Biomedical Engineering Reference
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66. James TD, Sandanayake KRAS, Iguchi R et al (1995) Novel saccharide-photoinduced
electron transfer sensors based on the interaction of boronic acid and amine. J Am Chem
Soc 117:8982-8987
67. James TD, Sandanayake KRAS, Shinkai S (1996) Saccharide sensing with molecular
receptors based on boronic acid. Angew Chem Int Ed Engl 35:1910-1922
68. Wang W, Gao S, Wang B (1999) Building fluorescent sensors by template polymerization:
the preparation of a fluorescent sensor for
D
-fructose. Org Lett 1:1209-1212
69. Wang W, Gao X, Wang B (2002) Boronic acid-based sensors. Curr Org Chem 6:1285-1317
70. Yang W, He H, Drueckhammer DG (2001) Computer-guided design in molecular recogni-
tion: design and synthesis of a glucopyranose receptor. Angew Chem Int Ed Engl
40:1714-1718
71. Yoon J, Czarnik AW (1992) Fluorescent chemosensors of carbohydrates. A means of
chemically communicating the binding of polyols in water based on chelation-enhanced
quenching. J Am Chem Soc 114:5874-5875
72. Fang H, Kaur G, Wang B (2004) Progress in boronic acid-based fluorescent glucose sensors.
J Fluoresc 14:481-489
73. Springsteen G, Wang B (2002) A detailed examination of boronic acid-diol complexation.
Tetrahedron 58:5291-5300
74. Yan J, Springsteen G, Deeter S et al (2004) The relationship among p
K
a
, pH, and binding
constants in the interactions between boronic acids and diols-it is not as simple as it appears.
Tetrahedron 60:11205-11209
75. Badugu R, Lakowicz JR, Geddes CD (2005) Boronic acid fluorescent sensors for monosac-
charide signaling based on the 6-methyoxyquinolinium heterocyclic nucleus: progress toward
noninvasive and continuous glucose monitoring. Bioorg Med Chem 13:113-119
76. Cao H, McGill T, Heagy MD (2004) Substituent effects on monoboronic acid sensors for
saccharides based on N-phenyl-1,8-naphthalenedicarboximides. J Org Chem 69:2959-2966
77. Gamsey S, Miller A, Olmstead MM et al (2007) Boronic acid-based bipyridinium salts as
tunable receptors for monosaccharides and
-hydroxycarboxylates. J Am Chem Soc
a
129:1278-1286
78. Alexeev VL, Das S, Finegold DN et al (2004) Photonic crystal glucose-sensing material for
noninvasive monitoring of glucose in tear fluid. Clin Chem 50:2353-2360
79. DiCesare N, Lakowicz JR (2002) Charge transfer fluorescent probes using boronic acids for
monosaccharide signaling. J Biomed Opt 7:538-545
80. Thoniyot P, Cappuccio FE, Gamsey S et al (2006) Continuous glucose sensing with fluores-
cent thin-film hydrogels. 2. Fiber optic sensor fabrication and in vitro testing. Diabetes
Technol Ther 8:279-287
81. Hansen JS, Christensen JB, Solling TI et al (2011) Ortho-substituted aryl monoboronic acids
have improved selectivity for
D
-glucose relative to
D
-fructose and
L
-lactate. Tetrahedron
67:1334-1340
82. Mulla HR, Agard NJ, Basu A (2004) 3-Methoxycarbonyl-5-nitrophenyl boronic: high affinity
diol recognition at neutral pH. Bioorg Med Chem Lett 14:25-27
83. Tony JD, Phillips MD, Shinkai S (2006) Boronic acids in saccharide recognition. The Royal
Society of Chemistry, Cambridge
84. Yang X, Lee M-C, Sartain F et al (2006) Designed boronate ligands for glucose-selective
holographic sensors. Chem-Eur J 12:8491-8497
85. Jiang S, Escobedo JO, Kim KK et al (2006) Stereochemical and regiochemical trends in the
selective detection of saccharides. J Am Chem Soc 128:12221-12228
86. Soundararajan S, Badawi M, Kohlrust CM et al (1989) Boronic acids for affinity chromatog-
raphy: spectral methods for determinations of ionization and diol-binding constants. Anal
Biochem 178:125-134
87. Kitano S, Hisamitsu I, Koyama Y et al (1991) Effect of the incorporation of amino groups in a
glucose-responsive polymer complex having phenylboronic acid moieties. Polym Adv
Technol 2:261-264
88. Linnane P, James TD, Shinkai S (1995) The synthesis and properties of a calixarene-based
'sugar bowl'. J Chem Soc Chem Commun 1995:1997-1998
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