Your search keyword '"Valentina Preziosi"' showing total 31 results

1. Organic Electrochemical Transistor Immuno-Sensors for Spike Protein Early Detection

Author

Mario Barra, Giovanna Tomaiuolo, Valeria Rachela Villella, Speranza Esposito, Aris Liboà, Pasquale D’Angelo, Simone Luigi Marasso, Matteo Cocuzza, Valentina Bertana, Elena Camilli, and Valentina Preziosi

Subjects

organic electrochemical transistors, functionalization, spike protein, long COVID, diagnostic devices, Biotechnology, TP248.13-248.65

Abstract

The global COVID-19 pandemic has had severe consequences from the social and economic perspectives, compelling the scientific community to focus on the development of effective diagnostics that can combine a fast response and accurate sensitivity/specificity performance. Presently available commercial antigen-detecting rapid diagnostic tests (Ag-RDTs) are very fast, but still face significant criticisms, mainly related to their inability to amplify the protein signal. This translates to a limited sensitive outcome and, hence, a reduced ability to hamper the spread of SARS-CoV-2 infection. To answer the urgent need for novel platforms for the early, specific and highly sensitive detection of the virus, this paper deals with the use of organic electrochemical transistors (OECTs) as very efficient ion–electron converters and amplifiers for the detection of spike proteins and their femtomolar concentration. The electrical response of the investigated OECTs was carefully analyzed, and the changes in the parameters associated with the transconductance (i.e., the slope of the transfer curves) in the gate voltage range between 0 and 0.3 V were found to be more clearly correlated with the spike protein concentration. Moreover, the functionalization of OECT-based biosensors with anti-spike and anti-nucleocapside proteins, the major proteins involved in the disease, demonstrated the specificity of these devices, whose potentialities should also be considered in light of the recent upsurge of the so-called “long COVID” syndrome.

Published

2023

2. Immuno-Sensing at Ultra-Low Concentration of TG2 Protein by Organic Electrochemical Transistors

Author

Valentina Preziosi, Mario Barra, Valeria Rachela Villella, Speranza Esposito, Pasquale D’Angelo, Simone Luigi Marasso, Matteo Cocuzza, Antonio Cassinese, and Stefano Guido

Subjects

organic electrochemical transistors, functionalization, specificity, TG2 protein, diagnostic devices, Biotechnology, TP248.13-248.65

Abstract

Transglutaminase 2 (TG2) is a ubiquitously expressed member of the transglutaminase family with Ca2+-dependent protein crosslinking activity. Its subcellular localization is crucial in determining its function, and indeed, TG2 is found in the extracellular matrix, mitochondria, recycling endosomes, plasma membrane, cytosol, and nucleus because it is associated with cell growth, differentiation, and apoptosis. It is involved in several pathologies, such as celiac disease, cardiovascular, hepatic, renal, and fibrosis diseases, carrying out opposite functions of up and down regulation in the progression of the same pathology. Therefore, this fine regulation requires a very sensitive and specific method of identification of TG2, which is to be detected in very small quantities in a deregulated condition. Here, we demonstrate the possibility of detecting TG2 down to attomolar concentration by using organic electrochemical transistors driven by gold electrodes functionalized with anti-TG2 antibodies. In particular, a direct correlation between the TG2 concentration and the transistor transconductance values, as extracted from typical transfer curves, was found. Overall, our findings highlight the potentialities of this new biosensing approach for the detection of TG2 in the context of pathological diseases, offering a rapid and cost-effective alternative to traditional methods.

Published

2023

3. A novel chemotaxis assay in 3-D collagen gels by time-lapse microscopy.

Author

Angela Vasaturo, Sergio Caserta, Ilaria Russo, Valentina Preziosi, Carolina Ciacci, and Stefano Guido

Subjects

Medicine, Science

Abstract

The directional cell response to chemical gradients, referred to as chemotaxis, plays an important role in physiological and pathological processes including development, immune response and tumor cell invasion. Despite such implications, chemotaxis remains a challenging process to study under physiologically-relevant conditions in-vitro, mainly due to difficulties in generating a well characterized and sustained gradient in substrata mimicking the in-vivo environment while allowing dynamic cell imaging. Here, we describe a novel chemotaxis assay in 3D collagen gels, based on a reusable direct-viewing chamber in which a chemoattractant gradient is generated by diffusion through a porous membrane. The diffusion process has been analysed by monitoring the concentration of FITC-labelled dextran through epifluorescence microscopy and by comparing experimental data with theoretical and numerical predictions based on Fick's law. Cell migration towards chemoattractant gradients has been followed by time-lapse microscopy and quantified by cell tracking based on image analysis techniques. The results are expressed in terms of chemotactic index (I) and average cell velocity. The assay has been tested by comparing the migration of human neutrophils in isotropic conditions and in the presence of an Interleukin-8 (IL-8) gradient. In the absence of IL-8 stimulation, 80% of the cells showed a velocity ranging from 0 to 1 µm/min. However, in the presence of an IL-8 gradient, 60% of the cells showed an increase in velocity reaching values between 2 and 7 µm/min. Furthermore, after IL-8 addition, I increased from 0 to 0.25 and 0.25 to 0.5, respectively, for the two donors examined. These data indicate a pronounced directional migration of neutrophils towards the IL-8 gradient in 3D collagen matrix. The chemotaxis assay described here can be adapted to other cell types and may serve as a physiologically relevant method to study the directed locomotion of cells in a 3D environment in response to different chemoattractants.

Published

2012

4. Effect of surfactant concentration on diffusion and microstructure in water-in-oil emulsions studied by low-field benchtop NMR and optical microscopy

Author

Carmine D’Agostino, Valentina Preziosi, Giuseppina Caiazza, Maria Vittoria Maiorino, Einar Fridjonsson, Stefano Guido, D’Agostino, Carmine, Preziosi, Valentina, Caiazza, Giuseppina, Maiorino, MARIA VITTORIA, Fridjonsson, Einar, and Guido, Stefano

Subjects

General Chemistry, Condensed Matter Physics

Abstract

Emulsions are ubiquitous in many consumer products, including food, cosmetics and pharmaceuticals. Whilst their macroscopic characterisation is well-established, understanding their microscopic behaviour is very challenging. In our previous work we investigated oil-in-water emulsions by studying the effect of water on structuring and dynamics of such systems. In the present work, we investigate the effect of surfactant concentration on microstructure and diffusion within the water-in-oil emulsion system by using low-field pulsed-field gradient (PFG) NMR studies carried out with a benchtop NMR instrument, in conjunction with optical imaging. The results reveal that at high surfactant concentration the formation of smaller droplets gives rise to a third component in the PFG NMR attenuation plot, which is mostly attributed to restricted diffusion near the droplet boundaries. In addition, structuring effects due to increase in surfactant concentration at the boundaries could also contribute to further slowing down water diffusion at the boundaries. As the surfactant concentration decreases, the average droplet size becomes larger and both restriction and structuring effects at the droplet boundaries become less significant, as suggested by the PFG NMR plot, whereby the presence of a third diffusion component becomes less pronounced.

Published

2023

5. Organic electrochemical transistors as novel biosensing platforms to study the electrical response of whole blood and plasma

Author

Alessio Verna, Stefano Guido, Valentina Preziosi, Mario Barra, Simone Luigi Marasso, Matteo Cocuzza, Pasquale D'Angelo, Giovanna Tomaiuolo, Antonio Cassinese, Preziosi, Valentina, Barra, Mario, Tomaiuolo, Giovanna, Guido, Stefano, Cocuzza, Matteo, Marasso, Simone, Verna, Alessio, D'Angelo, Pasquale, and Cassinese, Antonio

Subjects

Erythrocytes, Materials science, Transistors, Electronic, Capacitive sensing, Blood viscosity, Biomedical Engineering, Biocompatible Materials, Biosensing Techniques, Electrolyte, Transistors, Materials Testing, Electronic, medicine, Humans, General Materials Science, Transient response, Particle Size, Cell Aggregation, Whole blood, Capacitive coupling, business.industry, Electrochemical Techniques, General Chemistry, General Medicine, Red blood cell, medicine.anatomical_structure, Optoelectronics, business, Biosensor

Abstract

In this paper, for the first time to the best of our knowledge, organic electrochemical transistors are employed to investigate the electrical response of human blood, plasma and alternative buffer solutions that inhibit red blood cell (RBC) aggregation. Our focus is on selecting a suitable electrolytic platform and the related operating conditions, where the RBC effect on the OECT response can be observed separately from the strong ionic environment of plasma in whole blood. The transient response of whole blood to pulse experiments is characterized by two time constants, which can be related to blood viscosity and to the capacitive coupling between the ionic and electronic components of the overall system. The role of capacitive effects, likely due to enhanced double-layer formation by negatively charged RBCs, is also confirmed by the increase of transconductance which was found in RBC suspensions as compared to the suspending buffer. Overall, the complex behavior found in these experiments provides new insights for the development of innovative blood-based sensing devices for biomedical applications.

Published

2022

6. Immuno-Biosensing Based on Organic Electrochemical Transistors for Anti-Spike Protein Early Detection

Author

Mario Barra, Giovanna Tomaiuolo, Valeria Rachela Villella, Speranza Esposito, Pasquale D’Angelo, Simone Luigi Marasso, Matteo Cocuzza, Valentina Bertana, Elena Camilli, and Valentina Preziosi

Published

2023

7. Experimental investigation on foam formation through deformable porous media

Author

Valentina Preziosi, Karl Ghislain Braeckman, Raffaele Graziano, Giovanna Tomaiuolo, Stefano Guido, Graziano, R., Preziosi, V., Tomaiuolo, G., Braeckman, K., and Guido, S.

Subjects

Materials science, transport processes, General Chemical Engineering, surface, interfaces and thin film, Fluid mechanics, Composite material, fluid mechanic, multi-phase system, Porous medium

Abstract

Foam formation in porous media is a topic of growing scientific and industrial interest due to its range of applications, from daily life consumer products to oil recovery. Despite the work done on foams flowing through complex structures, this field still needs to be fully elucidated. An additional complexity to the problem arises when the porous medium is deformable, a situation which has only been faced from a modeling point of view. To address this, the investigation of foam formation in deformable porous media was conducted using commercial sponges as a deformable porous media system, with special emphasis on the effect of confinement on foam bubble size distribution. Foam was formed by wetting the sponge with an aqueous surfactant solution and then squeezing the sponge either between two glass cover slides or between a plastic net and a cover slide. Results revealed that the latter system allowed the formation of drier foams (i.e., with lower liquid fraction, fL < 0.3), more similar to the ones obtained in dish-washing applications. Also, the effect of sponge type, in terms of material and microstructure, on final foam was considered.

Published

2020

8. Semen rheology and its relation to male infertility

Author

Giovanna Tomaiuolo, Fiammetta Fellico, Valentina Preziosi, Stefano Guido, Tomaiuolo, G., Fellico, F., Preziosi, V., and Guido, S.

Subjects

Biomaterials, lifestyle factor, genetic cause, Biomedical Engineering, Biophysics, semen viscosity and viscoelasticity, sperm motility, Bioengineering, Biochemistry, male infertility, Biotechnology

Abstract

Infertility affects 15% of couples of reproductive age worldwide. In spite of many advances in understanding and treating male infertility, there is still a number of issues that need further investigation and translation to the clinic. Here, we review the current knowledge and practice concerning semen rheology and its relation with pathological states affecting male infertility. Although it is well recognized that altered rheological properties of semen can impair normal sperm movement in the female reproductive tract, routine semen analysis is mostly focused on number, motility and morphology of spermatozoa, and includes only an approximate, operator-dependent measure of semen viscosity. The latter is based on the possible formation of a liquid thread from a pipette where a semen sample has been aspirated, a method that is sensitive not only to viscosity but also to elongational properties and surface tension of semen. The formation of a liquid thread is usually associated with a gel-like consistency of the sample and changes in spermatozoa motility in such a complex medium are still to be fully elucidated. The aim of this review is to point out that a more quantitative and reliable characterization of semen rheology is in order to improve the current methods of semen analysis and to develop additional tools for the diagnosis and treatment of male infertility.

Published

2022

9. Flow-induced concentration gradients in shear-banding of branched wormlike micellar solutions

Author

Vincenzo Guida, Carla Caiazza, Stefano Guido, Valentina Preziosi, Giovanna Tomaiuolo, D. O'Sullivan, Caiazza, C., Preziosi, V., Tomaiuolo, G., O'Sullivan, Patrick, Guida, V., and Guido, S.

Subjects

Materials science, Microfluidics, Phase separation, Video microscopy, 02 engineering and technology, 010402 general chemistry, 01 natural sciences, Biomaterials, Shear-induced structuring, Colloid and Surface Chemistry, Surfactant, Wormlike micelle, Microchannel, Conductance, Velocimetry, 021001 nanoscience & nanotechnology, 0104 chemical sciences, Surfaces, Coatings and Films, Electronic, Optical and Magnetic Materials, Microfluidic, Shear (geology), Chemical physics, Micellar solutions, 0210 nano-technology, Concentration gradient, Shear banding

Abstract

Hypothesis Shear-banding of branched wormlike solutions is a topic of active investigation which has not been fully elucidated. Here, we surmise that flow-induced microstructuring in the shear banding regime is associated with spatial concentration gradients. Experiments The experiments focus on the flow-induced behavior of a CTAB/NaSal wormlike micellar system. A unique approach based on a microfluidic-spitter geometry, combined with particle-image velocimetry and high-speed video microscopy, is used to separate the streams flowing out from the core and the near wall zones of the microchannel. Findings Here, we present the first direct experimental evidence of the correlation between phase separation and shear banding. By increasing the pressure-drop across a microcapillary, the onset of a grainy texture close to the wall, showing a flow-induced demixing effect, is observed. We use a splitter to measure effluent streams from the center and the near-wall zones in terms of viscosity, conductance and dry mass. We observe that phase-separation induced by the flow correlates with chemical concentration gradients. This confirms our hypothesis that shear-induced local de-mixing of the system is strongly related to chemical concentration gradients.

Published

2019

10. The microstructure of Carbopol in water under static and flow conditions and its effect on the yield stress

Author

Jan Claussen, Behzad Mohebbi, Valentina Preziosi, Stefano Guido, Dario Uva, Raffaele Graziano, Giovanna Tomaiuolo, Graziano, R., Preziosi, V., Uva, D., Tomaiuolo, G., Mohebbi, B., Claussen, J., and Guido, S.

Subjects

Materials science, Capillary action, Spinodal decomposition, Carbopol, 02 engineering and technology, Slip (materials science), 010402 general chemistry, 01 natural sciences, Clustering, Biomaterials, Colloid and Surface Chemistry, Flow-induced effect, Composite material, Polymer, Microstructure, Yield stress, Complex fluid, chemistry.chemical_classification, Rheometry, 021001 nanoscience & nanotechnology, 0104 chemical sciences, Surfaces, Coatings and Films, Electronic, Optical and Magnetic Materials, Flow conditions, chemistry, Microfluidic, 0210 nano-technology

Abstract

In this work, experimental observations of the microstructure of neutralized polyacrylic acid (Carbopol) in water by confocal microscopy under both static and flow conditions are presented. In the former case, a Carbopol-rich phase made by swollen particles dispersed in a water-rich continuous phase is found, so that the system will be henceforth referred to as a suspension, as long as particles are observed. The swollen particles form dendritic-like aggregates, which span the entire solution volume above a critical concentration. In such conditions, a percolated network can be formed, leading to the onset of a yield stress behavior. By separating the dispersed and continuous phase through centrifugation, we provide evidence of a miscibility gap in the phase behavior of Carbopol in water. When the Carbopol suspensions flow in a microfluidic capillary, a particle-concentrated plug core can be distinguished from a less concentrated layer corresponding to a steep velocity decrease. Confocal imaging also shows that the apparent slip found in Carbopol suspensions is due to a particle-concentrated near-wall region, where no flow is observed. Such flow-induced microstructure is responsible for the different nature of the yield stress values measured by classical rheometry and by flow velocimetry. While the yield stress measured by the former can be here related to the presence of a percolated network, the yield stress obtained from the velocity profile is due to the heterogeneous particle distribution along the capillary radius. These results provide a novel insight on the mechanisms governing yield stress in complex fluids.

Published

2021

11. Microcapillary flow method to investigate emulsion droplet deformability

Author

Valentina Preziosi, Giovanna Tomaiuolo, Preziosi, V., and Tomaiuolo, G.

Subjects

Work (thermodynamics), Materials science, Microfluidics, Flow (psychology), 02 engineering and technology, Deformation (meteorology), 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, 0104 chemical sciences, Surface tension, Chemical engineering, Phase (matter), Emulsion, 0210 nano-technology, Porous medium

Abstract

Emulsions are complex systems widely used in many relevant industrial applications, such as in the food, biomedical and petrochemical fields. They are metastable systems composed of oil, water and surfactants, and show complex structures at rest spanning different spatial scales and depending on composition and temperature. Although the phase behavior of emulsions at rest has been thoroughly investigated, the behavior of emulsions under flow still remains an open question. In particular, emulsion droplet deformation in microconfined conditions is a topic of relevant importance because of its applications in a wide range of processes, such as flow in porous media and transdermal drug delivery. In this work, a microfluidic device to investigate the effect of different oils as emulsion continuous phase on droplet deformability is presented by measuring in situ the interfacial tension of water in oil emulsions flowing in a microcapillary.

Published

2020

12. Gravure printed organic thin film transistors: Study on the ink printability improvement

Author

Luigi Mariucci, Valentina Preziosi, Antonio Cassinese, Antonio Valletta, Francesco Maita, Guglielmo Fortunato, Sabrina Calvi, Matteo Rapisarda, Calvi, S., Maita, F., Rapisarda, M., Fortunato, G., Valletta, A., Preziosi, V., Cassinese, A., and Mariucci, L.

Subjects

Organic inks, Materials science, Organic thin film transistor, Organic thin film transistors, 02 engineering and technology, Dielectric, Fluid dynamic parameters, 010402 general chemistry, 01 natural sciences, Biomaterials, Materials Chemistry, Deposition (phase transition), Electronics, Electrical and Electronic Engineering, Electrical conductor, Organic ink, Inkwell, business.industry, Process (computing), General Chemistry, 021001 nanoscience & nanotechnology, Condensed Matter Physics, Gravure printing, 0104 chemical sciences, Electronic, Optical and Magnetic Materials, Characterization (materials science), Thin-film transistor, ComputingMethodologies_DOCUMENTANDTEXTPROCESSING, Optoelectronics, Fluid dynamic parameter, Rheology, 0210 nano-technology, business

Abstract

Organic material deposition by gravure printing is a promising pathway for the realization of large area flexible electronic devices. Nevertheless, in order to achieve high performance it is required to improve the electronic ink printability, operating on the fluid dynamic mechanisms involved during the process. In this work, this issue has been faced working on ink characteristics for a conductive and a dielectric material. The suitable ink features have been defined studying the influence on the printability of the different forces that act in the fluid during the printing process, using an experimental approach. Properly defined ink formulations have been printed, considering different shapes and dimensions of the cells on the gravure cliche to fit the ink features. The printing outcomes have been compared and analysed through the evaluation of several significant fluid dynamic parameters and the rheological characterization of the materials. Finally, exploiting the results of this study, high performance fully printed organic thin film transistors have been realized.

Published

2018

13. Emulsions in porous media: From single droplet behavior to applications for oil recovery

Author

Valentina Preziosi, Antonio Perazzo, Stefano Guido, Giovanna Tomaiuolo, Perazzo, Antonio, Tomaiuolo, Giovanna, Preziosi, Valentina, and Guido, Stefano

Subjects

Materials science, Petroleum engineering, technology, industry, and agriculture, 02 engineering and technology, Surfaces and Interfaces, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, 0104 chemical sciences, Colloid and Surface Chemistry, Rheology, Emulsion, Enhanced oil recovery, Wetting, Physical and Theoretical Chemistry, 0210 nano-technology, Porous medium

Abstract

Emulsions are suspensions of droplets ubiquitous in oil recovery from underground reservoirs. Oil is typically trapped in geological porous media where emulsions are either formed in situ or injected to elicit oil mobilization and thus enhance the amount of oil recovered. Here, we briefly review basic concepts on geometrical and wetting features of porous media, including thin film stability and fluids penetration modes, which are more relevant for oil recovery and oil-contaminated aquifers. Then, we focus on the description of emulsion flow in porous media spanning from the behaviour of single droplets to the collective flow of a suspension of droplets, including the effect of bulk and interfacial rheology, hydrodynamic and physico-chemical interactions. Finally, we describe the particular case of emulsions used in underground porous media for enhanced oil recovery, thereby discussing some perspectives of future work. Although focused on oil recovery related topics, most of the insights we provide are useful towards remediation of oil-contaminated aquifers and for a basic understanding of emulsion flow in any kind of porous media, such as biological tissues.

Published

2018

14. Development of model systems for in vitro investigation of transdermal transport pathways

Author

Sergio Caserta, Stefano Guido, Valentina Preziosi, Roberta Liuzzi, Liuzzi, Roberta, Preziosi, Valentina, Caserta, Sergio, and Guido, Stefano

Subjects

Chromatography, Chemistry, General Chemical Engineering, Transport pathways, 02 engineering and technology, 021001 nanoscience & nanotechnology, 030226 pharmacology & pharmacy, In vitro, 03 medical and health sciences, 0302 clinical medicine, Emulsion, 0210 nano-technology, Transdermal Drug-Delivery, Emulsion, Multiphase Fluids Microstructure, Transport processes, Bicontinuous emulsion, Transdermal

Abstract

Skin is a complex structured system primarily involved in Transdermal Drug Delivery (TDD). The outer stratum corneum represents the main barrier to the entrance of external molecules. Nowadays, none of the recognized methods, used for the investigation of penetration processes, is able to give a complete overview of the transport mechanisms involved. Standard protocols are based on the use of human or animal skin samples, which are difficult and expensive to obtain. Here, we present a novel experimental setup to investigate TDD by using Confocal Laser Scanning Microscopy and image analysis. The methodology is based on diffusion experiments of fluorescent-labelled fluids (water, oil, and oil-in-water emulsions), in a model matrix. Using an agarose gel as model for a proof of concept, different penetration efficiencies were observed, suggesting an important role of both chemical composition and fluid microstructure on the transport mechanism. An adequate model system should be used to better mimic the stratum corneum morphology and properties. To this aim, several bicontinuous emulsion gels, obtained from an emulsification process, were preliminary formulated and suggested as model systems to mimic the stratum corneum. In this work, we define the key directions for the development of an innovative approach to study the penetration of formulations through the skin.

Published

2017

15. Flow-induced nanostructuring of gelled emulsions

Author

Stefano Guido, Valentina Preziosi, Antonio Perazzo, Giovanna Tomaiuolo, Dganit Danino, Vitaly Pipich, Luigi Paduano, Preziosi, V., Perazzo, A., Tomaiuolo, G., Pipich, V., Danino, D., Paduano, L., and Guido, S.

Subjects

Materials science, Capillary action, Emulsified fuel, Nanotechnology, 02 engineering and technology, General Chemistry, 021001 nanoscience & nanotechnology, Condensed Matter Physics, Microstructure, 01 natural sciences, Suspension (chemistry), Chemical engineering, Phase (matter), Percolation, 0103 physical sciences, Emulsion, 010306 general physics, 0210 nano-technology, Shear flow

Abstract

Although the phase behavior of emulsions has been thoroughly investigated, the effect of flow on emulsion morphology, which is relevant for many applications, is far from being fully elucidated. Here, we investigate an emulsion based on two common nonionic surfactants in a range of water concentration where complex and diverse microstructures are found at rest, such as multilamellar and bicontinuous phases. In spite of such complexity, once subjected to shear flow, all the emulsions investigated are characterized by thinning filaments which eventually break up into a concentrated suspension of micro-sized water-based droplets dispersed in a continuous oil phase. The so-formed droplets tend to align in string-like structures. The emulsions exhibit a yield stress, whose value can be estimated by the plug-core velocity profiles in pressure-driven capillary flow, thus providing evidence of weakly attractive interdroplet interactions. The latter are consistent with droplet clustering and percolation observed at rest. These results can also be relevant to the flow behavior of other liquid–liquid systems, such as polymer blends, where the flow-induced microstructure is under debate as well.

Published

2017

16. Microstructure evolution during nano-emulsification by NMR and microscopy

Author

Stefano Guido, Valentina Preziosi, Mick D. Mantle, Einar O. Fridjonsson, Carmine D'Agostino, Abdulaziz Khan, D'Agostino, C., Preziosi, V., Khan, A., Mantle, M., Fridjonsson, E., and Guido, S.

Subjects

Materials science, Diffusion, 02 engineering and technology, PFG NMR, 010402 general chemistry, 01 natural sciences, Micelle, Biomaterials, Colloid and Surface Chemistry, Pulmonary surfactant, Rheology, Nano-emulsions, Phase (matter), medicine, Lamellar structure, Phase inversion emulsification, Mineral oil, 021001 nanoscience & nanotechnology, Microstructure, 0104 chemical sciences, Nano-emulsion, Electronic, Optical and Magnetic Materials, Surfaces, Coatings and Films, Chemical engineering, 0210 nano-technology, CLSM, medicine.drug

Abstract

HypothesisMicrostructure evolution in emulsions as a function of composition is of great interest but fundamentals have not yet been fully elucidated. Here, pulsed-field gradient (PFG) NMR diffusion measurements have been combined with confocal laser scanning microscopy (CLSM) to assess evolution of dynamics and microstructure during nano-emulsification.ExperimentsDiffusion coefficients of emulsions made of water, mineral oil and surfactants (Span 20 and Tween 80) were measured as a function of water composition and compared with the morphological features of the emulsions obtained by CLSM.FindingsIn the absence of water, two phases are visible from CLSM, and two diffusion components are observed with PFG NMR, a major fast component attributed to a continuous oil phase containing the more hydrophobic surfactant Span 20 with traces of Tween 80, and a minor slow component attributed to a dispersed phase of the more hydrophilic surfactant Tween 80 with traces of mineral oil and Span 20. At the inversion point (25 wt% water) the two-component diffusion behavior of the oil-rich phase is drastically reversed in terms of populations, with the slow diffusion process becoming dominant. This suggests a significant structuring of the oil-rich phase in the presence of surfactants enhanced by water, which can be explained by the formation of aggregates in the oil phase as reverse micelles or of a lamellar structure, and ties in well with the rheological measurements.

Published

2019

17. Confined tube flow of low viscosity emulsions: Effect of matrix elasticity

Author

Stefano Guido, Valentina Preziosi, Sergio Caserta, M. Fenizia, Giovanna Tomaiuolo, Preziosi, Valentina, Tomaiuolo, Giovanna, Fenizia, M., Caserta, Sergio, and Guido, Stefano

Subjects

Flow visualization, Materials science, 010304 chemical physics, Mechanical Engineering, Constant Viscosity Elastic (Boger) Fluids, Thermodynamics, Condensed Matter Physic, 02 engineering and technology, Mechanics, 021001 nanoscience & nanotechnology, Condensed Matter Physics, 01 natural sciences, Viscoelasticity, Physics::Fluid Dynamics, Viscosity, Mechanics of Materials, 0103 physical sciences, Newtonian fluid, Mechanics of Material, General Materials Science, Materials Science (all), Two-phase flow, Elasticity (economics), 0210 nano-technology, Shear flow

Abstract

This study is addressed to the effect of the elasticity of the continuous phase on confined flow of low viscosity emulsions, a topic of interest in several applications. A Newtonian silicone oil was used as the dispersed phase, while three different water-based fluids, a Newtonian and two Boger fluids, were used as the continuous phase. All the fluids have the same viscosity (ca. 0.05 Pa s). Emulsions were prepared by feeding the two phases to a T-junction followed by a membrane. When the continuous phase was a Boger fluid, the average drop size of the so obtained emulsions was higher (as compared to the Newtonian continuous phase) and a bimodal distribution was observed. Such lower mixing efficiency for a Boger continuous phase is in line with the result for an isolated droplet that breakup is hindered by matrix elasticity. High-speed microscopy visualization of the emulsions flowing through a microcapillary allowed one to determine the velocity profiles and the droplet spatial distribution as a function of the shear rate. In all the experiments, the formation of a droplet-rich core and of a dropletdevoid wall region D was observed, with a significant enhancement when the continuous phase was a Boger fluid (where values of D as high as 37% of capillary radius were found). So, confinement here refers to the fact that, although the droplets are much smaller than capillary radius, the droplet-free layer takes up a significant fraction of the capillary radius. The observed nonhomogeneous droplet spatial distribution was not due to a transient entry effect, as shown by imaging the emulsions flow at different sections from the capillary inlet, but can be explained by a balance between collision-induced drop diffusion and wall lift force. The former acts to homogenize droplet spatial distribution, while the latter tends to push droplets away from the wall and is enhanced by matrix elasticity. These effects lead to the accumulation of larger droplets around the center of the channel, while smaller droplets are pushed toward the periphery. The velocity profiles for the Boger continuous phase were flat in the droplet-rich core, thus suggesting that the confined emulsions behave as a Bingham fluid. The corresponding yield stress was determined by data fitting of the velocity profiles and rather large values were so obtained. This result is consistent with the high values, close to the maximum packing for spherical particles in binary dispersions, of the droplet volume fraction in the core, which were estimated by measuring the thickness of the droplet-devoid annular region as a function of the applied flow rate and making a volume balance. Overall, the results of this work bear strong analogies with the confined flow of other concentrated suspensions of deformable particles, such as red blood cells in microcirculation, where the formation of a cell-free layer at the wall, which is referred to as margination, has important pathophysiological implications. These findings suggest that low viscosity emulsions with an elastic matrix under confined flow can be used as a tunable model system of biomedical relevance.

Published

2016

18. Confined flow behaviour of droplets in microcapillary flow

Author

Stefano Guido, Rosa D'Apolito, Sapana Khati Chhetri, Giovanna Tomaiuolo, Valentina Preziosi, D'Apolito, Rosa, Preziosi, Valentina, Khati Chhetri, Sapana, Tomaiuolo, Giovanna, and Guido, Stefano

Subjects

Materials science, Capillary action, Flow (psychology), Biophysics, Rotational symmetry, 02 engineering and technology, 01 natural sciences, 010305 fluids & plasmas, Physics::Fluid Dynamics, Viscosity, 0103 physical sciences, General Materials Science, Deformation (mechanics), Chemistry (all), Laminar flow, Surfaces and Interfaces, General Chemistry, Mechanics, Topical issue: Flowing Matter, Problems and Application, 021001 nanoscience & nanotechnology, Capillary number, Biophysic, Materials Science (all), 0210 nano-technology, Porous medium, Biotechnology

Abstract

The problem of droplets flowing in a micritions is relevant in several applications including flow in porous media. When the flow in the capillary is laminar with negligible gravity effects, droplet velocity and deformation depend upon three independent parameters: the droplet size relative to the capillary radius [Formula: see text][Formula: see text], which is a measure of confinement, the viscosity ratio [Formula: see text] between the droplet and the continuous phase and the capillary number Ca which measures the ratio of viscous to capillary forces. Although droplet microconfined flow behaviour in capillaries has been widely investigated by theoretical models, experimental results are still scarce. Here, an experimental campaign focused on the flow behaviour of axisymmetric confined droplets flowing in a microcapillary is carried out. Our experimental results were obtained by using a water in soybean oil emulsion with a low viscosity ratio and the effect of the aforementioned three parameters, [Formula: see text], [Formula: see text] and Ca, on droplet motion was investigated. Moreover, our experimental results are compared with numerical solutions available in the literature.

Published

2018

19. Measuring Interfacial Tension of Emulsions in Situ by Microfluidics

Author

Stefano Guido, Valentina Preziosi, Giovanna Tomaiuolo, Antonio Perazzo, Reinhard Miller, Mariapia D’Antuono, Rosa D'Apolito, D'Apolito, Rosa, Perazzo, Antonio, D'Antuono, Mariapia, Preziosi, Valentina, Tomaiuolo, Giovanna, Miller, Reinhard, and Guido, Stefano

Subjects

Steady state, Materials science, Microfluidics, Condensed Matter Physic, 02 engineering and technology, Surfaces and Interfaces, 010402 general chemistry, 021001 nanoscience & nanotechnology, Condensed Matter Physics, 01 natural sciences, 0104 chemical sciences, Surface tension, Pulmonary surfactant, Critical micelle concentration, Emulsion, Electrochemistry, General Materials Science, Materials Science (all), Deformation (engineering), Composite material, 0210 nano-technology, Shear flow, Surfaces and Interface, Spectroscopy

Abstract

Interfacial tension is a key parameter affecting industrially relevant properties of emulsions, such as morphology and stability. Although several methods are available to measure interfacial tension, they are based on generation of droplets starting from separate emulsion components and cannot directly probe the interfacial tension of an emulsion as such. Here, a novel microfluidic tensiometry device to measure interfacial tension of a water-in-oil emulsion in situ as a function of surfactant concentration is presented. In our approach, interfacial tension is obtained from a quantitative analysis of the deformation of individual emulsion droplets under steady state shear flow in microfluidic channels. The technique is validated by comparing the results with experimental data obtained by the pendant drop method in a broad range of interfacial tension values. A very good agreement is found, and an estimate of the surfactant critical micellar concentration (CMC) is also obtained. The proposed microfluidic setup can be used even at high surfactant concentrations, where the measurement is made more challenging by sample viscoelasticity, thus providing a powerful tool to determine the interfacial tension of complex systems in an extended concentration range. The technique could be also used for in-line monitoring of emulsion processing.

Published

2018

20. Flow-switchable morphology of concentrated emulsions

Author

Stefano Guido, Antonio Perazzo, Valentina Preziosi, Giovanna Tomaiuolo, Preziosi, Valentina, Perazzo, Antonio, Tomaiuolo, Giovanna, and Guido, Stefano

Subjects

Materials science, Nanodroplet, General Chemical Engineering, Flow (psychology), Energy Engineering and Power Technology, 02 engineering and technology, 010402 general chemistry, 01 natural sciences, Viscoelasticity, Industrial and Manufacturing Engineering, Impeller, Newtonian fluid, Chemical Engineering (all), Coalescence (physics), Birefringence, Flow-induced structuring, Emulsion, Process Chemistry and Technology, Chemistry (all), General Chemistry, 021001 nanoscience & nanotechnology, Microstructure, 0104 chemical sciences, Chemical engineering, Attractive interaction, 0210 nano-technology

Abstract

Soft materials can be switched from a liquid to a gel-like state by structural re-arrangement down to the nanoscale and find application in many fields ranging from biomedical engineering to oil recovery. Here, we show that flow-switchable emulsions of oil, water and surfactants can be obtained by simple low-energy emulsification processing. By dropwise addition of water to the oil-surfactant solution under mild stirring, a striking transition from a transparent, purely viscous Newtonian fluid to a highly viscoelastic translucent material climbing onto the impeller is observed. We show that this transition is associated with the formation of elongated droplets, eventually disrupting into nanodroplets which, upon stopping the flow, slowly relax to a stable gel-like microstructure with noticeable birefringent properties. The two structures (elongated droplets and gel-like microstructure) can be reversibly switched between each other by starting/stopping the flow. This behavior can be attributed to the interplay between the cluster-disruptive effect of flow on one side, and droplets attractive interactions promoting coalescence on the other side. Our results, observed for different systems by changing oil type and surfactants chain length, highlight a flow-switchable emulsion processing method, which can be used to produce concentrated emulsions for a variety of applications.

Published

2018

21. Contributors

Author

Salman Akram, Liliana Alamilla-Beltrán, Olaia Álvarez-Bermúdez, Nicolas Anton, Ana I. Bourbon, Cheryl Chung, Francesco Donsì, Jianguo Feng, Seyed M.T. Gharibzahedi, Raquel F.S. Gonçalves, Virginia G. Granillo-Guerrero, Gustavo F. Gutiérrez-López, Andreas Håkansson, Seid Mahdi Jafari, Heike P. Karbstein, Diana E. Leyva-Daniel, Qi Liu, Farooq A. Masoodi, David J. McClements, Amor Monroy-Villagrana, Rafael Muñoz-Espí, Kamla Pathak, Satyanarayan Pattnaik, Antonio Perazzo, Ana C. Pinheiro, Aldo Pizzino, Valentina Preziosi, Marilyn Rayner, Odile Sonneville-Aubrun, Kalpana Swain, Ulrike S. van der Schaaf, Thierry F. Vandamme, António A. Vicente, Fidel Villalobos-Castillejos, Goran T. Vladisavljević, Touseef A. Wani, Megumi N. Yukuyama, Zipei Zhang, Qi Zhang, Ruojie Zhang, and Zhengxi Zhu

Published

2018

22. The effect of flow on viscoelastic emulsion microstructure

Author

Valentina Preziosi, Stefano Guido, Antonio Perazzo, Giovanna Tomaiuolo, Preziosi, Valentina, Perazzo, Antonio, Tomaiuolo, Giovanna, and Guido, Stefano

Subjects

Work (thermodynamics), Materials science, Flow (psychology), Chemistry (all), Biophysics, 02 engineering and technology, General Chemistry, Surfaces and Interfaces, 021001 nanoscience & nanotechnology, Microstructure, 01 natural sciences, Soft materials, Viscoelasticity, Low energy, Biophysic, Phase (matter), 0103 physical sciences, Emulsion, General Materials Science, Materials Science (all), Composite material, 010306 general physics, 0210 nano-technology, Topical issue: Fluids and Structures: Multi-scale coupling and modeling, Biotechnology

Abstract

Emulsions made of oil, water and surfactants are widespread soft materials with complex structures depending on composition and temperature. Emulsion phase behavior at rest has been widely investigated but flow-induced effects, which are very relevant in many applications, can still be further explored towards improved emulsion microstructural design. In this work, we use low energy emulsification processing to create small-sized emulsions. In a previous report, we showed the emulsion morphology development and the effect of flow on the microstructure of a highly viscoelastic attractive emulsion which result in a concentrated nanoemulsion after viscoelastic droplet filaments are disrupted. Here, we show that upon stopping the flow, the filaments slowly buckle, recoil and finally form clusters of randomly flocculated droplets. We thus obtain two completely different emulsion morphologies simply induced by the action of flow, where in both cases attractive interactions play a key role. The emulsion high interfacial area represents a valuable feature for several applications such as upstream operations, microreaction media and drug delivery.

Published

2018

23. Monitoring emulsion microstructure by Organic Electrochemical Transistors

Author

Antonio Cassinese, Agostino Romeo, Antonio Perazzo, Stefano Guido, Simone Luigi Marasso, Giuseppe Tarabella, Valentina Preziosi, Salvatore Iannotta, Pasquale D'Angelo, Mario Barra, Preziosi, Valentina, Barra, Mario, Perazzo, Antonio, Tarabella, G., Romeo, A., Marasso, S. L., D'Angelo, P., Iannotta, S., Cassinese, Antonio, and Guido, Stefano

Subjects

Materials science, Fabrication, oil/water emulsions, Transistor, microstructure, OECT, Nanotechnology, 02 engineering and technology, General Chemistry, Electrolyte, 010402 general chemistry, 021001 nanoscience & nanotechnology, Microstructure, 01 natural sciences, 0104 chemical sciences, law.invention, Characterization (materials science), Organic semiconductor, law, Percolation, Phase (matter), Materials Chemistry, 0210 nano-technology

Abstract

Organic Electrochemical Transistors (OECTs) are powerful amplifying transducers of chemical signals allowing to measure ionic transport between an electrolyte solution and an organic semiconductor film with nanosensing capabilities and low cost of fabrication. Here, we report how OECTs can also be exploited to detect microstructural features of complex soft materials, such as oil/water emulsions. To this purpose, the response of OECTs is investigated for samples obtained at different stages of a nano-emulsification process carried out by gradually adding water to a mixture of oil and two non- ionic surfactants. Our results demonstrate that, above a critical water volume fraction, OECTs are able to work as depletion-mode transistors displaying specific features in terms of the final current modulation capability and of the transient time response. In particular, the kinetics of the device current upon the application of step-like probing gate voltages are succesfully modelled by using a double exponential law with characteristic time constants. We relate the OECT behavior to clustering and percolation of water droplets as detected by performing confocal laser scanning microscopy (CLSM) and rheometrical measurements. Our results lay the foundation for the quantitative application of OECTs to identify phase behaviour and microstructure in complex soft materials, a relevant issue in industrial processing and material characterization.

Published

2017

24. Interfacial tension of oil/water emulsions with mixed non-ionic surfactants: comparison between experiments and molecular simulations

Author

Valentina Preziosi, Sabrina Pricl, Antonio Perazzo, Stefano Guido, Erik Laurini, Paola Posocco, Posocco, Paola, Perazzo, A., Preziosi, V., Laurini, Erik, Pricl, Sabrina, Guido, S., Posocco, P., Perazzo, Antonio, Preziosi, Valentina, Laurini, E., Pricl, S., and Guido, Stefano

Subjects

Non ionic, General Chemical Engineering, Interfacial tension, water-in-oil emulsion, 02 engineering and technology, 010402 general chemistry, 01 natural sciences, Surface tension, Interfacial tension, water-in-oil emulsions, non-ionic surfactant mixutres, molecular simulations, pendant drop measurements, Pulmonary surfactant, Organic chemistry, Molecule, Chemical Engineering (all), pendant drop measurements, non-ionic surfactant mixutres, Chemistry, Drop (liquid), water-in-oil emulsions, Chemistry (all), Intermolecular force, General Chemistry, 021001 nanoscience & nanotechnology, 0104 chemical sciences, Chemical engineering, Critical micelle concentration, Emulsion, molecular simulations, 0210 nano-technology, Interfacial tension

Abstract

Stable oil/water emulsions are usually obtained by using mixtures of different surfactants. Such systems display synergistic interface stabilizing effects, which have not been fully elucidated yet. Moreover, in many applications surfactants are added at concentrations well above their critical micellar concentration (CMC), and this regime has not been thoroughly explored in the literature as well. Here, we investigate oil/water emulsions through oil/water interfacial tension using two common non-ionic surfactants, Tween 80 and Span 20, in the concentration range C (0.3-1 wt%) well above their respective CMCs. Mesoscale molecular simulations coupled interfacial tensiometry experiments to characterise these interfaces at a molecular level. Interfacial tension γ was measured by a pendant drop technique. Coarse-grained calculations provided a microscopic view of the interface at the molecular level (i.e. surfactant arrangement, interface thickness), and were employed to extend the study to those surfactant concentrations where experiments could hardly provide reliable data, if any. We found a significant synergistic effect between Tween 80 and Span 20, with low molecular weight Span molecules occupying free spaces between the much larger, bulky Tween compounds. The surfactant intermolecular interactions could be associated to a striking decrease of interfacial tension in going from pure surfactants to a mixture at the same total weight concentration. Furthermore, the interface was found to exhibit a spatial inhomogeneity with a "patch-like" organisation, reminiscent of microphase separation. Our results show that the proposed, combined experimental/in silico approach provides relevant insights for several industrial applications, such as emulsion stability and oil spill remediation.

Published

2016

25. Real-time monitoring of self-assembling worm-like micelle formation by organic transistors

Author

Salvatore Iannotta, Giuseppe Tarabella, Pasquale D'Angelo, Stefano Guido, Agostino Romeo, Valentina Preziosi, Mario Barra, Antonio Cassinese, Preziosi, V., Tarabella, G., D'Angelo, P., Romeo, A., Barra, M., Cassinese, Antonio, and Iannotta, S.

Subjects

Aqueous solution, Chemistry, General Chemical Engineering, Transistor, Nanotechnology, General Chemistry, Micelle, law.invention, PEDOT:PSS, Rheology, law, Real-time monitoring of self-assembling worm-like micelle formation by organic transistors, Micellar solutions, Self assembling

Abstract

Thanks to their appealing rheological properties, nowadays micellar solutions play a fundamental role in many industrial sectors, including personal care products, cosmetics and pharmaceuticals. The use of these solutions and their effectiveness in the desired application is, however, strongly dependent on the specific micellar aggregation form and the related degree of entanglement. To this end, it should be mentioned that, still today, the type and size of the micellar aggregates in a solution can be only investigated by using sophisticated laboratory techniques, which are very difficult to be applied directly in real industrial production sites. In this study, we demonstrate that organic electrochemical transistors (OECTs) based on PEDOT:PSS active channels can be used to reveal the presence of worm-like micelles in surfactant-salt aqueous solutions. In the worm-like regime the response of these devices displays distinctive features in comparison with those exhibited when pure surfactant solutions, containing only spherical micelles, are analysed. Our results could pave the way to the development of a new class of portable and user-friendly devices, suitable for the in situ monitoring of morphological transitions, involving micellar aggregates.

Published

2015

26. Phase inversion emulsification: Current understanding and applications

Author

Antonio Perazzo, Stefano Guido, Valentina Preziosi, Perazzo, Antonio, Preziosi, Valentina, and Guido, Stefano

Subjects

Materials science, Nanotechnology, Phase Transition, Colloid and Surface Chemistry, Nanoemulsion, Emulsion phase inversion, Phase (matter), Oil recovery, Humans, Physical and Theoretical Chemistry, Process engineering, Mixing (physics), Continuous phase modulation, Colloidal particle, business.industry, Emulsion, Medicine (all), Inversion (meteorology), Surfaces and Interfaces, Crude oil, Drug-delivery, Scientific method, Emulsions, Current (fluid), business, Phase behavior, Surfaces and Interface, Phase inversion, Human

Abstract

This review is addressed to the phase inversion process, which is not only a common, low-energy route to make stable emulsions for a variety of industrial products spanning from food to pharmaceuticals, but can also be an undesired effect in some applications, such as crude oil transportation in pipelines. Two main ways to induce phase inversion are described in the literature, i.e., phase inversion composition (PIC or catastrophic) and phase inversion temperature (PIT or transitional). In the former, starting from one phase (oil or water) with surfactants, the other phase is more or less gradually added until it reverts to the continuous phase. In PIT, phase inversion is driven by a temperature change without varying system composition. Given its industrial relevance and scientific challenge, phase inversion has been the subject of a number of papers in the literature, including extensive reviews. Due to the variety of applications and the complexity of the problem, most of the publications have been focused either on the phase behavior or the interfacial properties or the mixing process of the two phases. Although all these aspects are quite important in studying phase inversion and much progress has been done on this topic, a comprehensive picture is still lacking. In particular, the general mechanisms governing the inversion phenomenon have not been completely elucidated and quantitative predictions of the phase inversion point are limited to specific systems and experimental conditions. Here, we review the different approaches on phase inversion and highlight some related applications, including future and emerging perspectives.

Published

2014

27. Using Optical Tweezers for the Characterization of Polyelectrolyte Solutions with Very Low Viscoelasticity

Author

Sergio Caserta, Angelo Pommella, Manlio Tassieri, Valentina Preziosi, Stefano Guido, Jonathan M. Cooper, Pommella, Angelo, Preziosi, Valentina, Caserta, Sergio, Jonathan M., Cooper, Guido, Stefano, and Manlio, Tassieri

Subjects

Microrheology, Materials science, Optical Tweezers, Viscosity, Polyacrylamide, Acrylic Resins, Surfaces and Interfaces, Condensed Matter Physics, Elasticity, Article, Viscoelasticity, Polyelectrolyte, Solutions, Electrolytes, chemistry.chemical_compound, chemistry, Optical tweezers, Rheology, Chemical physics, Polymer chemistry, Electrochemistry, General Materials Science, Spectroscopy

Abstract

Recently, optical tweezing has been used to provide a method for microrheology addressed to measure the rheological properties of small volumes of samples. In this work, we corroborate this emerging field of microrheology by using these optical methods for the characterization of polyelectrolyte solutions with very low viscoelasticity. The influence of polyelectrolyte (i.e., polyacrylamide, PAM) concentration, specifically its aging, of the salt concentration is shown. The close agreement of the technique with classical bulk rheological measurements is demonstrated, illustrating the advantages of the technique.

Published

2013

28. A novel chemotaxis assay in 3-D collagen gels by time-lapse microscopy

Author

Ilaria Russo, Carolina Ciacci, Stefano Guido, Valentina Preziosi, Sergio Caserta, Angela Vasaturo, Vasaturo, Angela, Caserta, Sergio, I., Russo, Preziosi, Valentina, C., Ciacci, and Guido, Stefano

Subjects

cell migration, Diffusion, Image Processing, lcsh:Medicine, Cell motility, Engineering, Immune Regulation [NCMLS 2], Cell Movement, Fluorescence microscope, Biological Systems Engineering, Morphogenesis, lcsh:Science, 3_D gradient, Cells, Cultured, Microscopy, Multidisciplinary, Chemistry, Applied Mathematics, Physics, Chemotaxis, Cell migration, Chemotaxi, Chemical Engineering, Collagen, Research Article, Biotechnology, Cell type, Finite Element Analysis, Biophysics, Biomedical Engineering, Motility, Bioengineering, cells, collagen, Fluid Mechanics, Time-lapse microscopy, Humans, Biology, lcsh:R, Interleukin-8, Models, Theoretical, Immunology, Signal Processing, lcsh:Q, Mathematics, Chemotaxis assay, Developmental Biology

Abstract

Contains fulltext : 111018.pdf (Publisher’s version ) (Open Access) The directional cell response to chemical gradients, referred to as chemotaxis, plays an important role in physiological and pathological processes including development, immune response and tumor cell invasion. Despite such implications, chemotaxis remains a challenging process to study under physiologically-relevant conditions in-vitro, mainly due to difficulties in generating a well characterized and sustained gradient in substrata mimicking the in-vivo environment while allowing dynamic cell imaging. Here, we describe a novel chemotaxis assay in 3D collagen gels, based on a reusable direct-viewing chamber in which a chemoattractant gradient is generated by diffusion through a porous membrane. The diffusion process has been analysed by monitoring the concentration of FITC-labelled dextran through epifluorescence microscopy and by comparing experimental data with theoretical and numerical predictions based on Fick's law. Cell migration towards chemoattractant gradients has been followed by time-lapse microscopy and quantified by cell tracking based on image analysis techniques. The results are expressed in terms of chemotactic index (I) and average cell velocity. The assay has been tested by comparing the migration of human neutrophils in isotropic conditions and in the presence of an Interleukin-8 (IL-8) gradient. In the absence of IL-8 stimulation, 80% of the cells showed a velocity ranging from 0 to 1 microm/min. However, in the presence of an IL-8 gradient, 60% of the cells showed an increase in velocity reaching values between 2 and 7 microm/min. Furthermore, after IL-8 addition, I increased from 0 to 0.25 and 0.25 to 0.5, respectively, for the two donors examined. These data indicate a pronounced directional migration of neutrophils towards the IL-8 gradient in 3D collagen matrix. The chemotaxis assay described here can be adapted to other cell types and may serve as a physiologically relevant method to study the directed locomotion of cells in a 3D environment in response to different chemoattractants.

Published

2012

29. Microfluidics analysis of red blood cell membrane viscoelasticity

Author

Stefano Guido, Antonio Cassinese, Valentina Preziosi, Giovanna Tomaiuolo, Mario Barra, Bruno Rotoli, Tomaiuolo, Giovanna, M., Barra, Preziosi, Valentina, Cassinese, Antonio, B., Rotoli, and Guido, Stefano

Subjects

Work (thermodynamics), Erythrocytes, Microfluidics, microfluidic, Biomedical Engineering, Bioengineering, Nanotechnology, red blood cell, Biochemistry, Viscoelasticity, Cell membrane, Viscosity, medicine, Humans, Dimethylpolysiloxanes, membrane, viscoelasticity, Cell Size, Pressure drop, Chemistry, Microcirculation, General Chemistry, Mechanics, Microfluidic Analytical Techniques, Blood Viscosity, Elasticity, Red blood cell, Nylons, medicine.anatomical_structure, Membrane

Abstract

In this work, a microfluidic system to investigate the flow behavior of red blood cells in a microcirculation-mimicking network of PDMS microchannels with thickness comparable to cell size is presented. We provide the first quantitative description of cell velocity and shape as a function of the applied pressure drop in such devices. Based on these results, a novel methodology to measure cell membrane viscoelastic properties in converging/diverging flow is developed, and the results are in good agreement with data from the literature. In particular, in the diverging channel the effect of RBC surface viscosity is dominant with respect to shear elasticity. Possible applications include measurements of cell deformability in pathological samples, where reliable methods are still lacking.

Published

2010

30. A methodology to study the deformability of red blood cells flowing in microcapillaries in vitro

Author

Giovanna, Tomaiuolo, Valentina, Preziosi, Marino, Simeone, Stefano, Guido, Rosanna, Ciancia, Vincenzo, Martinelli, Ciro, Rinaldi, and Bruno, Rotoli

Subjects

Erythrocytes, Microscopy, Video, Erythrocyte Deformability, Hemorheology, Image Interpretation, Computer-Assisted, beta-Thalassemia, Humans, Blood Flow Velocity, Capillaries, Cell Size

Abstract

The deformability of red blood cells flowing in microvessels is essential to maintain optimal blood circulation and to allow gas transfer between blood and tissues. Here, we report on an experimental methodology to investigate the deformability of RBCs flowing in microcapillaries having diameter close to the average cell size. The microcapillaries are placed in a rectangular flow cell, where a suspension of RBCs, properly diluted in albumin-additioned ACD, is fed through a syringe under the action of a liquid head in the physiological range. Video microscopy images of the flowing RBCs are acquired at high magnification and later processed by an automated image analysis macro. It was found that RBCs from healthy donors exhibit the classical parachute shape observed in vivo. Furthermore, all the data of healthy RBC velocity vs liquid head are well represented by the same linear regression, independently on the donor. Preliminary results on beta-thalassemia RBCs are also presented and show, on the average, a reduced velocity compared to healthy samples.

Published

2007

31. A methodology to study the deformability of red blood cells flowing in microcapillaries in vitro

Author

Tomaiuolo, G., Valentina Preziosi, Simeone, M., Guido, S., Ciancia, R., Martinelli, V., Rinaldi, C., Rotoli, B., Tomaiuolo, G., Preziosi, V., Simeone, M., Guido, S., Ciancia, R., Rinaldi, C., Martinelli, V., and Rotoli, B.

Subjects

capillarie, erythrocyte deformability, thalassemia, microfluidic, erythrocyte

Abstract

The deformability of red blood cells flowing in microvessels is essential to maintain optimal blood circulation and to allow gas transfer between blood and tissues. Here, we report on an experimental methodology to investigate the deformability of RBCs flowing in microcapillaries having diameter close to the average cell size. The microcapillaries are placed in a rectangular flow cell, where a suspension of RBCs, isolated by centrifugation and properly diluted in albumin-additioned AC D, is fed through a syringe under the action of a liquid head in the physiological range. Video microscopy images of the flowing RBCs are acquired at high magnification and later processed by an automated image analysis macro. It was found that RBCs from healthy donors exhibit the classical parachute shape observed in vivo. Furthermore, all the data of healthy RBC velocity vs liquid head are well represented by the same linear regression, indipendently on the donor. Preliminary results on β-thalassemia RBCs are also presented and show, on the average, a reduced velocity compared to healthy samples.