An in-house made autosampler for capillary electrophoresis

Researchers are developing customized capillary electrophoresis (CE) instruments due to their affordability, and versatility. CE's simplicity, compared to chromatography-based methods, allows for low-cost designs using commercially available components. Injection methods, however, necessitate p...

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Published in	Analytica chimica acta Vol. 1350; p. 343835
Main Authors	Musile, Giacomo, Boillat, Marc-Aurèle, Hauser, Peter C.
Format	Journal Article
Language	English
Published	Netherlands Elsevier B.V 08.05.2025
Subjects	Autosampler Capillary electrophoresis Open-source hardware (OSH) Capillary electrophoresis Open-source hardware (OSH) Autosampler
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Abstract	Researchers are developing customized capillary electrophoresis (CE) instruments due to their affordability, and versatility. CE's simplicity, compared to chromatography-based methods, allows for low-cost designs using commercially available components. Injection methods, however, necessitate particular attention because of the high reproducibility required for quantitative determinations. Traditional manual hydrodynamic and electrokinetic injections involve one or more actions by the user thus increasing the number of potential sources of error. Automation efforts, such as using syringe pumps and pressure controllers, have improved injection precision, achieving results comparable to commercial systems. Despite progress, many methods still require manual sample loading and flushing, highlighting the need for further innovation in CE automation. A compact (26 x 9 × 9 cm) autosampler for a capillary electrophoresis (CE) system was designed, optimized and tested. The entire system was built in-house using the Open-Source Hardware (OSH) approach. It facilitates the fully automated analysis of a sequence of samples reducing the number of manual operations required by the user. The device allows hydrodynamic injection by pressure from six vials, as well as automatic rinsing of the capillary, and was coupled to a purpose made CE instrument with contactless conductivity detector (C4D). A precision better than 2.4 % was obtained for peak areas in the measurement of inorganic cations. The in-house made autosampler was used for analysing mineral water and the accuracies regarding the determination of the analytes were comparable to those observed for already published approaches. The significance of this research lies in running automated analysis sequences with an in-house-built injector that performs on par with commercial systems. The open-source hardware approach simplifies upgrades, supports the integration of new features, and allows the creation of complementary devices, making the system highly adaptable to evolving challenges and requirements. [Display omitted] •A compact (9x9x26 cm w. d. h.) autosampler for capillary electrophoresis is presented.•The sequence of actions for using the device is entirely automatized.•Direct hydrodynamic injection from the sample allows use of a few nanoliters of it.•The proposed assembly showed performances comparable with commercial devices.
AbstractList	Researchers are developing customized capillary electrophoresis (CE) instruments due to their affordability, and versatility. CE's simplicity, compared to chromatography-based methods, allows for low-cost designs using commercially available components. Injection methods, however, necessitate particular attention because of the high reproducibility required for quantitative determinations. Traditional manual hydrodynamic and electrokinetic injections involve one or more actions by the user thus increasing the number of potential sources of error. Automation efforts, such as using syringe pumps and pressure controllers, have improved injection precision, achieving results comparable to commercial systems. Despite progress, many methods still require manual sample loading and flushing, highlighting the need for further innovation in CE automation. A compact (26 x 9 × 9 cm) autosampler for a capillary electrophoresis (CE) system was designed, optimized and tested. The entire system was built in-house using the Open-Source Hardware (OSH) approach. It facilitates the fully automated analysis of a sequence of samples reducing the number of manual operations required by the user. The device allows hydrodynamic injection by pressure from six vials, as well as automatic rinsing of the capillary, and was coupled to a purpose made CE instrument with contactless conductivity detector (C4D). A precision better than 2.4 % was obtained for peak areas in the measurement of inorganic cations. The in-house made autosampler was used for analysing mineral water and the accuracies regarding the determination of the analytes were comparable to those observed for already published approaches. The significance of this research lies in running automated analysis sequences with an in-house-built injector that performs on par with commercial systems. The open-source hardware approach simplifies upgrades, supports the integration of new features, and allows the creation of complementary devices, making the system highly adaptable to evolving challenges and requirements. Researchers are developing customized capillary electrophoresis (CE) instruments due to their affordability, and versatility. CE's simplicity, compared to chromatography-based methods, allows for low-cost designs using commercially available components. Injection methods, however, necessitate particular attention because of the high reproducibility required for quantitative determinations. Traditional manual hydrodynamic and electrokinetic injections involve one or more actions by the user thus increasing the number of potential sources of error. Automation efforts, such as using syringe pumps and pressure controllers, have improved injection precision, achieving results comparable to commercial systems. Despite progress, many methods still require manual sample loading and flushing, highlighting the need for further innovation in CE automation. A compact (26 x 9 × 9 cm) autosampler for a capillary electrophoresis (CE) system was designed, optimized and tested. The entire system was built in-house using the Open-Source Hardware (OSH) approach. It facilitates the fully automated analysis of a sequence of samples reducing the number of manual operations required by the user. The device allows hydrodynamic injection by pressure from six vials, as well as automatic rinsing of the capillary, and was coupled to a purpose made CE instrument with contactless conductivity detector (C4D). A precision better than 2.4 % was obtained for peak areas in the measurement of inorganic cations. The in-house made autosampler was used for analysing mineral water and the accuracies regarding the determination of the analytes were comparable to those observed for already published approaches. The significance of this research lies in running automated analysis sequences with an in-house-built injector that performs on par with commercial systems. The open-source hardware approach simplifies upgrades, supports the integration of new features, and allows the creation of complementary devices, making the system highly adaptable to evolving challenges and requirements. [Display omitted] •A compact (9x9x26 cm w. d. h.) autosampler for capillary electrophoresis is presented.•The sequence of actions for using the device is entirely automatized.•Direct hydrodynamic injection from the sample allows use of a few nanoliters of it.•The proposed assembly showed performances comparable with commercial devices. Researchers are developing customized capillary electrophoresis (CE) instruments due to their affordability, and versatility. CE's simplicity, compared to chromatography-based methods, allows for low-cost designs using commercially available components. Injection methods, however, necessitate particular attention because of the high reproducibility required for quantitative determinations. Traditional manual hydrodynamic and electrokinetic injections involve one or more actions by the user thus increasing the number of potential sources of error. Automation efforts, such as using syringe pumps and pressure controllers, have improved injection precision, achieving results comparable to commercial systems. Despite progress, many methods still require manual sample loading and flushing, highlighting the need for further innovation in CE automation.BACKGROUNDResearchers are developing customized capillary electrophoresis (CE) instruments due to their affordability, and versatility. CE's simplicity, compared to chromatography-based methods, allows for low-cost designs using commercially available components. Injection methods, however, necessitate particular attention because of the high reproducibility required for quantitative determinations. Traditional manual hydrodynamic and electrokinetic injections involve one or more actions by the user thus increasing the number of potential sources of error. Automation efforts, such as using syringe pumps and pressure controllers, have improved injection precision, achieving results comparable to commercial systems. Despite progress, many methods still require manual sample loading and flushing, highlighting the need for further innovation in CE automation.A compact (26 x 9 × 9 cm) autosampler for a capillary electrophoresis (CE) system was designed, optimized and tested. The entire system was built in-house using the Open-Source Hardware (OSH) approach. It facilitates the fully automated analysis of a sequence of samples reducing the number of manual operations required by the user. The device allows hydrodynamic injection by pressure from six vials, as well as automatic rinsing of the capillary, and was coupled to a purpose made CE instrument with contactless conductivity detector (C4D). A precision better than 2.4 % was obtained for peak areas in the measurement of inorganic cations. The in-house made autosampler was used for analysing mineral water and the accuracies regarding the determination of the analytes were comparable to those observed for already published approaches.RESULTSA compact (26 x 9 × 9 cm) autosampler for a capillary electrophoresis (CE) system was designed, optimized and tested. The entire system was built in-house using the Open-Source Hardware (OSH) approach. It facilitates the fully automated analysis of a sequence of samples reducing the number of manual operations required by the user. The device allows hydrodynamic injection by pressure from six vials, as well as automatic rinsing of the capillary, and was coupled to a purpose made CE instrument with contactless conductivity detector (C4D). A precision better than 2.4 % was obtained for peak areas in the measurement of inorganic cations. The in-house made autosampler was used for analysing mineral water and the accuracies regarding the determination of the analytes were comparable to those observed for already published approaches.The significance of this research lies in running automated analysis sequences with an in-house-built injector that performs on par with commercial systems. The open-source hardware approach simplifies upgrades, supports the integration of new features, and allows the creation of complementary devices, making the system highly adaptable to evolving challenges and requirements.SIGNIFICANCEThe significance of this research lies in running automated analysis sequences with an in-house-built injector that performs on par with commercial systems. The open-source hardware approach simplifies upgrades, supports the integration of new features, and allows the creation of complementary devices, making the system highly adaptable to evolving challenges and requirements.
ArticleNumber	343835
Author	Hauser, Peter C. Musile, Giacomo Boillat, Marc-Aurèle
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Cites_doi	10.1002/elps.202000211 10.1080/10408340091164162 10.1021/acs.analchem.1c02119 10.1016/j.aca.2016.01.029 10.1016/j.aca.2016.06.015 10.1002/elps.201600366 10.1002/elps.202200260 10.1016/j.trac.2018.03.007 10.1016/j.aca.2023.341832 10.1016/j.chroma.2022.462895 10.1002/elps.201800304 10.1002/elps.201800250 10.1016/j.chroma.2023.464201 10.1016/j.chroma.2012.07.009 10.1016/j.aca.2018.10.071 10.1021/acs.analchem.7b00485 10.1039/b108884j 10.1021/acs.jchemed.6b00262 10.1016/j.chroma.2021.462533 10.1021/acs.analchem.5b04666
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Keywords	Capillary electrophoresis Open-source hardware (OSH) Autosampler
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StartPage	343835
SubjectTerms	Autosampler Capillary electrophoresis Open-source hardware (OSH)
Title	An in-house made autosampler for capillary electrophoresis
URI	https://dx.doi.org/10.1016/j.aca.2025.343835 https://www.ncbi.nlm.nih.gov/pubmed/40155165 https://www.proquest.com/docview/3183675894
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