Your search keyword '"Paper-based substrates"' showing total 13 results

1. Paper-based plasmonic substrates as surface-enhanced Raman scattering spectroscopy platforms for cell culture applications

Author

J.M. Romo-Herrera, K. Juarez-Moreno, L. Guerrini, Y. Kang, N. Feliu, W.J. Parak, and R.A. Alvarez-Puebla

Subjects

Plasmonic nanoparticles, Paper-based substrates, SERS, Cell culture, Plasmonic papers, Medicine (General), R5-920, Biology (General), QH301-705.5

Abstract

The engineering of advanced materials capable of mimicking the cellular micro-environment while providing cells with physicochemical cues is central for cell culture applications. In this regard, paper meets key requirements in terms of biocompatibility, hydrophilicity, porosity, mechanical strength, ease of physicochemical modifications, cost, and ease of large-scale production, to be used as a scaffold material for biomedical applications. Most notably, paper has demonstrated the potential to become an attractive alternative to conventional biomaterials for creating two-dimensional (2D) and three-dimensional (3D) biomimetic cell culture models that mimic the features of in vivo tissue environments for improving our understanding of cell behavior (e.g. growth, cell migration, proliferation, differentiation and tumor metastasis) in their natural state. On the other hand, integration of plasmonic nanomaterials (e.g. gold nanoparticles) within the fibrous structure of paper opens the possibility to generate multifunctional scaffolds equipped with biosensing tools for monitoring different cell cues through physicochemical signals. Among different plasmonic based detection techniques, surface-enhanced Raman scattering (SERS) spectroscopy emerged as a highly specific and sensitive optical tool for its extraordinary sensitivity and the ability for multidimensional and accurate molecular identification. Thus, paper-based plasmonic substrates in combination with SERS optical detection represent a powerful future platform for monitoring cell cues during cell culture processes. To this end, in this review, we will describe the different methods for fabricating hybrid paper-plasmonic nanoparticle substrates and their use in combination with SERS spectroscopy for biosensing and, more specifically, in cell culture applications.

Published

2021

2. Dimension Confinement Effect Boosted Ultrasensitive Colorimetric Signal Concentrating.

Author

Wang, Peixian, Cai, Zhenzhen, Li, Jiguang, Li, Yushu, Zu, Baiyi, and Dou, Xincun

Subjects

*POLYVINYL alcohol, *HYDROXYL group, *FILTER paper, *NETWORK performance, *POTASSIUM

Abstract

To understand the underlying fundamental mechanism affecting the optical sensitivity of a paper‐based substrate, a layered polyvinyl alcohol (PVA) network paper is proposed considering the physical geometry and chemical composition required to enhance the sensitivity. It is verified both theoretically and experimentally that the dimension confinement effect introduced by the Steiner network, layered and pore structures, as well as massive hydroxyl groups, play an essential role in enhancing the concentration signal on the surface. Trace chlorate droplets and particles are considered representative examples to prove the excellent structural design‐induced performance of the PVA network paper. A practical mass detection from potassium chlorate solution and particles could be as low as 9.9 pg and 0.34 fg, respectively, and the corresponding naked‐eye observation limit could reach 0.69 ng and 1.6 pg, respectively, assuming the distinguishable size for human eyes is 100 µm. Further, the detection time could be far less than 2 s, which is remarkably superior than the detection performance of the parallel filter paper counterpart. The dimension confinement effect demonstrated here is expected to be of great importance for advancing the development of paper‐based trace detection. [ABSTRACT FROM AUTHOR]

Published

2020

3. Communication and Sensing Circuits on Cellulose

Author

Federico Alimenti, Chiara Mariotti, Valentina Palazzi, Marco Virili, Giulia Orecchini, Paolo Mezzanotte, and Luca Roselli

Subjects

circuits on cellulose, paper-based substrates, green electronics, all-natural electronic, wireless sensors, Internet of Things (IoT), Applications of electric power, TK4001-4102

Abstract

This paper proposes a review of several circuits for communication and wireless sensing applications implemented on cellulose-based materials. These circuits have been developed during the last years exploiting the adhesive copper laminate method. Such a technique relies on a copper adhesive tape that is shaped by a photo-lithographic process and then transferred to the hosting substrate (i.e., paper) by means of a sacrificial layer. The presented circuits span from UHF oscillators to a mixer working at 24 GHz and constitute an almost complete set of building blocks that can be applied to a huge variety communication apparatuses. Each circuit is validated experimentally showing performance comparable with the state-of-the-art. This paper demonstrates that circuits on cellulose are capable of operating at record frequencies and that ultra- low cost, green i.e., recyclable and biodegradable) materials can be a viable solution to realize high frequency hardware for the upcoming Internet of Things (IoT) era.

Published

2015

4. A 24-GHz Front-End Integrated on a Multilayer Cellulose-Based Substrate for Doppler Radar Sensors.

Author

Alimenti, Federico, Palazzi, Valentina, Mariotti, Chiara, Virili, Marco, Orecchini, Giulia, Bonafoni, Stefania, Roselli, Luca, and Mezzanotte, Paolo

Abstract

This paper presents a miniaturized Doppler radar that can be used as a motion sensor for low-cost Internet of things (IoT) applications. For the first time, a radar front-end and its antenna are integrated on a multilayer cellulose-based substrate, built-up by alternating paper, glue and metal layers. The circuit exploits a distributed microstrip structure that is realized using a copper adhesive laminate, so as to obtain a low-loss conductor. The radar operates at 24 GHz and transmits 5 mW of power. The antenna has a gain of 7.4 dBi and features a half power beam-width of 48 degrees. The sensor, that is just the size of a stamp, is able to detect the movement of a walking person up to 10 m in distance, while a minimum speed of 50 mm/s up to 3 m is clearly measured. Beyond this specific result, the present paper demonstrates that the attractive features of cellulose, including ultra-low cost and eco-friendliness (i.e., recyclability and biodegradability), can even be exploited for the realization of future high-frequency hardware. This opens opens the door to the implementation on cellulose of devices and systems which make up the “sensing layer” at the base of the IoT ecosystem. [ABSTRACT FROM AUTHOR]

Published

2017

5. Paper-based plasmonic substrates as surface-enhanced Raman scattering spectroscopy platforms for cell culture applications

Author

Universitat Rovira i Virgili, Romo-Herrera, J. M.; Juarez-Moreno, K.; Guerrini, L.; Kang, Y.; Feliu, N.; Parak, W. J.; Alvarez-Puebla, R. A., Universitat Rovira i Virgili, and Romo-Herrera, J. M.; Juarez-Moreno, K.; Guerrini, L.; Kang, Y.; Feliu, N.; Parak, W. J.; Alvarez-Puebla, R. A.

Abstract

The engineering of advanced materials capable of mimicking the cellular micro-environment while providing cells with physicochemical cues is central for cell culture applications. In this regard, paper meets key requirements in terms of biocompatibility, hydrophilicity, porosity, mechanical strength, ease of physicochemical modifications, cost, and ease of large-scale production, to be used as a scaffold material for biomedical applications. Most notably, paper has demonstrated the potential to become an attractive alternative to conventional biomaterials for creating two-dimensional (2D) and three-dimensional (3D) biomimetic cell culture models that mimic the features of in vivo tissue environments for improving our understanding of cell behavior (e.g. growth, cell migration, proliferation, differentiation and tumor metastasis) in their natural state. On the other hand, integration of plasmonic nanomaterials (e.g. gold nanoparticles) within the fibrous structure of paper opens the possibility to generate multifunctional scaffolds equipped with biosensing tools for monitoring different cell cues through physicochemical signals. Among different plasmonic based detection techniques, surface-enhanced Raman scattering (SERS) spectroscopy emerged as a highly specific and sensitive optical tool for its extraordinary sensitivity and the ability for multidimensional and accurate molecular identification. Thus, paper-based plasmonic substrates in combination with SERS optical detection represent a powerful future platform for monitoring cell cues during cell culture processes. To this end, in this review, we will describe the different methods for fabricating hybrid paper-plasmonic nanoparticle substrates and their use in combination with SERS spectroscopy for biosensing and, mo

Published

2021

6. A 24-GHz Front-End Integrated on a Multilayer Cellulose-Based Substrate for Doppler Radar Sensors

Author

Federico Alimenti, Valentina Palazzi, Chiara Mariotti, Marco Virili, Giulia Orecchini, Stefania Bonafoni, Luca Roselli, and Paolo Mezzanotte

Subjects

Doppler radar sensors, green electronics, all-natural electronic, circuits on cellulose, paper-based substrates, flexible substrates, substrate integrated circuits, Internet of things (IoT), Chemical technology, TP1-1185

Abstract

This paper presents a miniaturized Doppler radar that can be used as a motion sensor for low-cost Internet of things (IoT) applications. For the first time, a radar front-end and its antenna are integrated on a multilayer cellulose-based substrate, built-up by alternating paper, glue and metal layers. The circuit exploits a distributed microstrip structure that is realized using a copper adhesive laminate, so as to obtain a low-loss conductor. The radar operates at 24 GHz and transmits 5 mW of power. The antenna has a gain of 7.4 dBi and features a half power beam-width of 48 degrees. The sensor, that is just the size of a stamp, is able to detect the movement of a walking person up to 10 m in distance, while a minimum speed of 50 mm/s up to 3 m is clearly measured. Beyond this specific result, the present paper demonstrates that the attractive features of cellulose, including ultra-low cost and eco-friendliness (i.e., recyclability and biodegradability), can even be exploited for the realization of future high-frequency hardware. This opens opens the door to the implementation on cellulose of devices and systems which make up the “sensing layer” at the base of the IoT ecosystem.

Published

2017

7. Communication and Sensing Circuits on Cellulose.

Author

Alimenti, Federico, Mariotti, Chiara, Palazzi, Valentina, Virili, Marco, Orecchini, Giulia, Mezzanotte, Paolo, and Roselli, Luca

Subjects

DETECTOR circuits, GREEN electronics, INTERNET of things

Abstract

This paper proposes a review of several circuits for communication and wireless sensing applications implemented on cellulose-based materials. These circuits have been developed during the last years exploiting the adhesive copper laminate method. Such a technique relies on a copper adhesive tape that is shaped by a photo-lithographic process and then transferred to the hosting substrate (i.e., paper) by means of a sacrificial layer. The presented circuits span from UHF oscillators to a mixer working at 24 GHz and constitute an almost complete set of building blocks that can be applied to a huge variety communication apparatuses. Each circuit is validated experimentally showing performance comparable with the state-of-the-art. This paper demonstrates that circuits on cellulose are capable of operating at record frequencies and that ultra- low cost, green i.e., recyclable and biodegradable) materials can be a viable solution to realize high frequency hardware for the upcoming Internet of Things (IoT) era. [ABSTRACT FROM AUTHOR]

Published

2015

8. Paper-based plasmonic substrates as surface-enhanced Raman scattering spectroscopy platforms for cell culture applications

Author

L. Guerrini, Yanan Kang, K. Juarez-Moreno, José M. Romo-Herrera, R.A. Alvarez-Puebla, Wolfgang J. Parak, N. Feliu, and Publica

Subjects

Medicine (General), Materials science, Biocompatibility, QH301-705.5, Biomedical Engineering, Nanoparticle, Bioengineering, Nanotechnology, Review Article, Nanomaterials, Biomaterials, R5-920, Biology (General), Plasmonic nanoparticles, Molecular Biology, Plasmon, SERS, Paper-based substrates, Cell Biology, Plasmonic papers, Colloidal gold, Cell culture, Biosensor, Biotechnology

Abstract

The engineering of advanced materials capable of mimicking the cellular micro-environment while providing cells with physicochemical cues is central for cell culture applications. In this regard, paper meets key requirements in terms of biocompatibility, hydrophilicity, porosity, mechanical strength, ease of physicochemical modifications, cost, and ease of large-scale production, to be used as a scaffold material for biomedical applications. Most notably, paper has demonstrated the potential to become an attractive alternative to conventional biomaterials for creating two-dimensional (2D) and three-dimensional (3D) biomimetic cell culture models that mimic the features of in vivo tissue environments for improving our understanding of cell behavior (e.g. growth, cell migration, proliferation, differentiation and tumor metastasis) in their natural state. On the other hand, integration of plasmonic nanomaterials (e.g. gold nanoparticles) within the fibrous structure of paper opens the possibility to generate multifunctional scaffolds equipped with biosensing tools for monitoring different cell cues through physicochemical signals. Among different plasmonic based detection techniques, surface-enhanced Raman scattering (SERS) spectroscopy emerged as a highly specific and sensitive optical tool for its extraordinary sensitivity and the ability for multidimensional and accurate molecular identification. Thus, paper-based plasmonic substrates in combination with SERS optical detection represent a powerful future platform for monitoring cell cues during cell culture processes. To this end, in this review, we will describe the different methods for fabricating hybrid paper-plasmonic nanoparticle substrates and their use in combination with SERS spectroscopy for biosensing and, more specifically, in cell culture applications., Graphical abstract Image 1

Published

2021

9. Low-Power Frequency Doubler in Cellulose-Based Materials for Harmonic RFID Applications.

Author

Palazzi, Valentina, Alimenti, Federico, Mezzanotte, Paolo, Virili, Marco, Mariotti, Chiara, Orecchini, Giulia, and Roselli, Luca

Abstract

This letter presents the design of a Schottky diode frequency doubler suitable for harmonic RFID tags. A microwave frequency doubler is implemented in a cellulose-based (paper) substrate, i.e., an ultra-low cost, recyclable and biodegradable material. The circuit exploits a distributed microstrip structure that is fabricated using a copper adhesive laminate to have low conductor losses. The measurements show a conversion loss of 13.4 dB at the output frequency of 2.08 GHz. This is achieved with an available input power of -10 dBm only. Finally a harmonic RFID experiment proves a reading range of 50 cm, obtained by transmitting 0 dBm and receiving a second harmonic of -60 dBm, i.e., well above the sensitivity of a typical microwave receiver. [ABSTRACT FROM PUBLISHER]

Published

2014

10. Communication and Sensing Circuits on Cellulose

Author

Marco Virili, Luca Roselli, Chiara Mariotti, Federico Alimenti, Giulia Orecchini, Paolo Mezzanotte, and Valentina Palazzi

Subjects

IoT, Engineering, circuits on cellulose, Substrate (printing), Hardware_PERFORMANCEANDRELIABILITY, Span (engineering), all-natural electronic, chemistry.chemical_compound, Electronic engineering, Hardware_INTEGRATEDCIRCUITS, Wireless, Electrical and Electronic Engineering, Cellulose, Layer (object-oriented design), Electronic circuit, business.industry, electronic, Electrical engineering, Process (computing), lcsh:Applications of electric power, lcsh:TK4001-4102, internet of things, wireless sensors, Internet of Things (IoT), paper-based substrates, chemistry, green electronics, low power electronics, Internet of Things, business, circuits on cellulose, electronic, green electronics, internet of things, IoT, low power electronics, paper-based substrates, wireless sensors

Abstract

This paper proposes a review of several circuits for communication and wireless sensing applications implemented on cellulose-based materials. These circuits have been developed during the last years exploiting the adhesive copper laminate method. Such a technique relies on a copper adhesive tape that is shaped by a photo-lithographic process and then transferred to the hosting substrate (i.e., paper) by means of a sacrificial layer. The presented circuits span from UHF oscillators to a mixer working at 24 GHz and constitute an almost complete set of building blocks that can be applied to a huge variety communication apparatuses. Each circuit is validated experimentally showing performance comparable with the state-of-the-art. This paper demonstrates that circuits on cellulose are capable of operating at record frequencies and that ultra- low cost, green i.e., recyclable and biodegradable) materials can be a viable solution to realize high frequency hardware for the upcoming Internet of Things (IoT) era.

Published

2015

11. Paper-based plasmonic substrates as surface-enhanced Raman scattering spectroscopy platforms for cell culture applications.

Author

Romo-Herrera JM, Juarez-Moreno K, Guerrini L, Kang Y, Feliu N, Parak WJ, and Alvarez-Puebla RA

Abstract

The engineering of advanced materials capable of mimicking the cellular micro-environment while providing cells with physicochemical cues is central for cell culture applications. In this regard, paper meets key requirements in terms of biocompatibility, hydrophilicity, porosity, mechanical strength, ease of physicochemical modifications, cost, and ease of large-scale production, to be used as a scaffold material for biomedical applications. Most notably, paper has demonstrated the potential to become an attractive alternative to conventional biomaterials for creating two-dimensional (2D) and three-dimensional (3D) biomimetic cell culture models that mimic the features of in vivo tissue environments for improving our understanding of cell behavior (e.g. growth, cell migration, proliferation, differentiation and tumor metastasis) in their natural state. On the other hand, integration of plasmonic nanomaterials (e.g. gold nanoparticles) within the fibrous structure of paper opens the possibility to generate multifunctional scaffolds equipped with biosensing tools for monitoring different cell cues through physicochemical signals. Among different plasmonic based detection techniques, surface-enhanced Raman scattering (SERS) spectroscopy emerged as a highly specific and sensitive optical tool for its extraordinary sensitivity and the ability for multidimensional and accurate molecular identification. Thus, paper-based plasmonic substrates in combination with SERS optical detection represent a powerful future platform for monitoring cell cues during cell culture processes. To this end, in this review, we will describe the different methods for fabricating hybrid paper-plasmonic nanoparticle substrates and their use in combination with SERS spectroscopy for biosensing and, more specifically, in cell culture applications., Competing Interests: The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (© 2021 Published by Elsevier Ltd.)

Published

2021

12. Silicon thin film solar cells on paper-based substrates with applications in optoelectronic biodevices

Author

Vicente, António Miguel Teixeira, Martins, Rodrigo, and Águas, Hugo

Subjects

paper-based substrates, silicon solar cells, optoelectronics, transparent conductive oxides, PECVD, Engenharia e Tecnologia::Outras Engenharias e Tecnologias [Domínio/Área Científica], optimization

Abstract

As the effects of climate change continue to exacerbate, it is crucial to shift to renewable energies as our primary energy sources. Benefits go beyond curbing greenhouse gases emissions and have, for instance, positive impacts on human lives in terms of health, social stability, and energy security of countries. The present thesis explores silicon thin film solar cells (TFSC) as one possible answer to the increasing energy demand, particularly to be applied in the emerging and fast-growing field of paper-based devices, to power autonomous optoelectronic biosensors. Such devices tend to be recyclable, flexible, lightweight, and low-cost. For such applications to become a reality, this thesis explores optimization methodologies for key fabrication steps of silicon TFSCs to achieve a sustainable and energy efficient process, with reduced resource consumption, and compatible with temperature-sensitive paper-based substrates: Experimental design and statistical analysis were combined to develop a methodology to explore in a multidimensional fashion the interactions between fabrication parameters and experimental outputs. This optimization step of the layer structure of TFSC was performed on glass and lead to a device with a power conversion efficiency of 5.2%, FF ≈ 66%, JSC = 9 mA·cm-2, and VOC = 0.88 V. Transparent conductive oxides (TCOs) based on doped zinc oxides materials (AZO, AZO:H, GZO:H and ZnO:H) were optimized by post-deposition annealing methods. Results show that these materials, with resistivity < 4 × 10-4 Ω.cm, a high transmittance > 85%, can be cost-effective and sustainable alternatives to the industrial standard ITO. The combination of optimization processes led to a first-time report of the viability of fabricating silicon TFSC on paper-based substrates, by PECVD, with a power conversion efficiency of ~4.1%, FF ≈ 54%, JSC = 9.05 mA·cm-2, and VOC = 0.84 V. The power density of an envisioned PV module at the current technology stage is in line with the power requirements of paper-based optoelectronic devices under development. Amid the possibilities, silicon TFSC can power point-of-care tests and contribute to a more responsive care through immediate diagnosis and subsequent clinical/therapeutic decision-making.

Published

2017

13. 24-GHz CW radar front-ends on cellulose-based substrates: A new technology for low-cost applications

Author

Marco Virili, Valentina Palazzi, Paolo Mezzanotte, Giulia Orecchini, Federico Alimenti, Luca Roselli, and Chiara Mariotti

Subjects

Beam diameter, CW radar front-ends, microwave mixers, cir­cuits on cellulose, paper-based substrates, green electronics, Materials science, business.industry, Local oscillator, Electrical engineering, Microstrip, law.invention, paper-based substrates, law, green electronics, microwave mixers, Optoelectronics, Continuous wave, CW radar front-ends, Antenna (radio), Radar, business, Microwave, cir­cuits on cellulose, Electronic circuit

Abstract

This paper presents, for the first time, a 24-GHz Continuous Wave (CW) radar front-end, entirely realized on a cellulose-based (i.e. paper) substrate. The front-end uses a microstrip circuitry that is fabricated using a copper adhesive laminate to have low conductor losses. A single dielectric layer is adopted to reduce complexity and, in perspective, costs. The radar exploits an external oscillator and transmits a power of about 2 mW. The antenna has a gain of 7 dBi and features an half-power beam width of 42 degrees. Its efficiency is 25%, including the feeding line. A singly-balanced diode mixer is adopted in the receiver chain. The mixer conversion loss is 11 dB with a local oscillator driving level of 0 dBm. In Doppler mode, the radar is able to detect a small fan (i.e. the movement of its rotor) at 1 m distance from the antenna. This contribution demonstrates that circuits on cellulose are capable to operate up to the boundary between microwave and millimeter-waves.

Published

2015