ACHIEVEMENTS IN PHYSICAL CHEMISTRY IN THE FIELD OF MICROSCOPY AND VISUALIZATION OF NANOSYSTEMS

ACHIEVEMENTS IN PHYSICAL CHEMISTRY IN THE FIELD OF MICROSCOPY AND VISUALIZATION OF NANOSYSTEMS

The review presents modern views and the history of the development of microscopic studies of nanosystems which heve been started 2014, after the Nobel Prize in Chemistry was awarded to Eric Betzig, William Mörner, and Stefan Gell "for the development of super-resolved fluorescence microscopy&q...

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Date:2023
Main Author: Ogenko, Volodymyr
Format: Article
Language:English
Published: V.I.Vernadsky Institute of General and Inorganic Chemistry 2023
Online Access:https://ucj.org.ua/index.php/journal/article/view/575
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Journal Title:Ukrainian Chemistry Journal

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Ukrainian Chemistry Journal
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spelling oai:ojs2.1444248.nisspano.web.hosting-test.net:article-5752023-12-22T17:00:54Z ACHIEVEMENTS IN PHYSICAL CHEMISTRY IN THE FIELD OF MICROSCOPY AND VISUALIZATION OF NANOSYSTEMS Ogenko, Volodymyr Fluorescence microscopy, optical interference microscopy, plasmon microscopy, super-resolution STED microscopy, nanosystems. The review presents modern views and the history of the development of microscopic studies of nanosystems which heve been started 2014, after the Nobel Prize in Chemistry was awarded to Eric Betzig, William Mörner, and Stefan Gell "for the development of super-resolved fluorescence microscopy". Their work ushered in a new era of optical microscopy, enabling the precise examination of individual molecules and molecular clusters by using optical microscopes. By circumventing the diffraction limitations that had constrained traditional optical microscopes, scientists gained access to the nanoscale realm, investigating structures within the 1–100 nanometer range. Special attention is paid to the use of carbon quantum dots and plasmon resonance to enhance fluorescence when obtaining the effect of super-resolution images, which allow the use of optical microscopes in the estimation of the sizes of cluster and single molecules. This breakthrough in removing the diffraction li­mitation allowed scientists to use the working range of 1–100 nm and obtain 3D images of nanosystems and images of living cells. Particular attention is paid to the achievements and prospects of high-resolution fluorescent nanoscopy SRM, which is successfully deve­lo­ping and studying the nanoworld in the range of 1–100 nm at the level of scanning electron microscopy. In cell biology, nanomedicine, etc. are developing roadmaps for scientific breakthroughs in super-resolution visualization me­thods for "live" images. Prospects of Immuno-­SERS microscopy and medicine of indivi­dual diagnosis are considered Key Findings: This article highlights the achievements and future prospects of super-resolution fluorescence microscopy SRM. High-resolution fluorescence microscopy has proven instrumental in advancing our understanding of the living world within the 1–100 nanometer range, which is akin to the capabilities of scanning electron microscopy. Within the domains of cell biology and nanomedicine, roadmaps for scientific breakthroughs are emerging, fueled by super-re­so­lution imaging techniques, providing "live" insights into cellular processes. The horizons of Immuno-SERS Microscopy and Personalized Diagnostics Medicine are expanding, promising exciting prospects in the field of medical diagnostics. V.I.Vernadsky Institute of General and Inorganic Chemistry 2023-09-29 Article Article Physical chemistry Физическая xимия Фізична xімія application/pdf https://ucj.org.ua/index.php/journal/article/view/575 10.33609/2708-129X.89.08.2023.63-77 Ukrainian Chemistry Journal; Vol. 89 No. 8 (2023): Ukrainian Chemistry Journal; 63-77 Украинский химический журнал; Том 89 № 8 (2023): Ukrainian Chemistry Journal; 63-77 Український хімічний журнал; Том 89 № 8 (2023): Ukrainian Chemistry Journal; 63-77 2708-129X 2708-1281 en https://ucj.org.ua/index.php/journal/article/view/575/292
institution Ukrainian Chemistry Journal
baseUrl_str
datestamp_date 2023-12-22T17:00:54Z
collection OJS
language English
topic_facet Fluorescence microscopy
optical interference microscopy
plasmon microscopy
super-resolution STED microscopy
nanosystems.
format Article
author Ogenko, Volodymyr
spellingShingle Ogenko, Volodymyr
ACHIEVEMENTS IN PHYSICAL CHEMISTRY IN THE FIELD OF MICROSCOPY AND VISUALIZATION OF NANOSYSTEMS
author_facet Ogenko, Volodymyr
author_sort Ogenko, Volodymyr
title ACHIEVEMENTS IN PHYSICAL CHEMISTRY IN THE FIELD OF MICROSCOPY AND VISUALIZATION OF NANOSYSTEMS
title_short ACHIEVEMENTS IN PHYSICAL CHEMISTRY IN THE FIELD OF MICROSCOPY AND VISUALIZATION OF NANOSYSTEMS
title_full ACHIEVEMENTS IN PHYSICAL CHEMISTRY IN THE FIELD OF MICROSCOPY AND VISUALIZATION OF NANOSYSTEMS
title_fullStr ACHIEVEMENTS IN PHYSICAL CHEMISTRY IN THE FIELD OF MICROSCOPY AND VISUALIZATION OF NANOSYSTEMS
title_full_unstemmed ACHIEVEMENTS IN PHYSICAL CHEMISTRY IN THE FIELD OF MICROSCOPY AND VISUALIZATION OF NANOSYSTEMS
title_sort achievements in physical chemistry in the field of microscopy and visualization of nanosystems
description The review presents modern views and the history of the development of microscopic studies of nanosystems which heve been started 2014, after the Nobel Prize in Chemistry was awarded to Eric Betzig, William Mörner, and Stefan Gell "for the development of super-resolved fluorescence microscopy". Their work ushered in a new era of optical microscopy, enabling the precise examination of individual molecules and molecular clusters by using optical microscopes. By circumventing the diffraction limitations that had constrained traditional optical microscopes, scientists gained access to the nanoscale realm, investigating structures within the 1–100 nanometer range. Special attention is paid to the use of carbon quantum dots and plasmon resonance to enhance fluorescence when obtaining the effect of super-resolution images, which allow the use of optical microscopes in the estimation of the sizes of cluster and single molecules. This breakthrough in removing the diffraction li­mitation allowed scientists to use the working range of 1–100 nm and obtain 3D images of nanosystems and images of living cells. Particular attention is paid to the achievements and prospects of high-resolution fluorescent nanoscopy SRM, which is successfully deve­lo­ping and studying the nanoworld in the range of 1–100 nm at the level of scanning electron microscopy. In cell biology, nanomedicine, etc. are developing roadmaps for scientific breakthroughs in super-resolution visualization me­thods for "live" images. Prospects of Immuno-­SERS microscopy and medicine of indivi­dual diagnosis are considered Key Findings: This article highlights the achievements and future prospects of super-resolution fluorescence microscopy SRM. High-resolution fluorescence microscopy has proven instrumental in advancing our understanding of the living world within the 1–100 nanometer range, which is akin to the capabilities of scanning electron microscopy. Within the domains of cell biology and nanomedicine, roadmaps for scientific breakthroughs are emerging, fueled by super-re­so­lution imaging techniques, providing "live" insights into cellular processes. The horizons of Immuno-SERS Microscopy and Personalized Diagnostics Medicine are expanding, promising exciting prospects in the field of medical diagnostics.
publisher V.I.Vernadsky Institute of General and Inorganic Chemistry
publishDate 2023
url https://ucj.org.ua/index.php/journal/article/view/575
work_keys_str_mv AT ogenkovolodymyr achievementsinphysicalchemistryinthefieldofmicroscopyandvisualizationofnanosystems
first_indexed 2025-09-24T17:43:52Z
last_indexed 2025-09-24T17:43:52Z
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