 12: Chapter 1 Metal nanoparticles 1.1 N
Page 13 and 14: Chapter 1 13 carry out reactions in
Page 15 and 16: Chapter 1 15 donor and the metal at
Page 17 and 18: Chapter 1 17 Figure 1.4: Surface pl
Page 19 and 20: Chapter 1 19 where the scattering a
Page 21 and 22: Chapter 1 21 screens the surface ch
Page 23 and 24: Chapter 1 23 easily be seen from eq
Page 25 and 26: Chapter 1 25 The first is equal to
Page 27 and 28: Chapter 1 27 dipole approximation a
Page 29 and 30: Chapter 1 29 used for disease or ca
Page 31: Bibliography [1] Nanotoxicology: na
Page 35 and 36: Chapter 2 Principles 2.1 Basics of
Page 37 and 38: Chapter 2 37 A direct consequence o
Page 39 and 40: Chapter 2 39 be considerably more c
Page 41 and 42: Chapter 2 41 Figure 2.5: Effect of
Page 43 and 44: Chapter 2 43 2.4 Two-photon excited
Page 45 and 46: Chapter 2 45 m = λV MI hc 2 N A (2
Page 47 and 48: Chapter 2 47 P SF OP E (u, v) = |h(
Page 49 and 50: Chapter 2 49 renditions of the spec
Page 51 and 52: Bibliography [1] Lakowicz J.R. In p
Page 53 and 54: Chapter 2 53 [29] Born M. and Wolf
Page 55 and 56: Chapter 3 55 3.2 Dynamic Light scat
Page 57 and 58: Chapter 3 57 where n is the refract
Page 59 and 60: Chapter 3 59 with g V H (t) ∝ β
Page 61 and 62: Chapter 3 61 κ m (Γ) = dm K(−τ
Page 63 and 64: Chapter 3 63 that plagues conventio
Page 65 and 66: Chapter 3 65 set equal to the new p
Page 67 and 68: Chapter 3 67 the molecules. In orde
Page 69 and 70: Chapter 3 69 number of molecules in
Page 71 and 72: Chapter 3 71 γ 1 G(τ) = V ex 〈C
Page 73 and 74: Chapter 3 73 Figure 3.2: Auto-corre
Page 75 and 76: Chapter 3 75 electronic distortions
Page 77 and 78: Chapter 3 77 Figure 3.5: left panel
Page 79 and 80: Chapter 3 79 p 1 (k, V 0 , ɛ) = 1
Page 81 and 82: Chapter 3 81 3.9.3 Photon Moment An
Page 83 and 84:
Chapter 3 83 Figure 3.6: Schematic
Page 85 and 86:
Bibliography [1] Chu B. In Laser Li
Page 87 and 88:
Chapter 3 87 [27] Eigen S.M. and Ri
Page 89 and 90:
Chapter 3 89 [53] Chen Y., Tekmen M
Page 91 and 92:
Chapter 4 91 • L.Sironi, S.Freddi
Page 93 and 94:
Chapter 4 93 die. Mutations in the
Page 95 and 96:
Chapter 4 95 arm of chromosome 17.
Page 97 and 98:
Chapter 4 97 shown that one of the
Page 99 and 100:
Chapter 4 99 DNA replication while
Page 101 and 102:
Chapter 4 101 4.2). The ratio R = [
Page 103 and 104:
Chapter 4 103 The polydispersity of
Page 105 and 106:
Chapter 4 105 The fitting of the FC
Page 107 and 108:
Chapter 4 107 the streptavidin (4.5
Page 109 and 110:
Chapter 4 109 29 nm for the 10 nm s
Page 111 and 112:
Chapter 4 111 A 1 Γ 1 (nm) λ 1 (n
Page 113 and 114:
Chapter 4 113 Figure 4.8: (Left: Fl
Page 115 and 116:
Chapter 4 115 been systematically i
Page 117 and 118:
Chapter 4 117 Figure 4.12: Left: Me
Page 119 and 120:
Chapter 4 119 at the basis of the o
Page 121 and 122:
Chapter 4 121 presence of p53, comp
Page 123 and 124:
Chapter 4 123 Figure 4.17: The figu
Page 125 and 126:
Chapter 4 125 from probably aspecif
Page 127 and 128:
Chapter 4 127 Figure 4.21: Panel A:
Page 129 and 130:
Bibliography [1] Anker J. N.; Hall
Page 131 and 132:
Chapter 4 131 [47] Das P.; Metiu H.
Page 133 and 134:
Chapter 5 133 In this chapter the c
Page 135 and 136:
Chapter 5 135 Figure 5.1: Left:Symm
Page 137 and 138:
Chapter 5 137 5.3 Experimental deta
Page 139 and 140:
Chapter 5 139 back aperture of the
Page 141 and 142:
Chapter 5 141 5.4.2 Transmission El
Page 143 and 144:
Chapter 5 143 For anisotropic branc
Page 145 and 146:
Chapter 5 145 coefficient D is then
Page 147 and 148:
Chapter 5 147 Figure 5.9: ACF of th
Page 149 and 150:
Chapter 5 149 measured through a ve
Page 151 and 152:
Chapter 5 151 objective in epifluor
Page 153 and 154:
Chapter 5 153 The fitting of FCS cu
Page 155 and 156:
Chapter 5 155 Sample Population (%)
Page 157 and 158:
Chapter 5 157 5.8 Concentration eva
Page 159 and 160:
Chapter 5 159 Figure 5.17: Emission
Page 161 and 162:
Chapter 5 161 5.12 Dependence of TP
Page 163 and 164:
Chapter 5 163 Figure 5.22: Histogra
Page 165 and 166:
Chapter 5 165 5.13 Cellular uptake
Page 167 and 168:
Chapter 5 167 Figure 5.29: NPs obta
Page 169 and 170:
Chapter 5 169 Figure 5.33: Autofluo
Page 171 and 172:
Chapter 5 171 5.14 Photothermal eff
Page 173 and 174:
Chapter 5 173 Figure 5.37: ζ-poten
Page 175 and 176:
Chapter 5 175 Temperature [ ◦ C]
Page 177 and 178:
Chapter 5 177 In figure 5.39 the fl
Page 179 and 180:
Chapter 5 179 P [mW] < τ > [ns] 10
Page 181 and 182:
Chapter 5 181 The dependence of the
Page 183 and 184:
Chapter 6 183 Currently, only alumi
Page 185 and 186:
Chapter 6 185 tact organ studies, a
Page 187 and 188:
Chapter 6 187 with liquid flow chan
Page 189 and 190:
Chapter 6 189 Figure 6.1: DC in clo
Page 191 and 192:
Chapter 6 191 • New contrast agen
Page 193 and 194:
Chapter 6 193 experiments by flowin
Page 195 and 196:
Chapter 6 195 it has discontinuitie
Page 197 and 198:
Chapter 6 197 P t. rection. If all
Page 199 and 200:
Chapter 6 199 Figure 6.6: Commonly
Page 201 and 202:
Chapter 6 201 Figure 6.9: 3D and 2D
Page 203 and 204:
Chapter 6 203 Figure 6.11: (A) NK c
Page 205 and 206:
Chapter 6 205 are somehow confined,
Page 207 and 208:
Chapter 6 207 Figure 6.15: Distance
Page 209 and 210:
Chapter 6 209 Figure 6.18: (A)The s
Page 211 and 212:
Chapter 6 211 Figure 6.21: The figu
Page 213 and 214:
Chapter 6 213 Figure 6.24: Paramete
Page 215 and 216:
Chapter 6 215 of the natural killer
Page 217 and 218:
Chapter 6 217 and CD8 + T cells, is
Page 219 and 220:
Chapter 6 219 6.10.1 TLRs TLRs are
Page 221 and 222:
Chapter 6 221 arise from myeloid pr
Page 223 and 224:
Chapter 6 223 of infection, primari
Page 225 and 226:
Chapter 6 225 Figure 6.30: Lymph-no
Page 227 and 228:
Bibliography [1] A. Diaspro, G. Chi
Page 229 and 230:
Chapter 6 229 [25] E. O. Long. Regu
Page 231 and 232:
Chapter 6 231 [47] S. H. Wei, M. J.
Page 233 and 234:
Chapter 6 233 [72] S. Fossum and W.
Page 235 and 236:
Chapter 235 mode-locked cavity. Thi
Page 237 and 238:
Chapter 237 Figure 6.34: Energy lev
Page 239 and 240:
Chapter 239 Figure 6.37: Prisms seq
Page 241 and 242:
Chapter 241 part of the TE300 and t
Page 243 and 244:
Chapter 243 Figure 6.42: The Olympu
Page 245 and 246:
Chapter 245 a f=100 mm bispherical
Page 247 and 248:
Chapter 247 are just events’ dete
Page 249 and 250:
Chapter 249 smaller quartz cell (He
Page 251 and 252:
Chapter 251 needed to a linear corr
Page 253 and 254:
Chapter 253 Figure 6.48: Channel ar
Page 255 and 256:
Chapter 255 ming for burst height a
Page 257:
Chapter 257 • M. Caccia, T. Gorle
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