Los inmunoensayos ópticos requieren de sistemas de medición capaces de distinguir la luz de la fuente láser, utilizada para iluminar el ensayo, de aquella generada por las partículas contenidas en el mismo (fluorescencia). El principal desafío es que la luz usada para excitar la muestra es varios órdenes de magnitud más intensa que la generada por fluorescencia. Usualmente, se utilizan filtros ópticos y fotodiodos de juntura simple. La sensibilidad de estos esquemas se encuentra limitada por el desempeño del filtro. En este trabajo se presenta el diseño de un circuito integrado de lectura que incorpora fotodiodos de doble juntura, lo que permite la medición de ambas fuentes de luz en simultáneo. A partir de simulaciones, se demuestra que este enfoque lograría un mejor límite de detección que el esquema basado en fotodiodos de juntura simple de igual área. Además, la integración del circuito de lectura y los fotoreceptores en un mismo chip, favorecería la miniaturización y portabilidad del sistema para aplicaciones biomédicas como en dispositivos Point-of-Care (POC).

inmunoensayos; fotodiodos; point-of-care; CMOS

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