Version du 3 janvier 2024 à 14:17

Biophysical Equipment GroupCommunity Communauté

https://www.youtube.com/@Neurobiophysics/videos ; https://vimeo.com/user209330965

Leninsky pr. 38-2, room 18, INEPCP RAS, Moscow neurobiophys@gmail.com https://www.youtube.com/@Neurobiophysics/videos

CCD-or CMOS-lab-on-a-chip based on discrete converters of different physical and chemical parameters of samples into the optical signals with positional sensitivity for morphometry of non-optical patterns

A novel ultra-compact analytical system for simultaneous analysis of a variety of physical and chemical parameters of different biological samples (medical or veterinary analytes, food, soil microbiota, hydrobiological water probes etc.) both in the field and laboratory conditions has been developed on the basis of a single multiparametric microchip with a set of replaceable cartridges / converters, which allows to perform a complex diagnostic procedure of the analyte. The prototypes of automatic microfluidic devices for multiparametric mapping of biochemical and synthetic analytes using planar converters-visualizers have been designed. We propose to use a lab-on-a-chip with a number of replaceable cartridges-converters of various physical parameters / variables to optical signals, which can be detected using CMOS or CCD, as a single analytic and microelectronic platform for mapping and visualization of different physical and chemical parameters. The above system allows to perform a simultaneous mapping, detection and visualization of a number of the sample characteristics, such as: magnetic field (using magnetic film indicators and flux-detectors); electrochemical parameters (potentiometric indicators); laser beam transmission outside the visible spectral range (using the doped solid matrices); distribution of the emitting regions in autoradiography (using the scintillation detectors with different quenching factors or "position-sensitive spinthariscopes"); polarization characteristics and the angular fluorescence polarization (using polaroid films with the rotation angles changed by the stepper motors); the local biothermogenesis temperature of the sample at different points on a chip (according to the NIR-HDRI thermography principles), etc.

Très difficile
1 month(s)

Oleg Gradov

L'utilisateur n'a pas rentré d'informations à son sujet

Group-Biophysical Equipment Group 170814-1840.jpg

DIALACTRON TH2 (Configuration: DROPLETRON)

Device for the morphometric and photometric measurements of the sample droplets supplied from the pipette / micropipette tips and cuvettes/ cells (2017-2020). This setup can be used with the permanent monitoring of temperature and humidity in the cell and in the external medium [1].

Spectrozonal LED-Assisted Measurement Regimes.jpg

References: [1].

Orekhov, T. K. and Gradov, O. V. (2021). Digital spectrozonal and multispectral lens-less devices with spectrophotometric temperature calibration guis for dairy farming and qualimetry of diary products. Lecture Notes in Networks and Systems, volume 228, pages 300–324. DOI: 10.1007/978-3-030-77448-6_29

Group-Biophysical Equipment Group 170815-1532 003 .jpg

DIALACTRON _ POLAR (Configuration P1)

Instruments for polarizing lens-less microscopy and microphotometry of anisotropic diary or other crystallized media in dehydration / rehydration tests (“facial structures”) [1].

Group-Biophysical Equipment Group Screenshot 2.jpg

References:

[1]. Orekhov, T. K. and Gradov, O. V. (2021). Digital spectrozonal and multispectral lens-less devices with spectrophotometric temperature calibration guis for dairy farming and qualimetry of diary products. Lecture Notes in Networks and Systems, volume 228, pages 300–324. DOI: 10.1007/978-3-030-77448-6_29

Group-Biophysical Equipment Group 170727-1311 002 .jpg

Lens-Less Microscopes with 206 nm and 254 nm interference filters

Lens-Less Microscopes with 206 nm and 254 nm filters (design: O. Gradov, F. Orehov) [2].

References:

[2]. Orekhov, F. K. and Gradov, O. V. (2023). Towards ultraviolet microbeam scanning and lens-less UV microbeam microscopy with mirror galvanometric scanners: From the history of research instrumentation to engineering of modern mechatronic optical systems. Journal of Sensor Networks and Data Communications, 3(1):117–137 (Invited Paper).

Group-Biophysical Equipment Group 170815-1529 001 .jpg

DIALACTRON _ POLAR (Configuration P94)

Instruments for polarizing lens-less microscopy and microphotometry (see above mentioned : [1]. Orekhov, T. K. and Gradov, O. V. (2021). Digital spectrozonal and multispectral lens-less devices with spectrophotometric temperature calibration guis for dairy farming and qualimetry of diary products. Lecture Notes in Networks and Systems, volume 228, pages 300–324. DOI: 10.1007/978-3-030-77448-6_29).

Group-Biophysical Equipment Group 170815-1531 001 .jpg

Multiparametric Lens-Less Granulometer and Filter Tester

Basic idea proposed in the paper: [3] Gradov, O. V. and Jablokov, A. G. (2016). Novel morphometrics-on-a-chip: CCD- or CMOS-lab-on-a-chip based on discrete converters of different physical and chemical parameters of histological samples into the optical signals with positional sensitivity for morphometry of non-optical patterns. Journal of Biomedical Technologies, (2):1–29.

Description

Téléphone

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