ERC FUNDED PROJECTS

I intend to investigate what cognitive mechanisms give us combinatorial speech. Combinatorial speech is the ability to make new words using pre-existing speech sounds. Humans are the only apes that can do this, yet we do not know how our brains do it, nor how exactly we differ from other apes. Using new experimental techniques to study human behavior and new computational techniques to model human cognition, I will find out how we deal with combinatorial speech. The experimental part will study individual and cultural learning. Experimental cultural learning is a new technique that simulates cultural evolution in the laboratory. Two types of cultural learning will be used: iterated learning, which simulates language transfer across generations, and social coordination, which simulates emergence of norms in a language community. Using the two types of cultural learning together with individual learning experiments will help to zero in, from three angles, on how humans deal with combinatorial speech. In addition it will make a methodological contribution by comparing the strengths and weaknesses of the three methods. The computer modeling part will formalize hypotheses about how our brains deal with combinatorial speech. Two models will be built: a high-level model that will establish the basic algorithms with which combinatorial speech is learned and reproduced, and a neural model that will establish in more detail how the algorithms are implemented in the brain. In addition, the models, through increasing understanding of how humans deal with speech, will help bridge the performance gap between human and computer speech recognition. The project will advance science in four ways: it will provide insight into how our unique ability for using combinatorial speech works, it will tell us how this is implemented in the brain, it will extend the novel methodology of experimental cultural learning and it will create new computer models for dealing with human speech.

1 276 620 €

Start date: 2012-02-01, End date: 2017-01-31

My proposal seeks to explain the complex interplay between genetic and environmental causes of individual variation in substance use and the risk for abuse. Substance use is common. Substances like nicotine and cannabis have well-known negative health consequences, while alcohol and caffeine use may be both beneficial and detrimental, depending on quantity and frequency of use. Twin studies (including my own) demonstrated that both heritable and environmental factors play a role. My proposal on substance use (nicotine, alcohol, cannabis and caffeine) is organized around several key objectives: 1. To unravel the complex contribution of genetic and environmental factors to substance use by using extended twin family designs; 2. To identify and confirm genes and gene networks involved in substance use by using DNA-variant data; 3. To explore gene expression patterns with RNA data in substance users versus non-users; 4. To investigate biomarkers in substance users versus non-users using blood or urine; 5. To unravel relation between substance use and health by linking twin-family data to national medical databases. To realize these aims I will use the extensive resources of the Netherlands Twin Register (NTR); including both the longitudinal phenotype database and the biological samples. I have been involved in data collection, coordination of data collection and analyzing NTR data since 1999. With my comprehensive experience in data collection, data analyses and my knowledge in the field of behavior genetics and addiction research I will be able to successfully lead this cutting-edge project. Additional data crucial for the project will be collected by my team. Large samples will be available for this study and state-of-the art methods will be used to analyze the data. All together, my project will offer powerful approaches to unravel the complex interaction between genetic and environmental causes of individual differences in substance use and the risk for abuse.

1 491 964 €

Start date: 2011-12-01, End date: 2017-05-31

"I propose a structured multidisciplinary research programme that seeks to combine advanced materials, such as metal oxides and organics, with novel fabrication methods to develop devices for application in: (1) large area electronics, (2) integrated nanoelectronics and (3) sensors. At the heart of this programme lies the development of novel oxide semiconductors. These will be synthesised from solution using precursors. Chemical doping via physical blending will be explored for the tuning of the electronic properties of these compounds. This simple approach will enable the rapid development of a library of materials far beyond those accessible by traditional methods. Oxides will then be combined with inorganic/organic dielectrics to demonstrate low power transistors. Ultimate target for application area (1) is the development of transistors with hole/electron mobilities exceeding 20/200 cm^2/Vs respectively. For application area (2) I will combine the precursor formulations with advanced scanning thermochemical nanolithography. A heated atomic force microscope tip will be used for the local chemical conversion of the precursor to oxide with sub-50 nm resolution. This will enable patterning of nanostructures with desirable shape and size. Sequential patterning of semi/conductive layers combined with SAM dielectrics would enable fabrication of nano-sized devices and circuits. For application area (3), research effort will focus on novel hybrid phototransistors. Use of different light absorbing organic dyes functionalised onto the oxide channel will be explored as a mean for developing high sensitivity phototransistors and full colour sensing arrays. Organic dyes will also be combined with nano-sized transistors to demonstrate integrated nano-scale optoelectronics. The unique combination of bottom-up and top-down strategies adopted in this project will lead to the development of novel high performance devices with a host of existing and new applications."

1 497 798 €

Start date: 2012-01-01, End date: 2016-12-31

The interaction of cells with the extracellular matrix or neighboring cells plays a crucial role in many cellular functions, such as motility, differentiation and controlled cell death. Expanding on pioneering studies on defined 2-D model systems, the role of the currently known determinants (geometry, topography, biochemical functionality and mechanical properties) is currently addressed in more relevant 3-D matrices. However, there is a clear lack in currently available approaches to fabricate well defined microenvironments, which are asymmetric or in which these factors can be varied independently. The central objective of ASMIDIAS is the development of a novel route to asymmetric microenvironments for cell-matrix interaction studies. Inspired by molecular self-assembly on the one hand and guided macroscale assembly on the other hand, directed assembly of highly defined microfabricated building blocks will be exploited to this end. In this modular design approach different building blocks position themselves during assembly on pre-structured surfaces to afford enclosed volumes that are restricted by the walls of the blocks. The project relies on two central elements. For the guided assembly, the balance of attractive and repulsive interactions between the building blocks (and its dependence on the object dimensions) and the structured surface shall be controlled by appropriate surface chemistry and suitable guiding structures. To afford the required functionality, new approaches to (i) topographically structure, (ii) biochemically functionalize and pattern selected sides of the microscale building blocks and (iii) to control their surface elastic properties via surface-attached polymers and hydrogels, will be developed.The resulting unique asymmetric environments will facilitate novel insight into cell-matrix interactions, which possess considerable relevance in the areas of tissue engineering, cell (de)differentiation, bacteria-surface interactions and beyond.

1 484 100 €

Start date: 2011-11-01, End date: 2016-10-31