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Staff member

Silvia Catalina Blanco Rueda

Staff member publications

Concentrations down to 3 nM of the rhS100A4 protein, associated with human tumor development, have been detected in undiluted urine using an integrated sensor based on microring resonators in the emerging Al2O3 photonic platform. The fabricated microrings were designed for operation in the C-band (λ = 1565 nm) and exhibited a high-quality factor in air of 3.2 × 105. The bulk refractive index sensitivity of the devices was ~100 nm/RIU (for TM polarization) with a limit of detection of ~10−6 RIU. A surface functionalization protocol was developed to allow for the selective binding of the monoclonal antibodies designed to capture the target biomarker to the surface of the Al2O3 microrings. The detection of rhS100A4 proteins at clinically relevant concentrations in urine is a big milestone towards the use of biosensors for the screening and early diagnosis of different cancers. Biosensors based on this microring technology can lead to portable, multiplexed and easy-to-use point of care devices.

JTD Keywords: Distributed feedback lasers, Effective refractive index, Laser coupling, Polarization maintaining fibers, Refractive index, Scanning electron microscopy


Al2O3 microresonators were realized for sensing applications of both passive and active devices. Passive microring resonators exhibited quality factors up to 3.2×105 in air. A bulk refractive index sensitivity of 100 nm/RIU was demonstrated together with a limit of detection of 10-6 RIU. Functionalizing their surface allowed for the label-free detection of the biomarker rhS100A4 from urine with a limit of detection of 3 nM. Furthermore, single-mode Al2O3:Yb3+ microdisk lasers were realized that could operate in an aqueous environment. Upon varying the bulk refractive index their lasing wavelength could be tuned with a sensitivity of 20 nm/RIU and a LOD of 3×10-6 RIU.

JTD


The Al2O3 waveguide technology was explored for sensing applications. Passive microring resonators with a quality factor in air of 3.2×105 were developed with a bulk refractive index sensitivity of ~100 nm/RIU and limit of detection of ~10-6 RIU. These were functionalized to detect the biomarker rhS100A4 from urine down to concentrations of 3 nM. Furthermore, Al2O3:Yb3+ microdisk lasers were realized that exhibited single mode lasing operation in water. Their lasing wavelength was tuned by varying the bulk refractive index and a bulk refractive index sensitivity of ~20 nm/RIU with a LOD of ~3×10-6 was achieved.

JTD


Microring resonators find many applications for on-chip integrated optical sensors. Their spectral response contains resonance dips that shift due to variations of the optical path length of the microring probed. Numerous examples of such microring resonator sensors in the SOI, Si3N4 and SiON waveguide technologies have been reported for the detection of bulk refractive index variations and the label-free detection of biomarkers. Al2O3 is an alternative waveguide technology that exhibits low optical propagation losses, is transparent over a large spectral range extending from the visible to the mid-IR and permits co-doping with active rare-earth ions, which enables the co-integration of active devices on the chip. In this work an Al2O3 microring resonator sensor was developed for the label-free detection of protein biomarkers. The uncladded microring with a radius of 200 μm had a measured quality factor of 3.2 × 105 at 1550 nm. Submerging the devices in water decreased the quality factor to 45 × 103. This corresponds with propagation losses in the rings of 0.6 dB/cm and 5.7 dB/cm respectively. The bulk refractive index sensitivity of the sensor was determined by flowing NaCl dissolved in water in different concentrations. A sensitivity of 102.3 ± 0.5 nm/RIU with a corresponding limit of detection of 1.6 × 10-6 RIU was demonstrated for TM polarized light. High affinity human monoclonal antibodies mAb S100A4 were immobilized on the sensor to detect the S100A4 protein biomarker down to 12 nM concentrations. These results demonstrate the feasibility of this material for label-free optical biosensors.

JTD