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Double modified internal gate (MIG) pixel for fluorescence imaging applications

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Abstract:

In this work we present a double modified internal gate (MIG) pixel structure, fabricated in a slightly modified 0.35 mum CMOS process, to be effectively used in, e.g. lo...Show More

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Abstract:

In this work we present a double modified internal gate (MIG) pixel structure, fabricated in a slightly modified 0.35 mum CMOS process, to be effectively used in, e.g. low-level irradiance fluorescent imaging applications. The pixel structure enables a non-destructive readout, which facilitates a constant monitoring of the molecule fluorescence process. The readout is based on signal averaging and up-the-ramp sampling current differential readout, which drastically reduces the amount of noise in the pixel output signal. The modified internal gates enable extremely low dark-current and very low-noise operation.

Published in: 2009 European Conference on Circuit Theory and Design

Date of Conference: 23-27 August 2009

Date Added to IEEE Xplore: 02 October 2009

CD:978-1-4244-3896-9

DOI: 10.1109/ECCTD.2009.5275141

Conference Location: Antalya, Turkey

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Contents

I. Introduction

Nowadays, the whole-body and intravital optical imaging [1], [2] has become a very popular technique in medical research dealing with spatial-temporal behaviour of infectious processes. This approach is based on monitoring the luminance of green fluorescent protein (GFP)-expressing bacteria from outside intact infected animals, where no substrate injection, radioactivity, contrast agent, or anaesthesia is required [1]. The latter is normally achieved through an optical excitation induced using lasers, mercury lamps, or LEDs [3]. On the other hand, the multiple single-molecule fluorescence microscopy [4] is currently used in the DNA analysis, where nanometer-localized multiple single-molecules (NALMS) can be properly localized by use of centroid localization and photobleaching (degradation of the emitted radiation intensity) of the single fluorophores [4]. In both applications, solid-state imagers are required to acquire the emitted fluorescence light, which should operate with extremely long photogenerated charge collection times ranging from several milliseconds to several seconds in extreme cases, and very low radiant fluxes. For example, for the multiple single-molecule fluorescence microscopy application reported in [4], each “count” detected by a CCD imager operated in frame transfer mode and cooled to , using 1s charge collection times for each frame, corresponds to roughly two collected photons. In both applications described, the emitting radiation corresponds to visible part of the spectra (with wavelengths ).

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P. Lechnera, R. Hartmanna, P. Holla, G. Lutzb, N. Meidingerb,d, R. H. Richterb, H. Soltaua, L. Strüder, "X-ray imaging spectrometers in present and future satellite missions", Nuclear Instruments and Methods in Physics Research, A 509, 2003, pp. 302-314

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Double modified internal gate (MIG) pixel for fluorescence imaging applications

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I. Introduction

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Double modified internal gate (MIG) pixel for fluorescence imaging applications

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I. Introduction

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