Filed on 29 / 03 / 2015
Closed
Received
$ 3,759
Minimum
$ 10,464
Optimum
$ 16,191
91 Co-financiers
Channel
  • Contributing $ 10

    You will be included in our web as co-financier with your photograph

    Our gratitude for your contribution will be published and you will be included in our web as co-financier with a photograph of your own choice.

    > 18 Co-financiers
  • Contributing $ 26

    Microscope Picture + Acknowledgment

    You wil receive a microscope image from our laboratories and our gratitude for your contribution will be published. You will be included in our web as co-financier with a photograph of your own choice.

    > 08 Co-financiers
  • Contributing $ 36

    Button+ Microscope picture+ Co-financier

    You will get the button with our logo, and all previous rewards, including public acknowledgment in our web with your photograph.

    > 10 Co-financiers
  • Contributing $ 47

    Sensor replica + Previous rewards

    You will get a copy of our sensor and all previous rewards.

    > 28 Co-financiers
  • Contributing $ 104

    Visit our labs

    You can visit our laboratories and know our project in detail.

    > 03 Co-financiers
  • Contributing $ 312

    Technical Seminar

    You can attend a technichal seminar to know in depth the progress of the project and its results. You will also get all previous rewards.

    > 01 Co-financiers
  • Contributing $ 1,041

    Sponsorship

    Recognized support as sponsor in our web, publications and all platforms and dissemination events in wich the results will be presented.

    > 00 Co-financiers
  • Contributing $ 3,124

    Premium Sponsorship

    High-visibility support acknowledgment as sponsor in our web, publications and all platforms and dissemination events in wich the results will be presented.

    > 00 Co-financiers

About this project

Contribute to develop innovative biosensors for disease diagnosis improvement

Needs Task Minimum Optimum
Publication costs
Publicación en abierto de los resultados obtenidos
$ 2,082
Device design
Design and optimization of metamaterial based biosensors
$ 521
Fabrication
Prototype fabrication
$ 1,041
Functionalization
Design and application of a functionalization protocol for specific detection of the biomolecules under study
$ 1,041
Experimental validation
Electronic and biological experimental validation of the implemented prototypes
$ 521
Minimum management costs
Management expenses of Goteo and payment platforms
$ 1,093
Prototype improvement
Study for prototype improvement, use of new materials and further functionalities
$ 1,041
Extra publications
Open-access publication of the obtained results
$ 2,082
Extra Management costs
Management expenses of Goteo and payment platforms
$ 521
Needs Material Minimum Optimum
Rewards
Costs of the rewards for our co-financiers
$ 521
Basic lab materials
Materials for prototype fabrication and basic experiments
$ 3,644
Extra lab materials
Extra materials for prototype optimization and further improvements and studies
$ 2,082
Total $ 10,464 $ 16,191
Necessary
Supplemental

General information

This is the #PROMISE project (PROtein Metamaterial Immuno SEnsor).
Nowadays, biomolecule detection involves complex and expensive techniques. In this project we aim to develop new biosensors to simplify this task. All results will be open and accessible for the whole community. In the near future, we would be able to extend their application to areas such as the scientific or medical fields, where they can be applied to disease diagnosis. The project involves the application of an innovative technology called radiofrequency metamaterials for biosensor development.
Our main purpose is to simplify the detection of nerve growth factor, which has important and interesting medical and scientific applications. Would you be interested in collaborating with the #PROMISE project? Your collaboration is truly important for us.

Main features and goals of the crowdfunding campaign

What do we aim to detect?
We are focused on the design of sensors capable of detecting biomolecules taking part in natural processes and, later on, use them to enhance disease diagnosis.
Firstly, we want to detect Nerve Growth Factor (NGF); it is quite an important molecule for the development and operation of different organs and body parts and is currently being studied as a plausible technique to fight against diseases such as Alzheimer. You can find more information in our web page (promise.webs.tsc.uc3m.es).

What are do we use for detection?
Our sensors are radiofrequency circuits based on metamaterials. We want to emphasize that it is a completely innovative technique for sensor implementation and, with this application, we expect to highly reduce the detection time and simplify the analysis of the results.
Collaborating with this project, you will help the research progress in your country.
You can visit our web page (promise.webs.tsc.uc3m.es) to know more about our sensors.

Does this project have commercial or social purposes?
No commercial products are being developed in this project. Our purpose is to develop basic research prototypes and demonstrate the utility of the proposed technique. All results will be published with open access and will be accessible and available for the entire community.

Is this a terminal project or future steps are envisaged?
With this project, we want to demonstrate the high benefits of the proposed technology. Our idea is, in the future, to apply this technology to develop new biosensors that allow us to obtain a more efficient detection applicable for diagnosis.

Who is involved in this project?
It will be developed by a multidisciplinary team composed by two research groups at Universidad Carlos III de Madrid. We are a young, highly motivated group with a wide experience in research projects. You can know more about us in the “Previous experience” and “Team” sections.

879-77-1371209345265.jpg

Why this is important

Part of our research members in this project have been working to develop metamaterial sensors for a long time. Their versatility, high benefits and application possibilities in different fields have been widely demonstrated. At this moment we want to prove the benefits of this technique for biosensor implementation and, in the future, apply them to disease diagnosis.
We consider that this project involves important social benefits and that is why we think it is interesting as crowdfunding initiative. On one hand, this funding source can be helpful in hard moments for science, in which support is difficult to achieve. On the other hand, scientific research results are usually restricted to a specific and specialized spheres, so we want to collaborate to make othem accessible for the whole society.

The #PROMISE project is aimed at the following collectives:
• Society: Our final purpose is to apply the developed technology in the diagnosing process of diseases. No matter how small your contribution may be, it will be greatly important the project.
• Researchers: The results of the project will be open access, being available for the whole scientific community. We consider that such an innovative technique can be of interest for other researchers.
• Health staff: The proposed technique will improve the diagnosis process, making it faster and more efficient. Our aim is, in the future, to apply this technique in real clinical cases.
• Sponsors: All the contributions will be gratefully and conveniently published; sponsors may show and disclose their support for R & D and their commitment with social progress and the benefits of kowledge spreading.

All colectives can obtain rewards you can find on the right hand side.

camaraanecoica.png

Goals of the crowdfunding campaign

The main goal is to collect the necessary fund to cover the design, fabrication and sensor validation expenses, as well as the costs related to open-access publication.
The project can be divided into several stages:

  1. Design of the prototypes of the metamaterial radiofrequency biosensors.
  2. Prototype fabrication of the biosensor prototypes.
  3. Validation of the experimental prototypes. Comparison between the obtained results and the ones from conventional kits.
  4. Open-acces publication of the results.
    Along the implementation process we will regularly comment our advances obtained with the biosensors in our web and social networks.
labtermeg.png

Team and experience

In this project two research groups collaborate together: GREMA and TERMeG, both being part of the Carlos III University of Madrid (UC3M).
GREMA stands for Group of Radiofrequecny, Electromagnetism Microwaves and Antennas. This group has an important background in the design and implementation of antennas, radiofrequency devices, metamaterials and sensors.
TERMeG stands for Tissue Engineering and Regenerative Medicine Group. They work on the design and development of new therapeutical techniques for skin diseases based on bioengineering techniques, and tissue and genetic engineering.
GREMA provides its experience in the design of metamaterial based devices, with the objective of exploiting the special advantages of this technology on the development of high performance biosensors. TERMeG is formed by a multidisciplinary team working together in a new field called biologic engineering, a fusion of engineering, molecular and cellular biology, and genetics with the purpose of puting new energy into the scientific discovery and boost innovative biomedical techniques.
The team is composed by:
• Daniel Segovia Vargas. Tenured Associate Professor. PhD in Telecommunication Engineering(GREMA).
• Francisco Javier Herraiz Martínez. Visiting Professor. PhD in Telecommunication Engineering (GREMA).
• Marta Gil Barba. Post-doctoral researcher. PhD in Electronic Engineering (GREMA).
• Francisco Aznar Ballesta. Tenured Associate Professor. PhD in Electronic Engineering (GREMA).
• Marcela Del Río. Visiting Professor. PhD in Pharmacy (TERMeG).
• María José Escámez. Teaching Assistant. PhD in Science (TERMeG).
• Lucía Martínez. Teaching Assistant. PhD in Biology (TERMeG).
• Adela García. Visiting Professor. PhD in Biology (TERMeG).
• Diego Velasco Bayón. Visiting Professor. PhD in Polymer Science and Engineering (TERMeG).

imagenlogos-2.jpg

Social commitment