Your search keyword '"Dobryden, I."' showing total 40 results

1. A micrometeorite from a stony asteroid identified in Luna 16 soil

Author

Demidova, S. I., Whitehouse, M. J., Merle, R., Nemchin, A. A., Kenny, G. G., Brandstätter, F., Ntaflos, Th., and Dobryden, I.

Published

2022

2. Local surface mechanical properties of PDMS-silica nanocomposite probed with Intermodulation AFM

Author

Huang, H., Dobryden, I., Thorén, P.-A., Ejenstam, L., Pan, J., Fielden, M.L., Haviland, D.B., and Claesson, P.M.

Published

2017

3. Corrosion of AD31 (AA6063) Alloy in Chloride-Containing Solutions

Author

Kharitonov, D. S., Dobryden’, I. B., Sefer, B., Zharskii, I. M., Claesson, P. M., and Kurilo, I. I.

Published

2018

4. The measurement of wear using AFM and wear interpretation using a contact mechanics coupled wear model

Author

Furustig, J., Dobryden, I., Almqvist, A., Almqvist, N., and Larsson, R.

Published

2016

5. Corrosion resistance of nickel coatings deposited from low-temperature nickel-plating electrolytes

Author

Antikhovich, I. V., Kharitonov, D. S., Chernik, A. A., and Dobryden’, I. B.

Published

2017

6. The influence of AFM and VSI techniques on the accurate calculation of tribological surface roughness parameters

Author

Spencer, A., Dobryden, I., Almqvist, N., Almqvist, A., and Larsson, R.

Published

2013

7. Force interactions between magnetite, silica, and bentonite studied with atomic force microscopy

Author

Dobryden, I., Potapova, E., Holmgren, A., Weber, H., Hedlund, J., and Almqvist, N.

Published

2015

8. A micrometeorite from a stony asteroid identified in Luna 16 soil

Author

Demidova, S. , I, Whitehouse, M. J., Merle, Renaud E., Nemchin, A. A., Kenny, G. G., Brandstatter, F., Ntaflos, Th, Dobryden, I, Demidova, S. , I, Whitehouse, M. J., Merle, Renaud E., Nemchin, A. A., Kenny, G. G., Brandstatter, F., Ntaflos, Th, and Dobryden, I

Abstract

Despite the intense cratering history of the Moon, very few traces of meteoritic material have been identified in the more than 380 kg of samples returned to Earth by the Apollo and Luna missions. Here we show that an similar to 200-mu m-sized fragment collected by the Luna 16 mission has extra-lunar origins and probably originates from an LL chondrite with similar properties to near-Earth stony asteroids. The fragment has not experienced temperatures higher than 400 degrees C since its protolith formed early in the history of the Solar System. It arrived on the Moon, either as a micrometeorite or as the result of the break-up of a bigger impact, no earlier than 3.4 Gyr ago and possibly around 1Gyr ago, an age that would be consistent with impact ages inferred from basaltic fragments in the Luna 16 sample and of a known dynamic upheaval in the Flora asteroid family, which is thought to be the source of L and LL chondrite meteorites. These results highlight the importance of extra-lunar fragments in constraining the impact history of the Earth-Moon system and suggest that material from LL chondrite asteroids may be an important component.

Published

2022

9. Synthetic Mucin Gels with Self-Healing Properties Augment Lubricity and Inhibit HIV-1 and HSV-2 Transmission

Author

Kretschmer, Manuel, Ceña-Diez, R., Butnarasu, C., Silveira, V., Dobryden, I., Visentin, S., Berglund, Per, Sönnerborg, A., Lieleg, O, Crouzier, Thomas, Yan, Hongji, Kretschmer, Manuel, Ceña-Diez, R., Butnarasu, C., Silveira, V., Dobryden, I., Visentin, S., Berglund, Per, Sönnerborg, A., Lieleg, O, Crouzier, Thomas, and Yan, Hongji

Abstract

Mucus is a self-healing gel that lubricates the moist epithelium and provides protection against viruses by binding to viruses smaller than the gel’s mesh size and removing them from the mucosal surface by active mucus turnover. As the primary nonaqueous components of mucus (≈0.2%–5%, wt/v), mucins are critical to this function because the dense arrangement of mucin glycans allows multivalence of binding. Following nature’s example, bovine submaxillary mucins (BSMs) are assembled into “mucus-like” gels (5%, wt/v) by dynamic covalent crosslinking reactions. The gels exhibit transient liquefaction under high shear strain and immediate self-healing behavior. This study shows that these material properties are essential to provide lubricity. The gels efficiently reduce human immunodeficiency virus type 1 (HIV-1) and genital herpes virus type 2 (HSV-2) infectivity for various types of cells. In contrast, simple mucin solutions, which lack the structural makeup, inhibit HIV-1 significantly less and do not inhibit HSV-2. Mechanistically, the prophylaxis of HIV-1 infection by BSM gels is found to be that the gels trap HIV-1 by binding to the envelope glycoprotein gp120 and suppress cytokine production during viral exposure. Therefore, the authors believe the gels are promising for further development as personal lubricants that can limit viral transmission., QC 20221216

Published

2022

10. Mechanical Properties of Organic Electronic Polymers on the Nanoscale

Author

Panchal, V, Dobryden, I, Hangen, UD, Simatos, D, Spalek, LJ, Jacobs, IE, Schweicher, G, Claesson, PM, Venkateshvaran, D, Venkateshvaran, D [0000-0002-7099-7323], and Apollo - University of Cambridge Repository

Subjects

organic electronics, young's modulus, organic field-effect transistors, nanomechanics, organic semiconducting polymers

Abstract

Funder: Belgian National Fund for Scientific Research; Id: http://dx.doi.org/10.13039/501100002661, Organic semiconducting polymers have attractive electronic, optical, and mechanical properties that make them materials of choice for large area flexible electronic devices. In these devices, the electronically active polymer components are micrometers in size, and sport negligible performance degradation upon bending the centimeter‐scale flexible substrate onto which they are integrated. A closer look at the mechanical properties of the polymers, on the grain‐scale and smaller, is not necessary in large area electronic applications. In emerging micromechanical and electromechanical applications where the organic polymer elements are flexed on length scales spanning their own micron‐sized active areas, it becomes important to characterize the uniformity of their mechanical properties on the nanoscale. In this work, the authors use two precision nanomechanical characterization techniques, namely, atomic force microscope based PeakForce quantitative nanomechanical mapping (PF‐QNM) and nanoindentation‐based dynamical mechanical analysis (nano‐DMA), to compare the modulus and the viscoelastic properties of organic polymers used routinely in organic electronics. They quantitatively demonstrate that the semiconducting near‐amorphous organic polymer indacenodithiophene‐co‐benzothiadiazole (C16‐IDTBT) has a higher carrier mobility, lower modulus, and greater nanoscale modulus areal uniformity compared to the semiconducting semicrystalline organic polymer poly[2,5‐bis(3‐tetradecylthiophen‐2‐yl)thieno[3,2‐b]thiophene] (C14‐PBTTT). Modulus homogeneity appears intrinsic to C16‐IDTBT but can be improved in C14‐PBTTT upon chemical doping.

Published

2022

11. Определение низкотемпературного коэффициента собственной диффузии в твердом p-H2 из опытов по ползучести

Author

Dobryden, I.

Subjects

Низькотемпературна фізика пластичності та міцності

Abstract

Измерены зависимости относительного удлинения ε под действием постоянно приложенного напряжения при T = 1,8 К от времени выдержки t поликристаллического параводорода (p-H₂, ~ 0,2 % o-H₂) высокой чистоты по посторонним примесям (99,9999 мол. %) с различным содержанием дейтерия. Выявлена область линейной зависимости между измеренными величинами скорости установившейся ползучести ε' образцов и приложенной нагрузки σ. На основании линейной зависимости ε'~ σ сделан вывод о том, что низкотемпературный крип исследованного p-H₂ имеет диффузионный характер вакансионного типа. Проведено вычисление низкотемпературного коэффициента собственной диффузии вакансий D в твердом p-H₂, который характеризует скорость низкотемпературного массопереноса. Рассмотрены случаи миграции вакансий в объеме кристалла, вдоль разделяющих отдельные кристаллиты границ, а также между существующими в кристаллах дислокациями. Установлено заметное снижение величин ε' и D с ростом концентрации изотопов в образцах при сохранении для исследованного p-H₂ линейной связи между ε' и σ. Виміряно залежності відносного подовження ε під дією постійно прикладеної напруги при T = 1,8 К від часу витримки t полікристалічного параводню (p-H₂, ~0,2% o-H₂) високої чистоти по стороннім домішкам (99,9999 мол. %) з різним вмістом дейтерію. Виявлено область лінійної залежності між вимірюваними величинами швидкості сталої повзучості ε' зразків та прикладеного навантаження σ. На підставі виконання лінійної залежності ε' ~ σ зроблено висновок про дифузійний характер вакансійного типу низькотемпературного кріпа дослідженого p-H₂. Проведено обчислення низькотемпературного коефіцієнта власної дифузії вакансій D в твердому p-H₂, що характеризує швидкість низькотемпературного масопереносу. Розглянуто випадки міграції вакансій в об'ємі кристалла, уздовж меж, що розділяють окремі кристаліти, а також між існуючими в кристалах дислокаціями. Встановлено помітне зниження величин ε' та D зі зростанням концентрації ізотопів в зразках при збереженні для дослідженого p-H₂ лінійного зв'язку між ε' та σ. The dependences of the relative elongation ε on the endurance time t of polycrystalline parahydrogen (p-H₂, ~ 0,2% o-H₂) of high purity (99.9999 mol.%) on extraneous impurities with different deuterium content under the applied stress at T = 1.8 K were measured. The region of linear dependence between the measured creep rates of samples and the applied load σ was revealed. On the basis of the fulfillment of the linear law ε' ~ σ, the diffusion character of the low-temperature creep of the vacancytype p-H₂ investigated was concluded. The low-temperature values of the intrinsic diffusion coefficient of vacancies D in solid p-H₂, characterizing the rates of low-temperature mass transfer, are calculated. The cases of migration of vacancies in the crystal volume, along the boundaries, separating individual crystallites, are considered, as well as between dislocations existing in crystals. A noticeable decrease in the values of ε' and D was observed with an increase of the isotope concentration in the samples, while maintaining a linear relationship between ε' and σ for the p-H₂ studied.

Published

2018

12. Corrosion Behavior in Acid and Alkaline Media of Nickel Coatings Deposited at Room Temperature

Author

Makarova, I. V., primary, Kharitonov, D. S., additional, Dobryden’, I. B., additional, and Chernik, A. A., additional

Published

2018

13. Determination of the low-temperature self-diffusion coefficient in solid p-H2 from creep experiments

Author

Alekseeva, L. A., primary and Dobryden, I., additional

Published

2018

14. Необычное формоизменение твердого параводорода с содержанием изотопов выше природного

Author

Dobryden, I.

Subjects

Низкотемпературная физика пластичности и прочности

Abstract

При температурах 1,8–4,2 К измерены зависимости относительного удлинения ε от приложенного напряжения σ к образцам параводорода (p-H₂, ~ 0,2% o-H₂) высокой чистоты (99,9999 мол.%) по посторонним примесям, которые отличались содержанием стабильного изотопа водорода — дейтерия. Образцы были испытаны в условиях одноосного растяжения методом ступенчатого нагружения. Содержание [D]/[H] числа [D] атомов дейтерия по отношению к числу [Н] атомов протия в p-H₂ составляло (0,0055 ± 0,0005) ат.% или достигало 0,07 ат.%. В случае обогащенного дейтерием p-H₂ выявлено исчезновение на кривых σ(ε) стадии легкого скольжения дислокаций и значительное понижение величины полного относительного удлинения образцов, а также существенное возрастание коэффициента упрочнения dσ/dε. При деформации образцов p-H₂ с содержанием дейтерия больше природного обнаружено их необычное формоизменение, которое обусловлено появлением ротационной составляющей низкотемпературного пластического массопереноса. При температурах 1,8–4,2 К виміряно залежності відносного подовження ε від прикладеної напруги σ до зразків параводню (p-H₂, ~ 0,2% o-H₂) високої (99,9999 мол.%) чистоти відносно сторонніх домішок, якi вiдрiзнялись вмістом стабільного ізотопу водню — дейтерію. Зразки було випробувано в умовах од- новісного розтягу методом ступеневого навантаження. Вміст [D]/[H] кількостi [D] атомів дейтерію відносно кількостi [H] атомів протiю в p-H₂ складав (0,0055 ± 0,0005) ат.% або досягав 0,07 ат.%. У разі збагаченого дейтерієм p-H₂ виявлено зникнення на кривих σ(ε) стадії легкого ковзання дислокацій та значне зниження величини повного відносного подовження зразків, а також істотне зростання коефіцієнта зміцнення dσ/dε. При деформації зразків p-H₂ зi вмiстом дейтерію більш природного виявлено їх незвичайне формозмінювання, що обумовлено появою ротаційної складової низькотемпературного пластичного масопереносу. The relative elongation ε of samples of high purity (99.9999 mol. % with respect to nonhydrogenic impurities) parahydrogen ( p-H ₂, ∼0.2% o-H₂) with different amounts of the stable hydrogen isotope deuterium is measured as a function of applied stress σ at temperatures of 1.8–4.2 K. The samples were subjected to uniaxial tension by stepwise loading. The ratio [D]/[H] of the number [D] of deuterium atoms to the number [H] of p-H₂ hydrogen atoms ranged from 0.0055 ± 0.0005 at. % up to 0.07 at. %. For deuterium enriched p-H₂, the easy slip dislocation stage vanished from the σ(ε) curves and there was a significant reduction in the total relative elongation of the samples, as well as a substantial increase in the hardening coefficient dσ/ dε. Deformation of samples of p-H₂ with deuterium contents higher than the natural amount produces an unusual change in their shape owing to the appearance of a rotational component of the low-temperature plastic mass transfer.

Published

2016

15. Unusual changes in the shape of solid parahydrogen with higher than natural isotope content

Author

Alekseeva, L. A., primary and Dobryden, I., additional

Published

2016

16. Determination of the low-temperature self-diffusion coefficient in solid p-H2 from creep experiments.

Author

Alekseeva, L. A. and Dobryden, I.

Subjects

*PARAHYDROGEN, *DEUTERIUM, *POLYCRYSTALS, *CREEP (Materials), *STRESS relaxation (Mechanics), *SELF-diffusion (Solid state physics), *DIFFUSION coefficients

Abstract

Dependencies of the relative elongation ε under the constantly applied stress at T = 1.8 K on the endurance time t of polycrystalline parahydrogen (p-H2, ∼ 0.2% of o-H2) of high purity (99.9999 mol.%), with varying deuterium content, were measured. The region of linear dependence between the measured creep rates ε ˙ of samples and the applied stress σ was revealed. The conclusion that the low-temperature creep of the studied p-H2 possesses a vacancy-type diffusion character was made on the basis of linear dependence ε ˙ ∼ σ. Determination of the low-temperature self-diffusion coefficient of vacancies D in solid p-H2, which characterizes the rate of low-temperature mass transfer, was performed. The cases of migration of vacancies in the crystal bulk, along boundaries separating individual crystallites, as well as between dislocations existing in crystals, are considered. A significant decrease in the ε ˙ and D values with an increase in the isotope concentration in the samples was observed, while maintaining the linear relationship between ε ˙ and σ for the studied p-H2. [ABSTRACT FROM AUTHOR]

Published

2018

17. Force interactions between magnetite, silica, and bentonite studied with atomic force microscopy

Author

Dobryden, I., primary, Potapova, E., additional, Holmgren, A., additional, Weber, H., additional, Hedlund, J., additional, and Almqvist, N., additional

Published

2014

18. 12-hydroxystearic acid-mediated in-situ surfactant generation: A novel approach for organohydrogel emulsions.

Author

Fameau AL, Cousin F, Dobryden I, Dutot C, Le Coeur C, Douliez JP, Prevost S, Binks BP, and Saint-Jalmes A

Abstract

Hypothesis: Organohydrogel emulsions display unique rheological properties and contain hydrophilic and lipophilic domains highly desirable for the loading of active compounds. They find utility in various applications from food to pharmaceuticals and cosmetic products. The current systems have limited applications due to complex expensive formulation and/or processing difficulties in scale-up. To solve these issues, a simple emulsification process coupled with unique compounds are required., Experiments: Here, we report an organohydrogel emulsion based only on a low concentration of 12-hydroxystearic acid acting as a gelling agent for both oil and water phases but also as a surfactant. The emulsification process is based on in-situ surfactant transfer. We characterize the emulsification process occurring at the nanoscale by using tensiometry experiments. The emulsion structure was determined by coupling Small Angle X-ray and neutron scattering, and confocal Raman microscopy., Findings: We demonstrate that the stability and unique rheological properties of these emulsions come from the presence of self-assembled crystalline structures of 12-hydroxystearic acid in both liquid phases. The emulsion properties can be tuned by varying the emulsion composition over a wide range. These gelled emulsions are prepared using a low energy method offering easy scale-up at an industrial level., Competing Interests: Declaration of competing interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2024 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2024

19. Effects of Processing-Induced Contamination on Organic Electronic Devices.

Author

Simatos D, Jacobs IE, Dobryden I, Nguyen M, Savva A, Venkateshvaran D, Nikolka M, Charmet J, Spalek LJ, Gicevičius M, Zhang Y, Schweicher G, Howe DJ, Ursel S, Armitage J, Dimov IB, Kraft U, Zhang W, Alsufyani M, McCulloch I, Owens RM, Claesson PM, Knowles TPJ, and Sirringhaus H

Abstract

Organic semiconductors are a family of pi-conjugated compounds used in many applications, such as displays, bioelectronics, and thermoelectrics. However, their susceptibility to processing-induced contamination is not well understood. Here, it is shown that many organic electronic devices reported so far may have been unintentionally contaminated, thus affecting their performance, water uptake, and thin film properties. Nuclear magnetic resonance spectroscopy is used to detect and quantify contaminants originating from the glovebox atmosphere and common laboratory consumables used during device fabrication. Importantly, this in-depth understanding of the sources of contamination allows the establishment of clean fabrication protocols, and the fabrication of organic field effect transistors (OFETs) with improved performance and stability. This study highlights the role of unintentional contaminants in organic electronic devices, and demonstrates that certain stringent processing conditions need to be met to avoid scientific misinterpretation, ensure device reproducibility, and facilitate performance stability. The experimental procedures and conditions used herein are typical of those used by many groups in the field of solution-processed organic semiconductors. Therefore, the insights gained into the effects of contamination are likely to be broadly applicable to studies, not just of OFETs, but also of other devices based on these materials., (© 2023 The Authors. Small Methods published by Wiley-VCH GmbH.)

Published

2023

20. Bio-Based Binder Development for Lithium-Ion Batteries.

Author

Dobryden I, Montanari C, Bhattacharjya D, Aydin J, and Ahniyaz A

Abstract

The development of rechargeable lithium-ion battery (LIB) technology has facilitated the shift toward electric vehicles and grid storage solutions. This technology is currently undergoing significant development to meet industrial applications for portable electronics and provide our society with "greener" electricity. The large increase in LIB production following the growing demand from the automotive sector has led to the establishment of gigafactories worldwide, thus increasing the substantial consumption of fossil-based and non-sustainable materials, such as polyvinylidene fluoride and/or styrene-butadiene rubber as binders in cathode and anode formulations. Furthermore, the use of raw resources, such as Li, Ni, and Mn in cathode active materials and graphite and nanosilicon in anodes, necessitates further efforts to enhance battery efficiency. To foster a global sustainable transition in LIB manufacturing and reduce reliance on non-sustainable materials, the implementation of bio-based binder solutions for electrodes in LIBs is crucial. Bio-based binders such as cellulose, lignin, alginate, gums, starch, and others can address environmental concerns and can enhance LIBs' performance. This review aims to provide an overview of the current progress in the development and application of bio-based binders for LIB electrode manufacturing, highlighting their significance toward sustainable development.

Published

2023

21. Label-free detection of polystyrene nanoparticles in Daphnia magna using Raman confocal mapping.

Author

Kaur J, Kelpsiene E, Gupta G, Dobryden I, Cedervall T, and Fadeel B

Abstract

Micro- and nanoplastic pollution has emerged as a global environmental problem. Moreover, plastic particles are of increasing concern for human health. However, the detection of so-called nanoplastics in relevant biological compartments remains a challenge. Here we show that Raman confocal spectroscopy-microscopy can be deployed for the non-invasive detection of amine-functionalized and carboxy-functionalized polystyrene (PS) nanoparticles (NPs) in Daphnia magna . The presence of PS NPs in the gastrointestinal (GI) tract of D. magna was confirmed by using transmission electron microscopy. Furthermore, we investigated the ability of NH 2 -PS NPs and COOH-PS NPs to disrupt the epithelial barrier of the GI tract using the human colon adenocarcinoma cell line HT-29. To this end, the cells were differentiated for 21 days and then exposed to PS NPs followed by cytotoxicity assessment and transepithelial electrical resistance measurements. A minor disruption of barrier integrity was noted for COOH-PS NPs, but not for the NH 2 -PS NPs, while no overt cytotoxicity was observed for both NPs. This study provides evidence of the feasibility of applying label-free approaches, i.e. , confocal Raman mapping, to study PS NPs in a biological system., Competing Interests: The authors declare that they have no competing financial interests., (This journal is © The Royal Society of Chemistry.)

Published

2023

22. Improving OFF-State Bias-Stress Stability in High-Mobility Conjugated Polymer Transistors with an Antisolvent Treatment.

Author

Nguyen M, Kraft U, Tan WL, Dobryden I, Broch K, Zhang W, Un HI, Simatos D, Venkateshavaran D, McCulloch I, Claesson PM, McNeill CR, and Sirringhaus H

Abstract

Conjugated polymer field-effect transistors are emerging as an enabling technology for flexible electronics due to their excellent mechanical properties combined with sufficiently high charge-carrier mobilities and compatibility with large-area, low-temperature processing. However, their electrical stability remains a concern. ON-state (accumulation mode) bias-stress instabilities in organic semiconductors have been widely studied, and multiple mitigation strategies have been suggested. In contrast, OFF-state (depletion mode) bias-stress instabilities remain poorly understood despite being crucial for many applications in which the transistors are held in their OFF-state for most of the time. Here, a simple method of using an antisolvent treatment is presented to achieve significant improvements in OFF-state bias-stress and environmental stability as well as general device performance for one of the best performing polymers, solution-processable indacenodithiophene-co-benzothiadiazole (IDT-BT). IDT-BT is weakly crystalline, and the notable improvements to an antisolvent-induced, increased degree of crystallinity, resulting in a lower probability of electron trapping and the removal of charge traps is attributed. The work highlights the importance of the microstructure in weakly crystalline polymer films and offers a simple processing strategy for achieving the reliability required for applications in flexible electronics., (© 2023 The Authors. Advanced Materials published by Wiley-VCH GmbH.)

Published

2023

23. Bio-Graphene Sensors for Monitoring Moisture Levels in Wood and Ambient Environment.

Author

Mulla MY, Isacsson P, Dobryden I, Beni V, Östmark E, Håkansson K, and Edberg J

Abstract

Wood is an inherently hygroscopic material which tends to absorb moisture from its surrounding. Moisture in wood is a determining factor for the quality of wood being employed in construction, since it causes weakening, deformation, rotting, and ultimately leading to failure of the structures resulting in costs to the economy, the environment, and to the safety of residents. Therefore, monitoring moisture in wood during the construction phase and after construction is vital for the future of smart and sustainable buildings. Employing bio-based materials for the construction of electronics is one way to mitigate the environmental impact of such electronics. Herein, a bio-graphene sensor for monitoring the moisture inside and around wooden surfaces is fabricated using laser-induced graphitization of a lignin-based ink precursor. The bio-graphene sensors are used to measure humidity in the range of 10% up to 90% at 25 °C. Using laser induced graphitization, conductor resistivity of 18.6 Ω sq -1 is obtained for spruce wood and 57.1 Ω sq -1 for pine wood. The sensitivity of sensors fabricated on spruce and pine wood is 2.6 and 0.74 MΩ per % RH. Surface morphology and degree of graphitization are investigated using scanning electron microscopy, Raman spectroscopy, and thermogravimetric analysis methods., Competing Interests: The authors declare no conflict of interest., (© 2023 The Authors. Global Challenges published by Wiley‐VCH GmbH.)

Published

2023

24. Synthetic Mucin Gels with Self-Healing Properties Augment Lubricity and Inhibit HIV-1 and HSV-2 Transmission.

Author

Kretschmer M, Ceña-Diez R, Butnarasu C, Silveira V, Dobryden I, Visentin S, Berglund P, Sönnerborg A, Lieleg O, Crouzier T, and Yan H

Subjects

Animals, Cattle, Humans, Herpesvirus 2, Human metabolism, Mucins metabolism, Gels, Mucus metabolism, HIV-1 metabolism

Abstract

Mucus is a self-healing gel that lubricates the moist epithelium and provides protection against viruses by binding to viruses smaller than the gel's mesh size and removing them from the mucosal surface by active mucus turnover. As the primary nonaqueous components of mucus (≈0.2%-5%, wt/v), mucins are critical to this function because the dense arrangement of mucin glycans allows multivalence of binding. Following nature's example, bovine submaxillary mucins (BSMs) are assembled into "mucus-like" gels (5%, wt/v) by dynamic covalent crosslinking reactions. The gels exhibit transient liquefaction under high shear strain and immediate self-healing behavior. This study shows that these material properties are essential to provide lubricity. The gels efficiently reduce human immunodeficiency virus type 1 (HIV-1) and genital herpes virus type 2 (HSV-2) infectivity for various types of cells. In contrast, simple mucin solutions, which lack the structural makeup, inhibit HIV-1 significantly less and do not inhibit HSV-2. Mechanistically, the prophylaxis of HIV-1 infection by BSM gels is found to be that the gels trap HIV-1 by binding to the envelope glycoprotein gp120 and suppress cytokine production during viral exposure. Therefore, the authors believe the gels are promising for further development as personal lubricants that can limit viral transmission., (© 2022 The Authors. Advanced Science published by Wiley-VCH GmbH.)

Published

2022

25. Dynamic self-stabilization in the electronic and nanomechanical properties of an organic polymer semiconductor.

Author

Dobryden I, Korolkov VV, Lemaur V, Waldrip M, Un HI, Simatos D, Spalek LJ, Jurchescu OD, Olivier Y, Claesson PM, and Venkateshvaran D

Abstract

The field of organic electronics has profited from the discovery of new conjugated semiconducting polymers that have molecular backbones which exhibit resilience to conformational fluctuations, accompanied by charge carrier mobilities that routinely cross the 1 cm 2 /Vs benchmark. One such polymer is indacenodithiophene-co-benzothiadiazole. Previously understood to be lacking in microstructural order, we show here direct evidence of nanosized domains of high order in its thin films. We also demonstrate that its device-based high-performance electrical and thermoelectric properties are not intrinsic but undergo rapid stabilization following a burst of ambient air exposure. The polymer's nanomechanical properties equilibrate on longer timescales owing to an orthogonal mechanism; the gradual sweating-out of residual low molecular weight solvent molecules from its surface. We snapshot the quasistatic temporal evolution of the electrical, thermoelectric and nanomechanical properties of this prototypical organic semiconductor and investigate the subtleties which play on competing timescales. Our study documents the untold and often overlooked story of a polymer device's dynamic evolution toward stability., (© 2022. The Author(s).)

Published

2022

26. Nanoscale Mechanical Properties of Core-Shell-like Poly-NIPAm Microgel Particles: Effect of Temperature and Cross-Linking Density.

Author

Li G, Varga I, Kardos A, Dobryden I, and Claesson PM

Subjects

Acrylic Resins, Gels, Temperature, Microgels

Abstract

Poly-NIPAm microgel particles with two different cross-linking densities were prepared with the classical batch polymerization process. These particles were adsorbed onto modified silica surfaces, and their nanomechanical properties were measured by means of atomic force microscopy. It was found that these particles have a hard core-soft shell structure both below and above the volume transition temperature. The core-shell-like structure appears due to a higher reaction rate of the cross-linker compared to that of the monomer, leading to depletion of cross-linker in the shell region. The microgel beads with lower average cross-linking density were found to be less stiff below the volume transition temperature than the microgel with higher cross-linking density. Increasing the temperature further to just above the volume transition temperature led to lower stiffness of the more highly cross-linked microgel compared to its less cross-linked counterpart. This effect is explained with the more gradual deswelling with temperature for the more cross-linked microgel particles. This phenomenon was confirmed by dynamic light scattering measurements in the bulk phase, which showed that the larger cross-linking density microgel showed a more gradual collapse in aqueous solution as the temperature was increased.

Published

2021

27. Nanoscale Wear and Mechanical Properties of Calcite: Effects of Stearic Acid Modification and Water Vapor.

Author

Wojas NA, Dobryden I, Wallqvist V, Swerin A, Järn M, Schoelkopf J, Gane PAC, and Claesson PM

Abstract

Understanding the wear of mineral fillers is crucial for controlling industrial processes, and in the present work, we examine the wear resistance and nanomechanical properties of bare calcite and stearic acid-modified calcite surfaces under dry and humid conditions at the nanoscale. Measurements under different loads allow us to probe the situation in the absence and presence of abrasive wear. The sliding motion is in general characterized by irregular stick-slip events that at higher loads lead to abrasion of the brittle calcite surface. Bare calcite is hydrophilic, and under humid conditions, a thin water layer is present on the surface. This water layer does not affect the friction force. However, it slightly decreases the wear depth and strongly influences the distribution of wear particles. In contrast, stearic acid-modified surfaces are hydrophobic. Nevertheless, humidity affects the wear characteristics by decreasing the binding strength of stearic acid at higher humidity. A complete monolayer coverage of calcite by stearic acid results in a significant reduction in wear but only a moderate reduction in friction forces at low humidity and no reduction at 75% relative humidity (RH). Thus, our data suggest that the wear reduction does not result from a lowering of the friction force but rather from an increased ductility of the surface region as offered by the stearic acid layer. An incomplete monolayer of stearic acid on the calcite surface provides no reduction in wear regardless of the RH investigated. Clearly, the wear properties of modified calcite surfaces depend crucially on the packing density of the surface modifier and also on the air humidity.

Published

2021

28. Nanoscale characterization of an all-oxide core-shell nanorod heterojunction using intermodulation atomic force microscopy (AFM) methods.

Author

Dobryden I, Borgani R, Rigoni F, Ghamgosar P, Concina I, Almqvist N, and Vomiero A

Abstract

The electrical properties of an all-oxide core-shell ZnO-Co 3 O 4 nanorod heterojunction were studied in the dark and under UV-vis illumination. The contact potential difference and current distribution maps were obtained utilizing new methods in dynamic multifrequency atomic force microscopy (AFM) such as electrostatic and conductive intermodulation AFM. Light irradiation modified the electrical properties of the nanorod heterojunction. The new techniques are able to follow the instantaneous local variation of the photocurrent, giving a two-dimensional (2D) map of the current-voltage curves and correlating the electrical and morphological features of the heterostructured core-shell nanorods., Competing Interests: RB is a part owner of Intermodulation Products AB, which manufactures and sells the multifrequency lock-in amplifier used in this study., (This journal is © The Royal Society of Chemistry.)

Published

2021

29. Temperature-Dependent Nanomechanical Properties of Adsorbed Poly-NIPAm Microgel Particles Immersed in Water.

Author

Li G, Varga I, Kardos A, Dobryden I, and Claesson PM

Abstract

The temperature dependence of nanomechanical properties of adsorbed poly-NIPAm microgel particles prepared by a semibatch polymerization process was investigated in an aqueous environment via indentation-based atomic force microscopy (AFM) methods. Poly-NIPAm microgel particles prepared by the classical batch process were also characterized for comparison. The local mechanical properties were measured between 26 and 35 °C, i.e., in the temperature range of the volume transition. Two different AFM tips with different shapes and end radii were utilized. The nanomechanical properties measured by the two kinds of tips showed a similar temperature dependence of the nanomechanical properties, but the actual values were found to depend on the size of the tip. The results suggest that the semibatch synthesis process results in the formation of more homogeneous microgel particles than the classical batch method. The methodological approach reported in this work is generally applicable to soft surface characterization in situ.

Published

2021

30. Friction at nanopillared polymer surfaces beyond Amontons' laws: Stick-slip amplitude coefficient (SSAC) and multiparametric nanotribological properties.

Author

Ishak MI, Dobryden I, Martin Claesson P, Briscoe WH, and Su B

Abstract

Frictional and nanomechanical properties of nanostructured polymer surfaces are important to their technological and biomedical applications. In this work, poly(ethylene terephthalate) (PET) surfaces with a periodic distribution of well-defined nanopillars were fabricated through an anodization/embossing process. The apparent surface energy of the nanopillared surfaces was evaluated using the Fowkes acid-base approach, and the surface morphology was characterized using scanning electron microscope (SEM) and atomic force microscope (AFM). The normal and lateral forces between a silica microparticle and these surfaces were quantified using colloidal probe atomic force microscopy (CP-AFM). The friction-load relationship followed Amonton's first law, and the friction coefficient appeared to scale linearly with the nanopillar height. Furthermore, all the nanopillared surfaces showed pronounced frictional instabilities compared to the smooth sliding friction loop on the flat control. Performing the stick-slip amplitude coefficient (SSAC) analysis, we found a correlation between the frictional instabilities and the nanopillars density, pull-off force and work of adhesion. We have summarised the dependence of the nanotribological properties on such nanopillared surfaces on five relevant parameters, i.e. pull-off force f p , Amontons' friction coefficient μ, RMS roughness R q , stick-slip amplitude friction coefficient SSAC, and work of adhesion between the substrate and water W adh in a radar chart. Whilst demonstrating the complexity of the frictional behaviour of nanopillared polymer surfaces, our results show that analyses of multiparametric nanotribological properties of nanostructured surfaces should go beyond classic Amontons' laws, with the SSAC more representative of the frictional properties compared to the friction coefficient., Competing Interests: Declaration of Competing Interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2020 Elsevier Inc. All rights reserved.)

Published

2021

31. Glyco-Modification of Mucin Hydrogels to Investigate Their Immune Activity.

Author

Yan H, Hjorth M, Winkeljann B, Dobryden I, Lieleg O, and Crouzier T

Subjects

Animals, Cattle, Cytokines genetics, Endocytosis drug effects, Gene Expression drug effects, Humans, Hydrogels chemistry, Immunologic Factors chemistry, Macrophages metabolism, Mucins chemistry, N-Acetylneuraminic Acid chemistry, Neuraminidase chemistry, Phagocytosis drug effects, Polysaccharides chemistry, THP-1 Cells, Hydrogels pharmacology, Immunologic Factors pharmacology, Macrophage Activation drug effects, Mucins pharmacology

Abstract

Mucins are multifunctional glycosylated proteins that are increasingly investigated as building blocks of novel biomaterials. An attractive feature is their ability to modulate the immune response, in part by engaging with sialic acid binding receptors on immune cells. Once assembled into hydrogels, bovine submaxillary mucins (Muc gels) were shown to modulate the recruitment and activation of immune cells and avoid fibrous encapsulation in vivo . However, nothing is known about the early immune response to Muc gels. This study characterizes the response of macrophages, important orchestrators of the material-mediated immune response, over the first 7 days in contact with Muc gels. The role of mucin-bound sialic acid sugar residues was investigated by first enzymatically cleaving the sugar and then assembling the mucin variants into covalently cross-linked hydrogels with rheological and surface nanomechanical properties similar to nonmodified Muc gels. Results with THP-1 and human primary peripheral blood monocytes derived macrophages showed that Muc gels transiently activate the expression of both pro-inflammatory and anti-inflammatory cytokines and cell surface markers, for most makers with a maximum on the first day and loss of the effect after 7 days. The activation was sialic acid-dependent for a majority of the markers followed. The pattern of gene expression, protein expression, and functional measurements did not strictly correspond to M1 or M2 macrophage phenotypes. This study highlights the complex early events in macrophage activation in contact with mucin materials and the importance of sialic acid residues in such a response. The enzymatic glyco-modulation of Muc gels appears as a useful tool to help understand the biological functions of specific glycans on mucins which can further inform on their use in various biomedical applications.

Published

2020

32. Bioinspired Adhesion Polymers: Wear Resistance of Adsorption Layers.

Author

Dobryden I, Steponavičiu Tė M, Klimkevičius V, Makuška R, Dėdinaitė A, Liu X, Corkery RW, and Claesson PM

Abstract

Mussel adhesive polymers owe their ability to strongly bind to a large variety of surfaces under water to their high content of 3,4-dihydroxy-l-phenylalanine (DOPA) groups and high positive charge. In this work, we use a set of statistical copolymers that contain medium-length poly(ethylene oxide) side chains that are anchored to the surface in three different ways: by means of (i) electrostatic forces, (ii) catechol groups (as in DOPA), and (iii) the combination of electrostatic forces and catechol groups. A nanotribological scanning probe method was utilized to evaluate the wear resistance of the formed layers as a function of normal load. It was found that the combined measurement of surface topography and stiffness provided an accurate assessment of the wear resistance of such thin layers. In particular, surface stiffness maps allowed us to identify the initiation of wear before a clear topographical wear scar was developed. Our data demonstrate that the molecular and abrasive wear resistance on silica surfaces depends on the anchoring mode and follows the order catechol groups combined with electrostatic forces > catechol groups alone > electrostatic forces alone. The devised methodology should be generally applicable for evaluating wear resistance or "robustness" of thin adsorbed layers on a variety of surfaces.

Published

2019

33. Load-dependent surface nanomechanical properties of poly-HEMA hydrogels in aqueous medium.

Author

Li G, Dobryden I, Salazar-Sandoval EJ, Johansson M, and Claesson PM

Abstract

The mechanical properties of hydrogels are of importance in many applications, including scaffolds and drug delivery vehicles where the release of drugs is controlled by water transport. While the macroscopic mechanical properties of hydrogels have been reported frequently, there are less studies devoted to the equally important nanomechanical response to local load and shear. Scanning probe methods offer the possibility to gain insight on surface nanomechanical properties with high spatial resolution, and thereby provide fundamental insights on local material property variations. In this work, we investigate the local response to load and shear of poly(2-hydroxyethyl methacrylate) hydrogels with two different cross-linking densities submerged in aqueous solution. The response of the hydrogels to purely normal loads, as well as the combined action of load and shear, was found to be complex due to viscoelastic effects. Our results show that the surface stiffness of the hydrogel samples increased with increasing load, while the tip-hydrogel adhesion was strongly affected by the load only when the cross-linking density was low. The combined action of load and shear results in the formation of a temporary sub-micrometer hill in front of the laterally moving tip. As the tip pushes against such hills, a pronounced stick-slip effect is observed for the hydrogel with low cross-linking density. No plastic deformation or permanent wear scar was found under our experimental conditions.

Published

2019

34. Thermoresponsive Pentablock Copolymer on Silica: Temperature Effects on Adsorption, Surface Forces, and Friction.

Author

Dobryden I, Cortes Ruiz M, Zhang X, Dėdinaitė A, Wieland DCF, Winnik FM, and Claesson PM

Abstract

The adsorption of hydrophilic or amphiphilic multiblock copolymers provides a powerful means to produce well-defined "smart" surfaces, especially if one or several blocks are sensitive to external stimuli. We focus here on an A-B-A-B-A copolymer, where A is a cationic poly((3-acrylamido-propyl)-trimethylammonium chloride) (PAMPTMA) block containing 15 (end blocks) or 30 (middle block) repeat units and B is a neutral thermosensitive water-soluble poly(2-isopropyl-2-oxazoline) (PIPOZ) block with 50 repeat units. X-ray reflectivity and quartz crystal microbalance with dissipation monitoring were employed to study the adsorption of PAMPTMA 15 -PIPOZ 50 -PAMPTMA 30 -PIPOZ 50 -PAMPTMA 15 on silica surfaces. The latter technique was employed at different temperatures up to 50 °C. Surface forces and friction between the two silica surfaces across aqueous pentablock copolymer solutions at different temperatures were determined with the atomic force microscopy colloidal probe force and friction measurements. The cationic pentablock copolymer was found to have a high affinity to the negatively charged silica surface, leading to a thin (2 nm) and rigid adsorbed layer. A steric force was encountered at a separation of around 3 nm from hard wall contact. A capillary condensation of a polymer-rich phase was observed at the cloud point of the solution. The friction forces were evaluated using Amontons' rule modified with an adhesion term.

Published

2019

35. Synergistic effects of metal-induced aggregation of human serum albumin.

Author

Hedberg YS, Dobryden I, Chaudhary H, Wei Z, Claesson PM, and Lendel C

Subjects

Aluminum Silicates chemistry, Binding Sites, Cations, Divalent, Humans, Hydrogen-Ion Concentration, Kinetics, Protein Binding, Protein Conformation, alpha-Helical, Solutions, Chromium chemistry, Cobalt chemistry, Nanoparticles chemistry, Nickel chemistry, Protein Aggregates, Serum Albumin, Human chemistry

Abstract

Exposure to cobalt (Co), chromium (Cr), and nickel (Ni) occurs often via skin contact and from different dental and orthopedic implants. The metal ions bind to proteins, which may induce structural changes and aggregation, with different medical consequences. We investigated human serum albumin (HSA) aggregation in the presence of Co II , Cr III , and/or Ni II ions and/or their nanoparticle precipitates by using scattering, spectroscopic, and imaging techniques, at simulated physiological conditions (phosphate buffered saline - PBS, pH 7.3) using metal salts that did not affect the pH, and at HSA:metal molar ratios of up to 1:8. Co ions formed some solid nanoparticles in PBS at the investigated conditions, as determined by nanoparticle tracking analysis, but the Cr III anions and Ni II ions remained fully soluble. It was found that all metal ions induced HSA aggregation, and this effect was significantly enhanced when a mixture of all three metal ions was present instead of any single type of ion. Thus, the metal ions induce aggregation synergistically. HSA aggregates formed linear structures on a mica surface in the presence of Cr III ions. A clear tendency of aggregation and linearly aligned aggregates was seen in the presence of all three metal ions. Spectroscopic investigations indicated that the majority of the HSA molecules maintained their alpha helical secondary structure and conformation. This study highlights the importance of synergistic effects of metal ions and/or their precipitates on protein aggregation, which are highly relevant for implant materials and common exposures to metals., (Copyright © 2018 The Author(s). Published by Elsevier B.V. All rights reserved.)

Published

2019

36. Reversible Condensation of Mucins into Nanoparticles.

Author

Yan H, Chircov C, Zhong X, Winkeljann B, Dobryden I, Nilsson HE, Lieleg O, Claesson PM, Hedberg Y, and Crouzier T

Subjects

Animals, Calcium chemistry, Glycerol chemistry, Mucins isolation & purification, Particle Size, Polylysine chemistry, Protein Conformation drug effects, Solvents chemistry, Swine, Viscosity, Mucins chemistry, Nanoparticles chemistry

Abstract

Mucins are high molar mass glycoproteins that assume an extended conformation and can assemble into mucus hydrogels that protect our mucosal epithelium. In nature, the challenging task of generating a mucus layer, several hundreds of micrometers in thickness, from micrometer-sized cells is elegantly solved by the condensation of mucins inside vesicles and their on-demand release from the cells where they suddenly expand to form the extracellular mucus hydrogel. We aimed to recreate and control the process of compaction for mucins, the first step toward a better understanding of the process and creating biomimetic in vivo delivery strategies of macromolecules. We found that by adding glycerol to the aqueous solvent, we could induce drastic condensation of purified mucin molecules, reducing their size by an order of magnitude down to tens of nanometers in diameter. The condensation effect of glycerol was fully reversible and could be further enhanced and partially stabilized by cationic cross-linkers such as calcium and polylysine. The change of structure of mucins from extended molecules to nano-sized particles in the presence of glycerol translated into macroscopic rheological changes, as illustrated by a dampened shear-thinning effect with increasing glycerol concentration. This work provides new insight into mucin condensation, which could lead to new delivery strategies mimicking cell release of macromolecules condensed in vesicles such as mucins and heparin.

Published

2018

37. From force curves to surface nanomechanical properties.

Author

Claesson PM, Dobryden I, Li G, He Y, Huang H, Thorén PA, and Haviland DB

Abstract

Surface science, which spans the fields of chemistry, physics, biology and materials science, requires information to be obtained on the local properties and property variations across a surface. This has resulted in the development of different scanning probe methods that allow the measurement of local chemical composition and local electrical and mechanical properties. These techniques have led to rapid advancement in fundamental science with applications in areas such as composite materials, corrosion protection and wear resistance. In this perspective article, we focussed on the branch of scanning probe methods that allows the determination of surface nanomechanical properties. We discussed some different AFM-based modes that were used for these measurements and provided illustrative examples of the type of information that could be obtained. We also discussed some of the difficulties encountered during such studies.

Published

2017

38. Temperature-dependent surface nanomechanical properties of a thermoplastic nanocomposite.

Author

Huang H, Dobryden I, Ihrner N, Johansson M, Ma H, Pan J, and Claesson PM

Abstract

In polymer nanocomposites, particle-polymer interactions influence the properties of the matrix polymer next to the particle surface, providing different physicochemical properties than in the bulk matrix. This region is often referred to as the interphase, but detailed characterization of its properties remains a challenge. Here we employ two atomic force microscopy (AFM) force methods, differing by a factor of about 15 in probing rate, to directly measure the surface nanomechanical properties of the transition region between filler particle and matrix over a controlled temperature range. The nanocomposite consists of poly(ethyl methacrylate) (PEMA) and poly(isobutyl methacrylate) (PiBMA) with a high concentration of hydrophobized silica nanoparticles. Both AFM methods demonstrate that the interphase region around a 40-nm-sized particle located on the surface of the nanocomposite could extend to 55-70nm, and the interphase exhibits a gradient distribution in surface nanomechanical properties. However, the slower probing rate provides somewhat lower numerical values for the surface stiffness. The analysis of the local glass transition temperature (T g ) of the interphase and the polymer matrix provides evidence for reduced stiffness of the polymer matrix at high particle concentration, a feature that we attribute to selective adsorption. These findings provide new insight into understanding the microstructure and mechanical properties of nanocomposites, which is of importance for designing nanomaterials., (Copyright © 2017 Elsevier Inc. All rights reserved.)

Published

2017

39. Adsorption Behavior of Cellulose and Its Derivatives toward Ag(I) in Aqueous Medium: An AFM, Spectroscopic, and DFT Study.

Author

Zhu C, Dobryden I, Rydén J, Öberg S, Holmgren A, and Mathew AP

Abstract

The aim of this study was to develop a fundamental understanding of the adsorption behavior of metal ions on cellulose surfaces using experimental techniques supported by computational modeling, taking Ag(I) as an example. Force interactions among three types of cellulose microspheres (native cellulose and its derivatives with sulfate and phosphate groups) and the silica surface in AgNO3 solution were studied with atomic force microscopy (AFM) using the colloidal probe technique. The adhesion force between phosphate cellulose microspheres (PCM) and the silica surface in the aqueous AgNO3 medium increased significantly with increasing pH while the adhesion force slightly decreased for sulfate cellulose microspheres (SCM), and no clear adhesion force was observed for native cellulose microspheres (CM). The stronger adhesion enhancement for the PCM system is mainly attributed to the electrostatic attraction between Ag(I) and the negative silica surface. The observed force trends were in good agreement with the measured zeta potentials. The scanning electron microscopy (SEM), X-ray photoelectron spectroscopy (XPS), and attenuated total reflectance-Fourier transform infrared spectroscopy (ATR-FTIR) analyses confirmed the presence of silver on the surface of cellulose microspheres after adsorption. This study showed that PCM with a high content of phosphate groups exhibited a larger amount of adsorbed Ag(I) than CM and SCM and possible clustering of Ag(I) to nanoparticles. The presence of the phosphate group and a wavenumber shift of the P-OH vibration caused by the adsorption of silver ions on the phosphate groups were further confirmed with computational studies using density functional theory (DFT), which gives support to the above findings regarding the adsorption and clustering of Ag(I) on the cellulose surface decorated with phosphate groups as well as IR spectra.

Published

2015

40. Microstructure of bentonite in iron ore green pellets.

Author

Bhuiyan IU, Mouzon J, Schröppel B, Kaech A, Dobryden I, Forsmo SP, and Hedlund J

Abstract

Sodium-activated calcium bentonite is used as a binder in iron ore pellets and is known to increase strength of both wet and dry iron ore green pellets. In this article, the microstructure of bentonite in magnetite pellets is revealed for the first time using scanning electron microscopy. The microstructure of bentonite in wet and dry iron ore pellets, as well as in distilled water, was imaged by various imaging techniques (e.g., imaging at low voltage with monochromatic and decelerated beam or low loss backscattered electrons) and cryogenic methods (i.e., high pressure freezing and plunge freezing in liquid ethane). In wet iron ore green pellets, clay tactoids (stacks of parallel primary clay platelets) were very well dispersed and formed a voluminous network occupying the space available between mineral particles. When the pellet was dried, bentonite was drawn to the contact points between the particles and formed solid bridges, which impart strength to the solid compact.

Published

2014