]> 2026-04-12T07:43:20+02:00 Group:Biophysical Equipment Group 220 en Leninsky pr. 38-2, room 18, INEPCP RAS, Moscow https://www.youtube.com/@Neurobiophysics/videos ; https://vimeo.com/user209330965 neurobiophys@gmail.com If you wish like to visit us, please contact us via e-mail: neurobiophys[at]gmail.com or o.v.gradov[at]gmail.com. 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 [https://link.springer.com/chapter/10.1007/978-3-030-77448-6_29].<div class="annotatedImageDiv" typeof="Image" data-resource="Fichier:Spectrozonal LED-Assisted Measurement Regimes.jpg" data-sourceimage="https://wikifab.org/images/7/77/Spectrozonal_LED-Assisted_Measurement_Regimes.jpg"><span ><div class="center"><div class="floatnone"><a href="/wiki/Fichier:Spectrozonal_LED-Assisted_Measurement_Regimes.jpg" class="image"><img alt="Spectrozonal LED-Assisted Measurement Regimes.jpg" src="/images/7/77/Spectrozonal_LED-Assisted_Measurement_Regimes.jpg" width="789" height="172" data-file-width="789" data-file-height="172" /></a></div></div></span></div><br /><br /><br />'''References:'''<br />[1]. <br />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 Lens-Less Microscopes with 206 nm and 254 nm filters (design: O. Gradov, F. Orehov) [https://www.researchgate.net/publication/374849913_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_Optica].<div class="annotatedImageDiv" typeof="Image" data-resource="Fichier:Group-Biophysical Equipment Group Screenshot 3.jpg" data-sourceimage="https://wikifab.org/images/b/bd/Group-Biophysical_Equipment_Group_Screenshot_3.jpg"><span ><div class="center"><div class="floatnone"><a href="/wiki/Fichier:Group-Biophysical_Equipment_Group_Screenshot_3.jpg" class="image"><img alt="Group-Biophysical Equipment Group Screenshot 3.jpg" src="/images/thumb/b/bd/Group-Biophysical_Equipment_Group_Screenshot_3.jpg/1094px-Group-Biophysical_Equipment_Group_Screenshot_3.jpg" width="1094" height="428" data-file-width="1293" data-file-height="506" /></a></div></div></span></div><br /><br /><br />'''References:'''<br /><br />* [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). Instruments for polarizing lens-less microscopy and microphotometry of anisotropic diary or other crystallized media in dehydration / rehydration tests (“facial structures”) [1].<div class="annotatedImageDiv" typeof="Image" data-resource="Fichier:Group-Biophysical Equipment Group Screenshot 2.jpg" data-sourceimage="https://wikifab.org/images/7/7e/Group-Biophysical_Equipment_Group_Screenshot_2.jpg"><span ><div class="center"><div class="floatnone"><a href="/wiki/Fichier:Group-Biophysical_Equipment_Group_Screenshot_2.jpg" class="image"><img alt="Group-Biophysical Equipment Group Screenshot 2.jpg" src="/images/7/7e/Group-Biophysical_Equipment_Group_Screenshot_2.jpg" width="845" height="256" data-file-width="845" data-file-height="256" /></a></div></div></span></div><br /><br /><br />'''References:'''<br /><br />*[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 DIALACTRON (Configuration: CY-F3). Lens-less istrument for cylinder plastic photometric cells with the flexible extensible cell fixer for transfocator-like functioning in different regimes of photometric illumination for external light source positioning.<div class="annotatedImageDiv" typeof="Image" data-resource="Fichier:Group-Biophysical Equipment Group Screenshot 4.jpg" data-sourceimage="https://wikifab.org/images/7/7f/Group-Biophysical_Equipment_Group_Screenshot_4.jpg"><span ><div class="center"><div class="floatnone"><a href="/wiki/Fichier:Group-Biophysical_Equipment_Group_Screenshot_4.jpg" class="image"><img alt="Group-Biophysical Equipment Group Screenshot 4.jpg" src="/images/7/7f/Group-Biophysical_Equipment_Group_Screenshot_4.jpg" width="752" height="553" data-file-width="752" data-file-height="553" /></a></div></div></span></div><br /><br /><br /><br />'''References:'''<br /><br />*[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 DIALACTRON-NEPHELOTRON : Laser lens-less microscope-photometer and nephelometer with the compact UV-A diode laser source (2016-2018). <br/> * [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 See video:<div class="annotatedImageDiv" typeof="Image" data-resource="Fichier:Group-Biophysical Equipment Group Screenshot j.jpg" data-sourceimage="https://wikifab.org/images/8/80/Group-Biophysical_Equipment_Group_Screenshot_j.jpg"><span ><div class="center"><div class="floatnone"><a href="/wiki/Fichier:Group-Biophysical_Equipment_Group_Screenshot_j.jpg" class="image"><img alt="Group-Biophysical Equipment Group Screenshot j.jpg" src="/images/8/80/Group-Biophysical_Equipment_Group_Screenshot_j.jpg" width="551" height="636" data-file-width="551" data-file-height="636" /></a></div></div></span></div><br/> The first version of the multiparametric reader system for multidescriptor mapping of biological samples.<div class="annotatedImageDiv" typeof="Image" data-resource="Fichier:Group-Biophysical Equipment Group 273269b098317eb8ce81d1a7e08759b3.jpg" data-sourceimage="https://wikifab.org/images/5/53/Group-Biophysical_Equipment_Group_273269b098317eb8ce81d1a7e08759b3.jpg"><span ><div class="center"><div class="floatnone"><a href="/wiki/Fichier:Group-Biophysical_Equipment_Group_273269b098317eb8ce81d1a7e08759b3.jpg" class="image"><img alt="Group-Biophysical Equipment Group 273269b098317eb8ce81d1a7e08759b3.jpg" src="/images/5/53/Group-Biophysical_Equipment_Group_273269b098317eb8ce81d1a7e08759b3.jpg" width="600" height="399" data-file-width="600" data-file-height="399" /></a></div></div></span></div><br /><br /><br />The second version of the multiparametric reader system for multidescriptor mapping of biological samples.<div class="annotatedImageDiv" typeof="Image" data-resource="Fichier:Group-Biophysical Equipment Group 943559d5aeb0cc8ec9fdf452f3f4c74b.jpg" data-sourceimage="https://wikifab.org/images/f/f3/Group-Biophysical_Equipment_Group_943559d5aeb0cc8ec9fdf452f3f4c74b.jpg"><span ><div class="center"><div class="floatnone"><a href="/wiki/Fichier:Group-Biophysical_Equipment_Group_943559d5aeb0cc8ec9fdf452f3f4c74b.jpg" class="image"><img alt="Group-Biophysical Equipment Group 943559d5aeb0cc8ec9fdf452f3f4c74b.jpg" src="/images/f/f3/Group-Biophysical_Equipment_Group_943559d5aeb0cc8ec9fdf452f3f4c74b.jpg" width="600" height="390" data-file-width="600" data-file-height="390" /></a></div></div></span></div><div class="annotatedImageDiv" typeof="Image" data-resource="Fichier:Group-Biophysical Equipment Group E0ce03a836f36d7900978663c8f25f6c.jpg" data-sourceimage="https://wikifab.org/images/5/55/Group-Biophysical_Equipment_Group_E0ce03a836f36d7900978663c8f25f6c.jpg"><span ><div class="center"><div class="floatnone"><a href="/wiki/Fichier:Group-Biophysical_Equipment_Group_E0ce03a836f36d7900978663c8f25f6c.jpg" class="image"><img alt="Group-Biophysical Equipment Group E0ce03a836f36d7900978663c8f25f6c.jpg" src="/images/5/55/Group-Biophysical_Equipment_Group_E0ce03a836f36d7900978663c8f25f6c.jpg" width="600" height="450" data-file-width="600" data-file-height="450" /></a></div></div></span></div>Redox-signal conversion into the optical signal using colorimetric / spectrocolorimetric “chemical pixels” (“chemical resells” / “sensels”): A,C – baseline (reactive film without detective dye response); B,D – indicator signal. Equivalent mosaic sensor-converter elements may be assembled using different converters and indicators (not only “pH-pixels” / “pХ-pixels”, but also “electric luminescence pixels”, “magnetic field pixels”, “radiation pixels”).<br /><br/><br /><br />* [https://www.researchgate.net/publication/315589941_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_sen] 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. Ultracompact lab-on-a-chip reader with USB and TRS.<div class="annotatedImageDiv" typeof="Image" data-resource="Fichier:Group-Biophysical Equipment Group 54c3e61189ff8954128c52e616537ed4.jpg" data-sourceimage="https://wikifab.org/images/5/53/Group-Biophysical_Equipment_Group_54c3e61189ff8954128c52e616537ed4.jpg"><span ><div class="center"><div class="floatnone"><a href="/wiki/Fichier:Group-Biophysical_Equipment_Group_54c3e61189ff8954128c52e616537ed4.jpg" class="image"><img alt="Group-Biophysical Equipment Group 54c3e61189ff8954128c52e616537ed4.jpg" src="/images/5/53/Group-Biophysical_Equipment_Group_54c3e61189ff8954128c52e616537ed4.jpg" width="600" height="273" data-file-width="600" data-file-height="273" /></a></div></div></span></div><br /><br /><br /><br/><br /><br />*[https://www.researchgate.net/publication/315589941_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_sen] 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. Instruments for polarizing lens-less microscopy and microphotometry (see above mentioned review paper) : * [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). Basic idea proposed in the paper: * [https://www.researchgate.net/publication/315589941_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_sen] 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. [[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]] DIALACTRON TH2 (Configuration: DROPLETRON) DIALACTRON _ POLAR (Configuration P1) Lens-Less Microscopes with 206 nm and 254 nm interference filters DIALACTRON _ POLAR (Configuration P94) Multiparametric Lens-Less Granulometer and Filter Tester DIALACTRON (Configuration: CY-F3) DIALACTRON-NEPHELOTRON Setup for nanosecond testing of CCD-based optofluidic lens-less microscopes Multiparametric reader system for multidescriptor mapping of biological samples Ultracompact lab-on-a-chip reader with USB and TRS. Community 2024-01-03T15:04:17Z 2460313.1279745 Biophysical Equipment Group 0 0 0