Elektronika 2009-11.pdf - Instytut SystemÃ³w Elektronicznych

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pomiarami - po regeneracji lub powtórnej immobilizacji przeciwciał - immunoczujniki są przechowywane w temperaturze 4ºC. Czas, w którym immunoczujniki wymagające regeneracji zachowują swoje parametry może być liczony nawet w miesiącach i może obejmować kilkadziesiąt cykli pomiarowych i regeneracyjnych. Granicę czasu użytkowania immunoczujnika wyznacza gwałtowny spadek sygnału. Należy podkreślić, że aktywność przeciwciał w roztworze jest na ogół większa niż unieruchomionych na powierzchni. Dobrym środowiskiem dla białek w tym przeciwciał, okazała się matryca złożona z koloidalnych cząsteczek złota zawieszonych w układzie sol-żel, opartym na Al 2 O 3 . Układ ten wykazuje hydrofilowość, dość znaczną porowatość i dodatni ładunek powierzchniowy [61]. Podsumowanie W ciągu ostatnich 20 lat obserwuje się bardzo szybki rozwój metod analitycznych bazujących na układach mikrofluidycznych. Mikroprzepływy są stosowane w systemach do bioanaliz, takich jak: mikroukłady do analizy całościowej - micro-TAS (micro Total Analysis System) lub wielofunkcyjne układy mikroprzepływowe tzw. laboratoria na chipie - Lab On a Chip (LOC). Opracowywane są również narzędzia diagnostyczne i monitoringu środowiska bazujące na układach mikroprzepływowych z wykorzystaniem immunoczujników. Jednym z takich zastosowań jest oznaczanie białka C-reaktywnego w osoczu pacjentów. W naszych pracach dążymy do uzyskania czułego, amperometrycznego immunoczujnika CRP, który mógłby służyć do badań przy łóżku chorego (point-of-care). Literatura [1] Marnell, L., C. Mold, and T. W. D. Clos, C-reactive protein: Ligands, receptors and role in inflammation. Clinical Immunology, 2005, 117, pp. 104-111. [2] Orzędała-Koszel, U., Bachanek T., Kaczmarek-Borowska B.: Białko C-reaktywne jako czynnik diagnostyczny w stanach zapalnych jamy ustnej i chorobach nowotworowych C-Reactive Protein as a Diagnostic Factorin Inflammatory Processes of Oral Cavity and Neoplasma Diseases. Dent. Med. Probl., 2005, 42(1), pp. 131-136. [3] Volanakis, J. E.: Human C-reactive protein: expression, structure, and function Molecular Immunology, 2001, 38, pp. 189-197. [4] Szalai, A. J.: The biological functions of C-reactive protein. Vascular Pharmacology, 2002, 39, pp. 105-107. [5] Mora, S. and Ridker P. M.: Justification for the Use of Statins in Primary Prevention: An Intervention Trial Evaluating Rosuvastatin (JUPITER) - Can C-Reactive Protein Be Used to Target Statin Therapy inPrimary Prevention?The American Journal of Cardiology, 2006, 97(2A), pp. 33A-41A [6] Wiedener, J. M.: C-reactive protein measurenment in the patient with vascular disease. 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Elektronika, 2008, 6, pp. 41-49. [28] Kazimierczak B. and Pijanowska D.G.: Amperometryczne oznaczanie przeciwciał anty-CRP znakowanych fosfatazą alkaliczną. COE 2008, Poznań, 23-25 czerwca, 2008. [29] Kazimierczak B., Pijanowska D.G., and Torbicz W.: Application of enzyme labeled antibodies for immunosensors based on elecetrochemical detection. Pol. J. of Chem, 2008, 82, pp. 1255-1264. [30] Pultar J., et al.: Aptamer-antibody on chip sandwich immunoassay for detection of CRP in spiked serum. Biosensors and Bioelectronics, 2009, 24, pp. 1456-1461. [31] Das T., Mandal C.: Protein A - a new ligand for human C-reactive protein. FEBS Letters, 2004, 576, pp. 107-113. [32] Yang, Y. N., Lin H. I., Wang J. H., Shieh S. C., Lee G. B. : An integrated microfluidic system for C-reactive protein measurement. Biosensors and Bioelectronics, 2009, 24, pp. 3091-3096. 82 ELEKTRONIKA 11/2009
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nież pasmo emisji od około 500 MH
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