Integrated optofluidic microsystem based on vertical high-order one-dimensional silicon photonic crystals

Barillaro, Giuseppe; Merlo, S.; Surdo, Salvatore; Strambini, Lucanos Marsilio; Carpignano, F.

doi:10.1007/s10404-011-0896-0

Cited by 38 publications

(21 citation statements)

References 27 publications

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“…Optical read-out is undoubtedly a very fascinating solution among detection methods, as it allows remote sensing of the investigated parameters, being thus minimally invasive, while miniaturization enables testing with ultra-low quantities of materials, both important factors particularly in the fields of biological, biochemical and biomedical analyses [2]. Various types of sensors that respond to the mentioned requirements have been lately investigated, based on resonant micro-cavities [1,3,4], photonics crystals [5][6][7][8][9], ring resonators [10][11][12][13][14][15], or whispering gallery modes [16], just to cite a few of them. However, there is still the need of demonstrating the functionality of simple and low-cost devices to be used as core elements of micro-opto-fluidic sensors combined with suitable readout methods.…”

Section: Introductionmentioning

confidence: 99%

Flow-through micro-capillary refractive index sensor based on T/R spectral shift monitoring

Rigamonti

Guardamagna

Bello

et al. 2017

Biomed. Opt. Express

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Abstract:We present a flow-through refractive index sensor for measuring the concentration of glucose solutions based on the application of rectangular glass micro-capillaries, with channel depth of 50 µm and 30 µm. A custom designed and 3D printed polymeric shell protects the tiny capillaries, ensuring an easier handling and interconnection with the macrofluidic path. By illuminating the capillary with broadband radiation centered at λ~1.55 µm, both the transmitted (T) and reflected (R) optical spectrum from the capillary are detected with an optical spectrum analyzer, exploiting an all-fiber setup. Monitoring the spectral shift of the ratio T/R in response to increasing concentration of glucose solutions in water we have obtained sensitivities up to 530.9 nm/RIU and limit of detection in the range of 10 −5 -10RIU. Experimental results are in agreement with the theoretically predicted principle of operation. After the demonstration of amplitude detection at a single wavelength, we finally discuss the impact of the capillary parameters on the sensitivity.

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Section: Introductionmentioning

confidence: 99%

Flow-through micro-capillary refractive index sensor based on T/R spectral shift monitoring

Rigamonti

Guardamagna

Bello

et al. 2017

Biomed. Opt. Express

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“…One of these challenges is to create accurate, simple and cheap sensors. Several possible sensor conceptions were suggested [104,105] although they are not really suitable for widespread usage because of their complexity, difficult fabrication processes, and so on. A solution to overcome such a problem might be a usage of an opto-fluidic sensor with a specifically designed microlens array as its main component ( Fig.…”

Section: Opto-fluidicsmentioning

confidence: 99%

Nanophotonic lithography: a versatile tool for manufacturing functional three-dimensional micro-/nano-objects

Malinauskas¹,

Kiršanskė²,

Rekštytė³

et al. 2012

Lith. J. Phys.

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In this paper, an overview of literature supported by original experimental results on direct laser polymerization of three-dimensional micro-/nano-structuring of various photopolymers is presented. Alternative technologies, principles of threshold based direct laser writing in polymers employing ultrafast lasers, issues of optimization of the laser structuring parameters for increasing fabrication resolution and production throughput are presented and discussed. Examples of woodpile templates and nanogratings are shown as well as an opto-fluidic sensor design for usage in lab-on-chip type devices is demonstrated and its performance is characterized. Additionally, a possibility to produce a three-dimensional electric circuit is introduced.

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“…In this perspective, we developed three-dimensional silicon microstructures (3D-SMSs) formed by periodic arrays of parallel ≈3 m-thick silicon walls separated by ≈5 m-wide, 50 m-deep air gaps [5,6]. We demonstrated that these microdevices are suitable for the culture of human cancer cells [7,8] in 3D with a proliferation rate similar to the 2D counterpart.…”

Section: Introductionmentioning

confidence: 99%

An Innovative Cell Microincubator for Drug Discovery Based on 3D Silicon Structures

Aredia

Carpignano

Surdo

et al. 2016

Journal of Nanomaterials

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We recently employed three-dimensional (3D) silicon microstructures (SMSs) consisting in arrays of 3 μm-thick silicon walls separated by 50 μm-deep, 5 μm-wide gaps, as microincubators for monitoring the biomechanical properties of tumor cells. They were here applied to investigate the in vitro behavior of HT1080 human fibrosarcoma cells driven to apoptosis by the chemotherapeutic drug Bleomycin. Our results, obtained by fluorescence microscopy, demonstrated that HT1080 cells exhibited a great ability to colonize the narrow gaps. Remarkably, HT1080 cells grown on 3D-SMS, when treated with the DNA damaging agent Bleomycin under conditions leading to apoptosis, tended to shrink, reducing their volume and mimicking the normal behavior of apoptotic cells, and were prone to leave the gaps. Finally, we performed label-free detection of cells adherent to the vertical silicon wall, inside the gap of 3D-SMS, by exploiting optical low coherence reflectometry using infrared, low power radiation. This kind of approach may become a new tool for increasing automation in the drug discovery area. Our results open new perspectives in view of future applications of the 3D-SMS as the core element of a lab-on-a-chip suitable for screening the effect of new molecules potentially able to kill tumor cells.

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Integrated optofluidic microsystem based on vertical high-order one-dimensional silicon photonic crystals

Cited by 38 publications

References 27 publications

Flow-through micro-capillary refractive index sensor based on T/R spectral shift monitoring

Flow-through micro-capillary refractive index sensor based on T/R spectral shift monitoring

Nanophotonic lithography: a versatile tool for manufacturing functional three-dimensional micro-/nano-objects

An Innovative Cell Microincubator for Drug Discovery Based on 3D Silicon Structures

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