Publication

Printed polymers, patterned paper

Salentijn, G. 2017 [Groningen]: Rijksuniversiteit Groningen. 244 p.

Research output: ScientificDoctoral Thesis

APA

Salentijn, G. (2017). Printed polymers, patterned paper [Groningen]: Rijksuniversiteit Groningen

Author

Salentijn, Gert. / Printed polymers, patterned paper. [Groningen] : Rijksuniversiteit Groningen, 2017. 244 p.

Harvard

Salentijn, G 2017, 'Printed polymers, patterned paper', Doctor of Philosophy, University of Groningen, [Groningen].

Standard

Printed polymers, patterned paper. / Salentijn, Gert.

[Groningen] : Rijksuniversiteit Groningen, 2017. 244 p.

Research output: ScientificDoctoral Thesis

Vancouver

Salentijn G. Printed polymers, patterned paper. [Groningen]: Rijksuniversiteit Groningen, 2017. 244 p.


BibTeX

@misc{0f3f9d4e5428435f81c629bf6d80bc75,
title = "Printed polymers, patterned paper",
abstract = "In his research, Gert Salentijn investigated several approaches to decrease the dependence of chemical analysis on stationary laboratory facilities to make it more accessible, or as it is popularly phrased: “to bring the lab to the sample, instead of the sample to the lab”. This type of approach has been receiving a lot of attention recently, driven by a strong need in (low-resource) point-of-care settings for speed, flexibility and cost-effectiveness in disease diagnosis. This project was financed by the Netherlands Organization for Scientific Research (NWO), and aimed to develop disposable sample interfaces for on-site analysis with a portable mass-spectrometric instrument. At the core of the research lies a simple, yet elegant material that already has a long history in science, namely paper. By approaching this material in a number of different ways, amongst which the integration into 3D-printed devices, it has proven possible to leverage paper-based analysis. The tools and techniques that were developed in the research encompass a range of new functionalities that can be applied to making smarter and better tests, while ensuring affordability.",
author = "Gert Salentijn",
year = "2017",
isbn = "978-90-367-9863-1",
publisher = "Rijksuniversiteit Groningen",
school = "University of Groningen",

}

RIS

TY - THES

T1 - Printed polymers, patterned paper

AU - Salentijn,Gert

PY - 2017

Y1 - 2017

N2 - In his research, Gert Salentijn investigated several approaches to decrease the dependence of chemical analysis on stationary laboratory facilities to make it more accessible, or as it is popularly phrased: “to bring the lab to the sample, instead of the sample to the lab”. This type of approach has been receiving a lot of attention recently, driven by a strong need in (low-resource) point-of-care settings for speed, flexibility and cost-effectiveness in disease diagnosis. This project was financed by the Netherlands Organization for Scientific Research (NWO), and aimed to develop disposable sample interfaces for on-site analysis with a portable mass-spectrometric instrument. At the core of the research lies a simple, yet elegant material that already has a long history in science, namely paper. By approaching this material in a number of different ways, amongst which the integration into 3D-printed devices, it has proven possible to leverage paper-based analysis. The tools and techniques that were developed in the research encompass a range of new functionalities that can be applied to making smarter and better tests, while ensuring affordability.

AB - In his research, Gert Salentijn investigated several approaches to decrease the dependence of chemical analysis on stationary laboratory facilities to make it more accessible, or as it is popularly phrased: “to bring the lab to the sample, instead of the sample to the lab”. This type of approach has been receiving a lot of attention recently, driven by a strong need in (low-resource) point-of-care settings for speed, flexibility and cost-effectiveness in disease diagnosis. This project was financed by the Netherlands Organization for Scientific Research (NWO), and aimed to develop disposable sample interfaces for on-site analysis with a portable mass-spectrometric instrument. At the core of the research lies a simple, yet elegant material that already has a long history in science, namely paper. By approaching this material in a number of different ways, amongst which the integration into 3D-printed devices, it has proven possible to leverage paper-based analysis. The tools and techniques that were developed in the research encompass a range of new functionalities that can be applied to making smarter and better tests, while ensuring affordability.

M3 - Doctoral Thesis

SN - 978-90-367-9863-1

PB - Rijksuniversiteit Groningen

ER -

ID: 43753438