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38 results on '"Frascella, F."'

5. Microwave-assisted methacrylation of chitosan for 3D printable hydrogels in tissue engineering

Author

Zanon, M., Chiappone, A., Garino, N., Canta, M., Frascella, F., Hakkarainen, Minna, Pirri, C. F., Sangermano, M., Zanon, M., Chiappone, A., Garino, N., Canta, M., Frascella, F., Hakkarainen, Minna, Pirri, C. F., and Sangermano, M.

Abstract

Light processable natural polymers are highly attractive for 3D printing of biomedical hydrogels with defined geometries and sizes. However, functionalization with photo-curable groups, such as methacrylate or acrylate groups, is required. Here, we investigated a microwave-assisted process for methacrylation of chitosan to replace conventional methacrylation processes that can be time consuming and tedious. The microwave-assisted methacrylation reaction was optimized by varying the synthesis parameters such as the molar ratio of chitosan to the methacrylic agent, the launch and reaction times and process temperature. The optimized process was fast and efficient and allowed tuning of the degree of substitution and thereby the final hydrogel properties. The successful methacrylation and degree of substitution were verified by 1H NMR and attenuated total reflectance-Fourier transform infrared spectroscopy (ATR-FTIR). The influence of the degree of methacrylation on photo-rheology, mechanical stiffness, swelling degree and gel content was evaluated. Furthermore, favourable 3D printability, enzymatic degradability, biocompatibility, cell migration and proliferation were demonstrated giving promise for further applications in tissue engineering., QC 20230615

Published
2022
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6. Tailored and Guided Dewetting of Block Copolymer/Homopolymer Blends

Author

Ferrarese Lupi, F., primary, Murataj, I., additional, Celegato, F., additional, Angelini, A., additional, Frascella, F., additional, Chiarcos, R., additional, Antonioli, D., additional, Gianotti, V., additional, Tiberto, P., additional, Pirri, C. F., additional, Boarino, L., additional, and Laus, M., additional

Published
2020
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8. Three-Dimensional Printed Photoluminescent Polymeric Waveguides

Author

Frascella, F., González, G., Bosch, Paula, Angelini, A., Chiappone, A., Sangermano, M., Pirri, C.F., Roppolo, I., Frascella, F., González, G., Bosch, Paula, Angelini, A., Chiappone, A., Sangermano, M., Pirri, C.F., and Roppolo, I.

Abstract

In this work, we propose an innovative strategy for obtaining functional objects employing a light-activated three-dimensional (3D) printing process without affecting the materials' printability. In particular, a dye is a necessary ingredient in a formulation for a digital light processing 3D printing method to obtain precise and complex structures. Here, we use a photoluminescent dye specifically synthesized for this purpose that enables the production of 3D printed waveguides and splitters able to guide the luminescence. Moreover, copolymerizing the dye with the polymeric network during the printing process, we are able to maintain the solvatochromic properties of the dye toward different solvents in the printed structures, enabling the development of solvents' polarity sensors.

Published
2018

12. 3D printable light-responsive polymers

Author

Roppolo, I., primary, Chiappone, A., additional, Angelini, A., additional, Stassi, S., additional, Frascella, F., additional, Pirri, C. F., additional, Ricciardi, C., additional, and Descrovi, E., additional

Published
2017
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13. Phase-sentitive bloch surface wave biosensors

Author

Sinibaldi, A., primary, Anopchenko, A., additional, Rizzo, R., additional, Michelotti, F., additional, Danz, N., additional, Munzert, P., additional, Rivolo, P., additional, Ricciardi, S., additional, and Frascella, F., additional

Published
2015
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17. Enhanced fluorescence detection of miRNA-16 on a photonic crystal.

Author

Frascella, F., Ricciardi, S., Pasquardini, L., Potrich, C., Angelini, A., Chiadò, A., Pederzolli, C., De Leo, N., Rivolo, P., Pirri, C. F., and Descrovi, E.

Subjects
*MICRORNA, *FLUORESCENCE, *PHOTONIC crystals, *DIELECTRICS, *MICROARRAY technology, *BIOLOGICAL assay
Abstract

We report a novel sensing method for fluorescence-labelled microRNAs (miRNAs) spotted on an all-dielectric photonic structure. Such a photonic structure provides an enhanced excitation and a directional beaming of the emitted fluorescence, resulting in a significant improvement of the overall signal collected. As a result, the Limit of Detection (LoD) is demonstrated to decrease by a factor of about 50. A compact read-out system allows a wide-field imaging-based detection, with little or no optical alignment issues, which makes this approach particularly interesting for further development for example in microarray-type bioassays. [ABSTRACT FROM AUTHOR]

Published
2015
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19. Vat Photopolymerization 3D Printing of Hydrogels Embedding Metal-Organic Frameworks for Photodynamic Antimicrobial Therapy.

Author

Wang Y, Frascella F, Gaglio CG, Pirri CF, Wei Q, and Roppolo I

Subjects
Humans, Gelatin chemistry, Polymerization, Methacrylates chemistry, Methacrylates pharmacology, Microbial Sensitivity Tests, Animals, Metal-Organic Frameworks chemistry, Metal-Organic Frameworks pharmacology, Printing, Three-Dimensional, Staphylococcus aureus drug effects, Hydrogels chemistry, Hydrogels pharmacology, Escherichia coli drug effects, Anti-Bacterial Agents pharmacology, Anti-Bacterial Agents chemistry, Photochemotherapy
Abstract

Given the variability in wounds based on the underlying causes, personalized medicine and tailored care for patients with wounds are required to ensure optimal therapeutic outcomes. With the emergence of high-precision and high-efficiency photocuring 3D printing technology, there is the potential for its use in customizing precise shapes that can match complex wound sites, thereby providing better treatment for patients with wound infections. In this work, porphyrinic metal-organic framework (MOF) crystals, serving as the functional filler, were incorporated into gelatin methacrylate (GelMA) as a photocurable composite resin to investigate the capabilities of producing customizable wound dressings through vat photopolymerization 3D printing. The embedded MOF crystals allow for better control of the photopolymerization process due to photon competition with the photoinitiator, enabling the precise printing of complex structures. In addition, these crystals impart photothermal and photodynamic capabilities to the printed object. The antibacterial assay confirms the potent photothermal and photodynamic bactericidal properties of the printed GelMA/MOF hydrogels. The hydrogel with the highest MOF content exhibited over 99.99% antibacterial efficiency against both Gram-positive Staphylococcus aureus and Gram-negative Escherichia coli after 30 min of light exposure (∼30 mW/cm 2 , λ ≥ 420 nm). Simultaneously, hemolysis and cytotoxicity evaluations validated their excellent biocompatibility. The findings presented here introduce a strategy for integrating photosensitive MOF and 3D printing to fabricate size-adjustable photothermal/photodynamic monoliths and patches, opening perspectives toward personalized treatment for wound management.

Published
2024
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20. Differential Anti-Inflammatory Effects of Electrostimulation in a Standardized Setting.

Author

Di Pietro B, Villata S, Dal Monego S, Degasperi M, Ghini V, Guarnieri T, Plaksienko A, Liu Y, Pecchioli V, Manni L, Tenori L, Licastro D, Angelini C, Napione L, Frascella F, and Nardini C

Subjects
Humans, Tumor Necrosis Factor-alpha metabolism, Anti-Inflammatory Agents pharmacology, Electric Stimulation Therapy methods, Metabolomics methods, Collagen metabolism, Electric Stimulation methods, Wound Healing, Inflammation metabolism, Inflammation therapy, Fibroblasts metabolism, Keratinocytes metabolism
Abstract

The therapeutic usage of physical stimuli is framed in a highly heterogeneous research area, with variable levels of maturity and of translatability into clinical application. In particular, electrostimulation is deeply studied for its application on the autonomous nervous system, but less is known about the anti- inflammatory effects of such stimuli beyond the inflammatory reflex . Further, reproducibility and meta-analyses are extremely challenging, owing to the limited rationale on dosage and experimental standardization. It is specifically to address the fundamental question on the anti-inflammatory effects of electricity on biological systems, that we propose a series of controlled experiments on the effects of direct and alternate current delivered on a standardized 3D bioconstruct constituted by fibroblasts and keratinocytes in a collagen matrix, in the presence or absence of TNF-α as conventional inflammation inducer. This selected but systematic exploration, with transcriptomics backed by metabolomics at specific time points allows to obtain the first systemic overview of the biological functions at stake, highlighting the differential anti-inflammatory potential of such approaches, with promising results for 5 V direct current stimuli, correlating with the wound healing process. With our results, we wish to set the base for a rigorous systematic approach to the problem, fundamental towards future elucidations of the detailed mechanisms at stake, highlighting both the healing and damaging potential of such approaches.

Published
2024
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21. Innovative Detection of Biomarkers Based on Chemiluminescent Nanoparticles and a Lensless Optical Sensor.

Author

Potrich C, Palmara G, Frascella F, Pancheri L, and Lunelli L

Subjects
Humans, Luminescent Measurements, C-Reactive Protein analysis, Horseradish Peroxidase, Limit of Detection, Biosensing Techniques, Biomarkers analysis, Gold chemistry, Metal Nanoparticles chemistry
Abstract

The identification and quantification of biomarkers with innovative technologies is an urgent need for the precise diagnosis and follow up of human diseases. Body fluids offer a variety of informative biomarkers, which are traditionally measured with time-consuming and expensive methods. In this context, lateral flow tests (LFTs) represent a rapid and low-cost technology with a sensitivity that is potentially improvable by chemiluminescence biosensing. Here, an LFT based on gold nanoparticles functionalized with antibodies labeled with the enzyme horseradish peroxidase is combined with a lensless biosensor. This biosensor comprises four Silicon Photomultipliers (SiPM) coupled in close proximity to the LFT strip. Microfluidics for liquid handling complete the system. The development and the setup of the biosensor is carefully described and characterized. C-reactive protein was selected as a proof-of-concept biomarker to define the limit of detection, which resulted in about 0.8 pM when gold nanoparticles were used. The rapid readout (less than 5 min) and the absence of sample preparation make this biosensor promising for the direct and fast detection of human biomarkers.

Published
2024
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22. GelMA synthesis and sources comparison for 3D multimaterial bioprinting.

Author

Gaglio CG, Baruffaldi D, Pirri CF, Napione L, and Frascella F

Abstract

Gelatin Methacryloyl (GelMA) is one of the most used biomaterials for a wide range of applications, such as drug delivery, disease modeling and tissue regeneration. GelMA is obtained from gelatin, which can be derived from different sources (e.g., bovine skin, and porcine skin), through substitution of reactive amine and hydroxyl groups with methacrylic anhydride (MAA). The degree of functionalization (DoF) can be tuned by varying the MAA amount used; thus, different protocols, with different reaction efficiency, have been developed, using various alkaline buffers (e.g., phosphate-buffered saline, DPBS, or carbonate-bicarbonate solution). Obviously, DoF modulation has an impact on the final GelMA properties, so a deep investigation on the features of the obtained hydrogel must be carried on. The purpose of this study is to investigate how different gelatin sources and synthesis methods affect GelMA properties, as literature lacks direct and systematic comparisons between these parameters, especially between synthesis methods. The final aim is to facilitate the choice of the source or synthesis method according to the needs of the desired application. Hence, chemical and physical properties of GelMA formulations were assessed, determining the DoFs, mechanical and viscoelastic properties by rheological analysis, water absorption by swelling capacity and enzymatic degradation rates. Biological tests with lung adenocarcinoma cells (A549) were performed. Moreover, since 3D bioprinting is a rapidly evolving technology thanks to the possibility of precise deposition of cell-laden biomaterials (bioinks) to mimic the 3D structures of several tissues, the potential of different GelMA formulations as bioinks have been tested with a multi-material approach, revealing its printability and versatility in various applications., Competing Interests: The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest., (Copyright © 2024 Gaglio, Baruffaldi, Pirri, Napione and Frascella.)

Published
2024
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23. Pumpless deterministic lateral displacement separation using a paper capillary wick.

Author

Aghajanloo B, Ejeian F, Frascella F, Marasso SL, Cocuzza M, Tehrani AF, Nasr Esfahani MH, and Inglis DW

Abstract

Deterministic lateral displacement (DLD) is a passive separation method that separates particles by hydrodynamic size. This label-free method is a promising technique for cell separation because of its high size resolution and insensitivity to flow rate. Development of capillary-driven microfluidic technologies allows microfluidic devices to be operated without any external power for fluid pumping, lowering their total cost and complexity. Herein, we develop and test a DLD-based particle and cell sorting method that is driven entirely by capillary pressure. We show microchip self-filling, flow focusing, flow stability, and capture of separated particles. We achieve separation efficiency of 92% for particle-particle separation and more than 99% efficiency for cell-particle separation. The high performance of driven flow and separation along with simplicity of the operation and setup make it a valuable candidate for point-of-care devices.

Published
2023
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24. 3D printable acrylate polydimethylsiloxane resins for cell culture and drug testing.

Author

Villata S, Canta M, Baruffaldi D, Pavan A, Chiappone A, Pirri CF, Frascella F, and Roppolo I

Subjects
Lab-On-A-Chip Devices, Printing, Three-Dimensional, Dimethylpolysiloxanes, Cell Culture Techniques, Microfluidics
Abstract

Nowadays, most of the microfluidic devices for biological applications are fabricated with only few well-established materials. Among these, polydimethylsiloxane (PDMS) is the most used and known. However, it has many limitations, like the operator dependent and time-consuming manufacturing technique and the high molecule retention. TEGORad or Acrylate PDMS is an acrylate polydimethylsiloxane copolymer that can be 3D printed through Digital Light Processing (DLP), a technology that can boast reduction of waste products and the possibility of low cost and rapid manufacturing of complex components. Here, we developed 3D printed Acrylate PDMS-based devices for cell culture and drug testing. Our in vitro study shows that Acrylate PDMS can sustain cell growth of lung and skin epithelium, both of great interest for in vitro drug testing, without causing any genotoxic effect. Moreover, flow experiments with a drug-like solution (Rhodamine 6G) show that Acrylate PDMS drug retention is negligible unlike the high signal shown by PDMS. In conclusion, the study demonstrates that this acrylate resin can be an excellent alternative to PDMS to design stretchable platforms for cell culture and drug testing.

Published
2023
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25. Human Blood Platelets Adsorption on Polymeric Materials for Liquid Biopsy.

Author

Potrich C, Frascella F, Bertana V, Barozzi M, Vanzetti L, Piccoli F, Cristallo AF, Malara N, Pirri CF, Pederzolli C, and Lunelli L

Subjects
Adsorption, Biocompatible Materials, Humans, Liquid Biopsy, Microscopy, Electron, Scanning, Polymers, Blood Platelets, Platelet Adhesiveness physiology
Abstract

Platelets are emerging as a promising source of blood biomarkers for several pathologies, including cancer. New automated techniques for easier manipulation of platelets in the context of lab-on-a-chips could be of great support for liquid biopsy. Here, several polymeric materials were investigated for their behavior in terms of adhesion and activation of human platelets. Polymeric materials were selected among the most used in microfabrication (PDMS, PMMA and COC) and commercial and home-made resins for 3D printing technology with the aim to identify the most suitable for the realization of microdevices for human platelets isolation and analysis. To visualize adherent platelets and their activation state scanning, electron microscopy was used, while confocal microscopy was used for evaluating platelets' features. In addition, atomic force microscopy was employed to further study platelets adherent to the polymeric materials. Polymers were divided in two main groups: the most prone to platelet adhesion and materials that cause few or no platelets to adhere. Therefore, different polymeric materials could be identified as suitable for the realization of microdevices aimed at capturing human platelets, while other materials could be employed for the fabrication of microdevices or parts of microdevices for the processing of platelets, without loss on surfaces during the process.

Published
2022
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26. Design of a Portable Microfluidic Platform for EGOT-Based in Liquid Biosensing.

Author

Segantini M, Parmeggiani M, Ballesio A, Palmara G, Frascella F, Marasso SL, and Cocuzza M

Subjects
Electrodes, Electrolytes, Transistors, Electronic, Biosensing Techniques, Microfluidics
Abstract

In biosensing applications, the exploitation of organic transistors gated via a liquid electrolyte has increased in the last years thanks to their enormous advantages in terms of sensitivity, low cost and power consumption. However, a practical aspect limiting the use of these devices in real applications is the contamination of the organic material, which represents an obstacle for the realization of a portable sensing platform based on electrolyte-gated organic transistors (EGOTs). In this work, a novel contamination-free microfluidic platform allowing differential measurements is presented and validated through finite element modeling simulations. The proposed design allows the exposure of the sensing electrode without contaminating the EGOT device during the whole sensing tests protocol. Furthermore, the platform is exploited to perform the detection of bovine serum albumin (BSA) as a validation test for the introduced differential protocol, demonstrating the capability to detect BSA at 1 pM concentration. The lack of contamination and the differential measurements provided in this work can be the first steps towards the realization of a reliable EGOT-based portable sensing instrument.

Published
2022
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27. 3D Cell Culture: Recent Development in Materials with Tunable Stiffness.

Author

Baruffaldi D, Palmara G, Pirri C, and Frascella F

Subjects
Biocompatible Materials chemical synthesis, Humans, Materials Testing, Particle Size, Stress, Mechanical, Biocompatible Materials chemistry, Cell Culture Techniques, Three Dimensional
Abstract

It is widely accepted that three-dimensional cell culture systems simulate physiological conditions better than traditional 2D systems. Although extracellular matrix components strongly modulate cell behavior, several studies underlined the importance of mechanosensing in the control of different cell functions such as growth, proliferation, differentiation, and migration. Human tissues are characterized by different degrees of stiffness, and various pathologies (e.g., tumor or fibrosis) cause changes in the mechanical properties through the alteration of the extracellular matrix structure. Additionally, these modifications have an impact on disease progression and on therapy response. Hence, the development of platforms whose stiffness could be modulated may improve our knowledge of cell behavior under different mechanical stress stimuli. In this review, we have analyzed the mechanical diversity of healthy and diseased tissues, and we have summarized recently developed materials with a wide range of stiffness.

Published
2021
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28. Functional 3D printing: Approaches and bioapplications.

Author

Palmara G, Frascella F, Roppolo I, Chiappone A, and Chiadò A

Subjects
Bioreactors, Microfluidics, Printing, Three-Dimensional, Temperature, Biosensing Techniques
Abstract

3D printing technology has become a mature manufacturing technique, widely used for its advantages over the traditional methods, such as the end-user customization and rapid prototyping, useful in different application fields, including the biomedical one. Indeed, it represents a helpful tool for the realization of biodevices (i.e. biosensors, microfluidic bioreactors, drug delivery systems and Lab-On-Chip). In this perspective, the development of 3D printable materials with intrinsic functionalities, through the so-called 4D printing, introduces novel opportunities for the fabrication of "smart" or stimuli-responsive devices. Indeed, functional 3D printable materials can modify their surfaces, structures, properties or even shape in response to specific stimuli (such as pressure, temperature or light radiation), adding to the printed object new interesting properties exploited after the fabrication process. In this context, by combining 3D printing technology with an accurate materials' design, functional 3D objects with built-in (bio)chemical functionalities, having biorecognition, biocatalytic and drug delivery capabilities are here reported., (Copyright © 2020. Published by Elsevier B.V.)

Published
2021
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29. Materials Testing for the Development of Biocompatible Devices through Vat-Polymerization 3D Printing.

Author

González G, Baruffaldi D, Martinengo C, Angelini A, Chiappone A, Roppolo I, Pirri CF, and Frascella F

Abstract

Light-based 3D printing techniques could be a valuable instrument in the development of customized and affordable biomedical devices, basically for high precision and high flexibility in terms of materials of these technologies. However, more studies related to the biocompatibility of the printed objects are required to expand the use of these techniques in the health sector. In this work, 3D printed polymeric parts are produced in lab conditions using a commercial Digital Light Processing (DLP) 3D printer and then successfully tested to fabricate components suitable for biological studies. For this purpose, different 3D printable formulations based on commercially available resins are compared. The biocompatibility of the 3D printed objects toward A549 cell line is investigated by adjusting the composition of the resins and optimizing post-printing protocols; those include washing in common solvents and UV post-curing treatments for removing unreacted and cytotoxic products. It is noteworthy that not only the selection of suitable materials but also the development of an adequate post-printing protocol is necessary for the development of biocompatible devices.

Published
2020
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30. Real-time and reversible light-actuated microfluidic channel squeezing in dye-doped PDMS.

Author

Angelini A, Agero U, Ferrarese Lupi F, Fretto M, Pirri F, and Frascella F

Abstract

The azobenzene chromophore is used as a functional dye for the development of smart microfluidic devices. A single layer microfluidic channel is produced, exploiting the potential of a dye doped PDMS formulation. The key advantage of this approach is the possibility to control the fluid flow by means of a simple light stimulus. Furthermore, the deformation can be controlled in time, space and intensity, giving rise to several degrees of freedom in the actuation of the channel squeezing. A future perspective will be the implementation of the microfluidic platform with structured light, to have the possibility to control the flow in a parallel and reversible manner at several points, modifying the pattern in real time.

Published
2020
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31. Laser-Triggered Writing and Biofunctionalization of Thiol-Ene Networks.

Author

Romano A, Angelini A, Rossegger E, Palmara G, Castellino M, Frascella F, Chiappone A, Chiadò A, Sangermano M, Schlögl S, and Roppolo I

Subjects
Biosensing Techniques, Esters chemistry, Light, Alkenes chemistry, Lasers, Sulfhydryl Compounds chemistry
Abstract

The light responsivity of ortho-nitrobenzyl esters (o-NBE) is exploited to inscribe µ-scale 2.5D patterns in thiol-ene networks by direct laser writing. For this purpose, a multifunctional thiol and a photosensitive alkene with an o-NBE chromophore are cured upon visible light exposure without inducing a premature photocleavage of the o-NBE links. Once the network is formed, a laser beam source with a wavelength of 375 nm is used for selectively inducing the photocleavage reaction of the o-NBE groups. Positive tone patterns are directly inscribed onto the sample surface without the requirement of a subsequent development step (removing soluble species in an appropriate organic solvent). Along with the realization of dry-developable micropatterns, the chemical surface composition of the exposed areas can be conveniently adjusted since different domains with a tailored content of carboxylic groups are obtained simply by modulating the laser energy dose. In a following step, those are activated and exploited as anchor points for attaching an Alexa-546 conjugated Protein A. Thus, the laser writable thiol-ene networks do not only provide a convenient method for the fabrication of positive tone patterns but also open future prospectives for a wide range of biosensing applications., (© 2020 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published
2020
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32. Electrospun Nanofibers: from Food to Energy by Engineered Electrodes in Microbial Fuel Cells.

Author

Massaglia G, Frascella F, Chiadò A, Sacco A, Marasso SL, Cocuzza M, Pirri CF, and Quaglio M

Abstract

Microbial fuel cells (MFCs) are bio-electrochemical devices able to directly transduce chemical energy, entrapped in an organic mass named fuel, into electrical energy through the metabolic activity of specific bacteria. During the last years, the employment of bio-electrochemical devices to study the wastewater derived from the food industry has attracted great interest from the scientific community. In the present work, we demonstrate the capability of exoelectrogenic bacteria used in MFCs to catalyze the oxidation reaction of honey, employed as a fuel. With the main aim to increase the proliferation of microorganisms onto the anode, engineered electrodes are proposed. Polymeric nanofibers, based on polyethylene oxide (PEO-NFs), were directly electrospun onto carbon-based material (carbon paper, CP) to obtain an optimized composite anode. The crucial role played by the CP/PEO-NFs anodes was confirmed by the increased proliferation of microorganisms compared to that reached on bare CP anodes, used as a reference material. A parameter named recovered energy (Erec) was introduced to determine the capability of bacteria to oxidize honey and was compared with the Erec obtained when sodium acetate was used as a fuel. CP/PEO-NFs anodes allowed achieving an Erec three times higher than the one reached with a bare carbon-based anode.

Published
2020
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33. A modular 3D printed lab-on-a-chip for early cancer detection.

Author

Chiadò A, Palmara G, Chiappone A, Tanzanu C, Pirri CF, Roppolo I, and Frascella F

Subjects
Angiopoietin-2 analysis, Biomarkers, Tumor analysis, Humans, Vascular Endothelial Growth Factors analysis, Early Detection of Cancer, Lab-On-A-Chip Devices, Neoplasms diagnostic imaging, Printing, Three-Dimensional
Abstract

A functional polymeric 3D device is produced in a single step printing process using a stereolithography based 3D printer. The photocurable formulation is designed for introducing a controlled amount of carboxyl groups (-COOH), in order to perform a covalent immobilization of bioreceptors on the device. The effectiveness of the application is demonstrated by performing an immunoassay for the detection of protein biomarkers involved in angiogenesis, whose role is crucial in the onset of cancer and in the progressive metastatic behavior of tumors. The detection of angiogenesis biomarkers is necessary for an early diagnosis of the pathology, allowing the employment of a less invasive therapy for the patient. In particular, vascular endothelial growth factor and angiopoietin-2 biomarkers are detected with a limit of detection of 11 ng mL -1 and 0.8 ng mL -1 , respectively. This study shows how 3D microfabrication techniques, material characterization, and device development could be combined to obtain an engineered polymeric chip with intrinsic tuned functionalities.

Published
2020
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34. Three-Dimensional Printed Photoluminescent Polymeric Waveguides.

Author

Frascella F, González G, Bosch P, Angelini A, Chiappone A, Sangermano M, Pirri CF, and Roppolo I

Abstract

In this work, we propose an innovative strategy for obtaining functional objects employing a light-activated three-dimensional (3D) printing process without affecting the materials' printability. In particular, a dye is a necessary ingredient in a formulation for a digital light processing 3D printing method to obtain precise and complex structures. Here, we use a photoluminescent dye specifically synthesized for this purpose that enables the production of 3D printed waveguides and splitters able to guide the luminescence. Moreover, copolymerizing the dye with the polymeric network during the printing process, we are able to maintain the solvatochromic properties of the dye toward different solvents in the printed structures, enabling the development of solvents' polarity sensors.

Published
2018
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35. Reconfigurable elastomeric graded-index optical elements controlled by light.

Author

Angelini A, Pirani F, Frascella F, and Descrovi E

Abstract

In many optical applications, there is an increasing need for dynamically tunable optical elements that are able to shape the wavefront of light 'on demand'. In this work, an elastomeric easy-to-fabricate optical element whose transmission functions can be reversibly phase configured by visible light is demonstrated. The light responsivity of proper azopolymers incorporated within an elastomeric matrix is exploited to induce a light-controlled graded refractive index (GRIN) distribution within the bulk compound. The induced refractive index distribution is continuous and conformal to the intensity profile of the illumination at moderate power. A 100 mW doubled-frequency Nd:YAG Gaussian beam focused to a 650 μm waist is shown to induce a maximum relative refractive index change of ~0.4% in the elastomeric matrix, with an approximately parabolic profile. The restoring characteristics of the elastomeric matrix enable full recovery of the initial homogeneous refractive index distribution within a few seconds when the incident laser is switched off. As an exemplary application, the configurable GRIN element is used in a microscope-based imaging system for light control of the effective focal length., Competing Interests: The authors declare that they have no conflict of interest.

Published
2018
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36. Light-Driven Reversible Shaping of Individual Azopolymeric Micro-Pillars.

Author

Pirani F, Angelini A, Frascella F, Rizzo R, Ricciardi S, and Descrovi E

Abstract

Azopolymers are known to exhibit a strong light responsivity known as athermal photofluidization. Although the underlying physics is still under debate, athermal photofluidization has been demonstrated to trigger mass-migration according to the polarization of a proper illumination light. Here, a polymer blend is proposed wherein a commercial azo-polyelectrolyte is mixed with a passive polymer. The blend is patterned as an array of micro-pillars that are individually exposed to visible laser illumination. Thanks to the interplay between the two blend components, a reversible and controlled deformation of the micro-pillars by periodically tuning the laser polarization in time is demonstrated. A reduced mobility of the azo-compound allows to repeatibly elongate and rotate micro-pillars along specific directions, with no significant material flow outisde the initial volume and no significant degradation of the structure morphology over several cycles. The proposed work suggests new degrees of freedom in controlling the mechanical features of micro-patterned light-responsive materials that can be usefully exploited in many application fields.

Published
2016
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37. Optimization and characterization of a homogeneous carboxylic surface functionalization for silicon-based biosensing.

Author

Chiadò A, Palmara G, Ricciardi S, Frascella F, Castellino M, Tortello M, Ricciardi C, and Rivolo P

Subjects
Glutaral chemistry, Microscopy, Atomic Force, Photoelectron Spectroscopy, Polymethacrylic Acids chemistry, Reproducibility of Results, Silanes chemistry, Succinic Anhydrides chemistry, Surface Properties, Biosensing Techniques instrumentation, Biosensing Techniques methods, Carboxylic Acids chemistry, Silicon chemistry
Abstract

A well-organized immobilization of bio-receptors is a crucial goal in biosensing, especially to achieve high reproducibility, sensitivity and specificity. These requirements are usually attained with a controlled chemical/biochemical functionalization that creates a stable layer on a sensor surface. In this work, a chemical modification protocol for silicon-based surfaces to be applied in biosensing devices is presented. An anhydrous silanization step through 3-aminopropylsilane (APTES), followed by a further derivatization with succinic anhydride (SA), is optimized to generate an ordered flat layer of carboxylic groups. The properties of APTES/SA modified surface were compared with a functionalization in which glutaraldehyde (GA) is used as crosslinker instead of SA, in order to have a comparison with an established and largely applied procedure. Moreover, a functionalization based on the controlled deposition of a plasma polymerized acrylic acid (PPAA) thin film was used as a reference for carboxylic reactivity. Advantages and drawbacks of the considered methods are highlighted, through physico-chemical characterizations (OCA, XPS, and AFM) and by means of a functional Protein G/Antibody immunoassay. These analyses reveal that the most homogeneous, reproducible and active surface is achieved by using the optimized APTES/SA coupling., (Copyright © 2016 Elsevier B.V. All rights reserved.)

Published
2016
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38. Angularly resolved ellipsometric optical biosensing by means of Bloch surface waves.

Author

Sinibaldi A, Anopchenko A, Rizzo R, Danz N, Munzert P, Rivolo P, Frascella F, Ricciardi S, and Michelotti F

Subjects
Angiopoietin-2 chemistry, Angiopoietin-2 immunology, Animals, Antibodies, Biomarkers, Tumor, Humans, Lasers, Mice, Optics and Photonics, Recombinant Proteins chemistry, Recombinant Proteins immunology, Refractometry, Biosensing Techniques instrumentation, Biosensing Techniques methods, Optical Imaging instrumentation, Optical Imaging methods
Abstract

In label-free biosensing, a continuous improvement of the limit of detection is necessary to resolve the small change of the surface refractive index produced by interacting biomolecules at a very small concentration. In the present work, optical sensors based on one-dimensional photonic crystals supporting Bloch surface waves are proposed and adopted for label-free optical biosensing. We describe the implementation of an angularly resolved ellipsometric optical sensing scheme based on Bloch surface waves sustained by tantala/silica multilayers. The angular operation is obtained using a focused beam at fixed wavelength and detection of the angular reflectance spectrum by means of an array detector. The results show that the experimental limit of detection for a particular photonic crystal design is 6.5 × 10(-7) refractive index units (RIU)/Hz(1/2) and further decrease could be obtained. For the first time, we report on the practical application of this technique to a cancer biomarker protocol that aims at the detection of a specific glycoprotein (angiopoietin 2) involved in angiogenesis and inflammation processes.

Published
2015
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