Droplet microfluidic method for estimating the dynamic interfacial tension of ion-crosslinked sodium alginate microspheres; Langmuir; Vol. 40, iss. 30
| Parent link: | Langmuir.— .— Washington: ACS Publications Vol. 40, iss. 30.— 2024.— P. 15906–15917 |
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| Institution som forfatter: | |
| Andre forfattere: | , , , , |
| Summary: | Title screen The research focuses on optimizing the production of hydrogel microspheres using droplet microfluidics for pharmaceutical and bioengineering applications. A semiempirical method has been developed to predict the dynamic interfacial tension at the interface of ion-cross-linked sodium alginate microsphere-sunflower oil modified with glacial acetic acid and Tween 80 surfactant. These microspheres are produced in a small-scale coaxial device that is manufactured using affordable DLP/LCD 3D printing technology with a transparent photopolymer. The method was tested to design the minireactor in the device, which allows for the production of fully cross-linked microspheres that are ready for use at the output of the reactor without additional cross-linking steps in the microsphere collector. The mathematical expression for estimating the interfacial tension at the moment of formation of a hydrogel microsphere includes the Reynolds number for a two-phase liquid, the Ohnesorge number, and the surface tension at the liquid–air interface for continuous medium flow (modified oil). The reliability of the prediction is confirmed for continuous medium and dispersed phase flow rates of 0.8–3.2 and 0.01–0.08 mL/min, respectively. The evolution of the interfacial tension from the moment the microspheres formed and the estimated ultimate interfacial tension in a cross-linked hydrogel–modified oil system contributed to the reliable determination of the linear size of a minireactor. The ultimate interfacial tension of 76.5 ± 0.3 mN/m was determined using the Young–Laplace equation, which is based on measuring the surface free energy of the hydrogel as soft matter using the Owens-Wendt method. Additionally, the equilibrium static contact angle of the fully cross-linked hydrogel surface wetted with oil is measured using the sessile drop method. From a practical perspective, a method for optimizing and streamlining the high-tech manufacturing of cross-linked polymer microspheres and mini- and microchannel devices for use in bioengineering and pharmaceutical applications is suggested Текстовый файл AM_Agreement |
| Sprog: | engelsk |
| Udgivet: |
2024
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| Fag: | |
| Online adgang: | https://doi.org/10.1021/acs.langmuir.4c01940 |
| Format: | MixedMaterials Electronisk Book Chapter |
| KOHA link: | https://koha.lib.tpu.ru/cgi-bin/koha/opac-detail.pl?biblionumber=675934 |
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| 200 | 1 | |a Droplet microfluidic method for estimating the dynamic interfacial tension of ion-crosslinked sodium alginate microspheres |f Alexander Ashikhmin, Maxim Piskunov, Dmitry Kochkin [et al.] | |
| 203 | |a Текст |c электронный |b визуальный | ||
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| 300 | |a Title screen | ||
| 320 | |a References: 31 tit | ||
| 330 | |a The research focuses on optimizing the production of hydrogel microspheres using droplet microfluidics for pharmaceutical and bioengineering applications. A semiempirical method has been developed to predict the dynamic interfacial tension at the interface of ion-cross-linked sodium alginate microsphere-sunflower oil modified with glacial acetic acid and Tween 80 surfactant. These microspheres are produced in a small-scale coaxial device that is manufactured using affordable DLP/LCD 3D printing technology with a transparent photopolymer. The method was tested to design the minireactor in the device, which allows for the production of fully cross-linked microspheres that are ready for use at the output of the reactor without additional cross-linking steps in the microsphere collector. The mathematical expression for estimating the interfacial tension at the moment of formation of a hydrogel microsphere includes the Reynolds number for a two-phase liquid, the Ohnesorge number, and the surface tension at the liquid–air interface for continuous medium flow (modified oil). The reliability of the prediction is confirmed for continuous medium and dispersed phase flow rates of 0.8–3.2 and 0.01–0.08 mL/min, respectively. The evolution of the interfacial tension from the moment the microspheres formed and the estimated ultimate interfacial tension in a cross-linked hydrogel–modified oil system contributed to the reliable determination of the linear size of a minireactor. The ultimate interfacial tension of 76.5 ± 0.3 mN/m was determined using the Young–Laplace equation, which is based on measuring the surface free energy of the hydrogel as soft matter using the Owens-Wendt method. Additionally, the equilibrium static contact angle of the fully cross-linked hydrogel surface wetted with oil is measured using the sessile drop method. From a practical perspective, a method for optimizing and streamlining the high-tech manufacturing of cross-linked polymer microspheres and mini- and microchannel devices for use in bioengineering and pharmaceutical applications is suggested | ||
| 336 | |a Текстовый файл | ||
| 371 | 0 | |a AM_Agreement | |
| 461 | 1 | |t Langmuir |c Washington |n ACS Publications | |
| 463 | 1 | |t Vol. 40, iss. 30 |v P. 15906–15917 |d 2024 | |
| 610 | 1 | |a электронный ресурс | |
| 610 | 1 | |a труды учёных ТПУ | |
| 610 | 1 | |a hydrogels | |
| 610 | 1 | |a liquids | |
| 610 | 1 | |a microspheres | |
| 610 | 1 | |a nucleic acid structure | |
| 610 | 1 | |a surface tension | |
| 701 | 1 | |a Piskunov |b M. V. |c specialist in the field of thermal engineering |c engineer of Tomsk Polytechnic University |f 1991- |g Maksim Vladimirovich |9 17691 | |
| 701 | 1 | |a Ashikhmin |b A. E. |c Specialist in the field of thermal power engineering and heat engineering |c Research Engineer of Tomsk Polytechnic University |f 1998- |g Alexander Evgenjevich |9 23065 | |
| 701 | 1 | |a Kochkin |b D. Yu. |g Dmitry Yurjevich | |
| 701 | 1 | |a Ronshin |b F. V. |g Fedor Valerjevich | |
| 701 | 0 | |a Chen Longtsyuan | |
| 712 | 0 | 2 | |a National Research Tomsk Polytechnic University |c (2009- ) |9 27197 |4 570 |
| 801 | 0 | |a RU |b 63413507 |c 20241028 |g RCR | |
| 856 | 4 | |u https://doi.org/10.1021/acs.langmuir.4c01940 |z https://doi.org/10.1021/acs.langmuir.4c01940 | |
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