Chemistry Reference
In-Depth Information
44. Simion, M.; Iorgulescu, E.E.; Angelescu, A.; Kleps, I.; Miu, M. and Bragaru, A. (2002) Micro and nanoelectrode
voltammetric measurements,
International Semiconductor Conference CAS 2002 Proceedings
, 123-126.
45. Heller, A. and Feldman, B. (2008) Electrochemical glucose sensors and their applications in diabetes management,
Chem. Rev.
,
108
, 2482-2505.
46. Green, M. and Hilditch, P. (1991) Disposable Single-Use Sensors,
Anal. Proc.
,
28
, 374-376.
47. Erickson, K. and Wilding, P. (1993) Evaluation of a novel point-of-care system, the I-STAT portable clinical
analyzer,
Clin. Chem.
,
39
, 283-287.
48. Wang, J.; Tian, B.; Lu, J.; Olsen, C.; Yarnitsky, C.; Olsen, K.; Hammerstrom, D. and Bennett, W. (1999) Stripping
analysis into the 21st century: faster, smaller, cheaper, simpler and better,
Anal. Chim. Acta
,
385
, 429-435.
49. Eiceman, G.A. and Karpas, Z. (1994) Ion Mobility Spectrometry, CRC Press, Boca Raton.
50. Young, D.; Thomas, C.L.P.; Breach, J.; Brittain, A.H. and Eiceman, G.A. (1999) Extending the concentration and
linear dynamic range of ion mobility spectrometry with a sheath flow inlet,
Anal. Chim. Acta
,
381
, 69-83.
51. Ewing, R.G.; Atkinson, D.A.; Eiceman, G.A. and Ewing, G.J. (2001) A critical review of ion mobility spectrometry
for the detection of explosives and explosive related compounds,
Talanta
,
54
, 515-529.
52. Karpas, Z.; Tilman, B.; Gdalevsky, R. and Lorber, A. (2002) Determination of volatile biogenic amines in muscle
food products by ion mobility spectrometry,
Anal. Chim. Acta
,
463
, 155-163.
53. Eiceman, G.A.; Nazarov, E.G.; Tadjikov, B. and Miller, R.A. (2000) Monitoring volatile organic compounds in
ambient air inside and outside buildings with the use of a radio-frequency-based ion-mobility analyzer with a
micromachined drift tube,
Field Anal. Chem. Technol.
,
4
, 297-308.
54. Arce, L.; Menendez, M.; Garrido-Delgado, R. and Valcarcel, M. (2008) Sample-introduction systems coupled to
ion-mobility spectrometry equipment for determining compounds present in gaseous, liquid and solid samples,
TrAC-Trend Anal. Chem.
,
27
, 139-150.
55. Agilent Technologies (2011) Compact, portable, and handheld FTIR solutions for solid and liquid analysis,
publication number: 5990-8674EN. Available at http://www.chem.agilent.com/Library/flyers/Public/5990-
8674EN_Flyer_4100_4200_4500_5500.pdf (accessed November 3, 2011).
56. Axsun Technologies, Inc. (2007) AnavoTM Handheld NIR material Analyzer, data sheet. Available at http://www.
axsun.com/PDF/Anavo_Handheld_NIR.pdf (accessed November 3, 2011).
57. Kemeny, G.J. (2008) Process Analysis
in Handbook of Near Infrared Analysis
, 3rd edn (eds. D.A. Burns and
E.W. Ciurczak), CRC Press, Boca Raton.
58. Wesley, I.J.; Larsen, N.; Osborne, B.G. and Skerritt, J.H. (1998) Non-invasive monitoring of dough mixing by near-
infrared spectroscopy,
J
.
Cereal Sci.
,
27
, 61-69.
59. Determination of Protein by Near Infrared Reflectance (NIR) Spectroscopy (1995) Standard Method of the
International Association for Cereal Science and Technology. Available at http://www.icc.or.at/standard_
methods/159 (accessed 3 November 2011).
60. Hildrum, K.I.; Nilsen, B.N.; Westad, F. and Wahlgren, N.M. (2004) In-line analysis of ground beef using a diode
array near infrared instrument on a conveyor belt,
J
.
Near Infrared Spectrosc.
,
12
, 367-376.
61. Fearn, T. and Maris, P.I. (1991) An application of box-jenkins methodology to the control of gluten addition in a
flour mill,
Appl. Statist.
,
40
, 477-484.
62. Blanco, M. and Romero, M.A. (2001) Near-infrared libraries in the pharmaceutical industry,
Analyst
,
126
,
2212-2217.
63. Woo, Y.A.; Kim, H.J. and Cho, J. (1999) Identification of herbal medicines using pattern recognition techniques
with near-infrared reflectance spectra,
Microchem. J.
,
63
, 61-70.
64. Lewis, I.R. and Rosenblum, S.S. (2002) General introduction to fiber-optics, in
Handbook of Vibrational
Spectroscopy
(eds J. Chalmers and P.R. Griffiths), John Wiley & Sons, Ltd, Chichester.
65. Eliasson, C.; Macleod, N.A. and Matousek, P. (2007) Noninvasive detection of concealed liquid explosives using
Raman spectroscopy,
Anal. Chem.
,
79
, 8185-8189.
66. Eliasson, C.; Macleod, N.A. and Matousek, P. (2008) Non-invasive detection of cocaine dissolved in beverages
using displaced Raman spectroscopy,
Anal. Chim. Acta
,
607
, 50-53.
67.
Kim, M.; Chung, H.; Woo, Y. and Kemper, M.S. (2007) A new non-invasive, quantitative Raman technique for the
determination of an active ingredient in pharmaceutical liquids by direct measurement through a plastic bottle,
Anal.
Chim. Acta
,
587
, 200-207.