Andre Bossche

Publications

  1. Low-Cost Wearable Fluidic Sweat Collection Patch for Continuous Analyte Monitoring and Offline Analysis
    A Stijlen; KMB Jansen; J Bastemeijer; PJ French; A Bossche;
    Analytical Chemistry,
    Volume 94, pp. 6893-6901, April 2022. DOI: https://doi.org/10.1021/acs.analchem.2c01052
    Abstract: ... Sweat sensors allow for new unobtrusive ways to continuously monitor an athlete’s performance and health status. Significant advances have been made in the optimization of sensitivity, selectivity, and durability of electrochemical sweat sensors. However, comparing the in situ performance of these sensors in detail remains challenging because standardized sweat measurement methods to validate sweat sensors in a physiological setting do not yet exist. Current collection methods, such as the absorbent patch technique, are prone to contamination and are labor-intensive, which limits the number of samples that can be collected over time for offline reference measurements. We present an easy-to-fabricate sweat collection system that allows for continuous electrochemical monitoring, as well as chronological sampling of sweat for offline analysis. The patch consists of an analysis chamber hosting a conductivity sensor and a sequence of 5 to 10 reservoirs that contain level indicators that monitor the filling speed. After testing the performance of the patch in the laboratory, elaborate physiological validation experiments (3 patch locations, 6 participants) were executed. The continuous sweat conductivity measurements were compared with laboratory [Na+] and [Cl–] measurements of the samples, and a strong linear relationship (R2 = 0.97) was found. Furthermore, sweat rate derived from ventilated capsule measurement at the three locations was compared with patch filling speed and continuous conductivity readings. As expected from the literature, sweat conductivity was linearly related to sweat rate as well. In short, a successfully validated sweat collection patch is presented that enables sensor developers to systematically validate novel sweat sensors in a physiological setting.

  2. A New Approach for Monitoring Sweat Ammonia Levels Using a Ventilated Capsule
    Annemarijn Steijlen; Jeroen Bastemaijer; Robbert Nederhoff; Kasper Jansen; Paddy French; Andre Bossche;
    engineering proceedings,
    Volume 38, pp. 6, 2021. DOI: https://doi.org/10.3390/ecsa-8-11332
    Keywords: ... sweat sensor; NH3; metal oxide gas sensor; ventilated capsule.

    Abstract: ... Ammonium levels in sweat can potentially be used to measure muscle fatigue and to diagnose particular metabolic myopathies. To research the potential use of ammonia in sweat as a biomarker, a new real-time monitoring system is developed. This system consists of a capsule that is placed at the skin and ventilated with dry air. A metal oxide gas sensor in the capsule detects the ammonia that is evaporated from sweat. The sensor system was built, and calibration experiments were performed. The sensors show good sensitivity from 27 mV/ppm to 1.1 mV/ppm in the desired measurement range of 1 to 30 ppm respectively. A temperature and humidity sensor are integrated to compensate for temperature and humidity effects on the NH3 sensor.

  3. Smart sensor tights: Movement tracking of the lower limbs in football
    Annemarijn Steijlen; Bastiaan Burgers; Erik Wilmes; Jeroen Bastemeijer; Bram Bastiaansen; Patrick French; Andre Bossche; Kaspar Jansen;
    Wearable technologies,
    Volume 2, 2021. DOI: 10.1017/wtc.2021.16
    Keywords: ... inertial measurement units, wearable sensors, football, movement tracking.

    Abstract: ... This article presents a novel smart sensor garment with integrated miniaturized inertial measurements units (IMUs) that can be used to monitor lower body kinematics during daily training activities, without the need of extensive technical assistance throughout the measurements. The smart sensor tights enclose five ultra-light sensor modules that measure linear accelerations, angular velocities, and the earth magnetic field in three directions. The modules are located at the pelvis, thighs, and shanks. The garment enables continuous measurement in the field at high sample rates (250 Hz) and the sensors have a large measurement range (32 g, 4,000°/s). They are read out by a central processing unit through an SPI bus, and connected to a centralized battery in the waistband. A fully functioning prototype was built to perform validation studies in a lab setting and in a field setting. In the lab validation study, the IMU data (converted to limb orientation data) were compared with the kinematic data of an optoelectronic measurement system and good validity (CMCs >0.8) was shown. In the field tests, participants experienced the tights as comfortable to wear and they did not feel restricted in their movements. These results show the potential of using the smart sensor tights on a regular base to derive lower limb kinematics in the field.

  4. Smart sensor tights: Movement tracking of the lower limbs in football”, Wearable Technologies
    Annemarijn Steijlen; Bastiaan Burgers; Erik Wilmes; Jeroen Bastemeijer; Bram Bastiaansen; Patrick French; Andre Bossche; Kaspar Janse;
    Waerable Technologies,
    Volume 2, 2021. DOI: e17 doi:10.1017/wtc.2021.16

  5. A wearable fluidic collection patch and ion chromatography method for sweat electrolyte monitoring during exercise
    Annemarijn Steijlen, Jeroen Bastemeijer, Pim Groen, K.M.B Jansen, Patrick French ; Andre Bossche;
    Analytical Methods,
    pp. 8, November 2020. DOI: https://doi.org/10.1039/D0AY02014A
    Abstract: ... This paper presents a method to continuously collect and reliably measure sweat analyte concentrations during exercise. The method can be used to validate newly developed sweat sensors and to obtain insight in intraindividual variations of sweat analytes in athletes. First, a novel design of a sweat collection system is created. The sweat collection patch, that is made from hydrophilized foil and a double-sided acrylate adhesive, consists of a reservoir array that collects samples consecutively in time. During a physiological experiment, sweat can be collected from the back of a participant and the filling speed of the collector is monitored by a camera. After the experiment, Na+, Cl- and K+ levels are measured with ion chromatography. Sweat analyte variations are measured during an exercise of an hour at three different locations at the back. The Na+ and Cl- variations show a similar trend and the absolute concentrations vary with patch location. Na+ and Cl concentrations increase and K+ concentrations seem to decrease during this exercise. With this new sweat collection system,sweat Na+, Cl- and K+ concentrations can be collected over time during an exercise at medium to high intensity, to analyse the trend in electrolyte variations per individual.

  6. A wearable fluidic collection patch and ion chromatography method for sweat electrolyte monitoring during exercise
    Steijlen, Annemarijn SM; Bastemeijer, Jeroen; Groen, Pim; Jansen, Kaspar MB; French, Patrick J; Bossche, Andre;
    Analytical Methods,
    Volume 12, Issue 48, pp. 5885--5892, 2020. DOI: 10.1039/D0AY02014A
    Abstract: ... This paper presents a method to continuously collect and reliably measure sweat analyte concentrations during exercise. The method can be used to validate newly developed sweat sensors and to obtain insight into intraindividual variations of sweat analytes in athletes. First, a novel design of a sweat collection system is created. The sweat collection patch, that is made from hydrophilized foil and a double-sided acrylate adhesive, consists of a reservoir array that collects samples consecutively in time. During a physiological experiment, sweat can be collected from the back of a participant and the filling speed of the collector is monitored by using a camera. After the experiment, Na+, Cl− and K+ levels are measured with ion chromatography. Sweat analyte variations are measured during exercise for an hour at three different locations on the back. The Na+ and Cl− variations show a similar trend and the absolute concentrations vary with the patch location. Na+ and Cl− concentrations increase and K+ concentrations seem to decrease during this exercise. With this new sweat collection system, sweat Na+, Cl− and K+ concentrations can be collected over time during exercise at medium to high intensity, to analyse the trend in electrolyte variations per individual.

  7. A novel sweat rate and conductivity sensor patch made with low-cost fabrication techniques
    Steijlen, ASM; Bastemeijer, J; Jansen, KMB; French, PJ; Bossche, A;
    In 2020 IEEE Sensors,
    IEEE, pp. 1--4, 2020. DOI: 10.1109/SENSORS47125.2020.9278850
    Abstract: ... Sweat sensor patches offer new opportunities for unobtrusive monitoring of an athlete's physical status. This paper presents a novel sweat rate and sweat conductivity patch that is easy to prototype and can be made with common low-cost production techniques: laser cutting and standard printed circuit board (PCB) manufacturing. The device consists of a patch made from hydrophilic PET foil, a double-sided adhesive and a thin PCB with gold electrodes. Two electrodes, which are continuously in contact with the inflowing fluid, measure the sweat conductivity and a separate system with interdigitated electrodes measures the filling process of the reservoirs. Impedance measurement results of both systems demonstrate the working of the concept.

  8. Development of Sensor Tights with Integrated Inertial Measurement Units for Injury Prevention in Football
    Steijlen, ASM; Bastemeijer, J; Plaude, L; French, PJ; Bossche, A; Jansen, KMB;
    In Proceedings of the 6th International conference on Design4Health,
    2020.
    Abstract: ... In elite European football, 6 to 7 hamstring muscle injuries occur per team per season, which results in an absence of 14 to 180 days. These injuries occur typically in the last part of a training or match. This implies that the accumulation of demanding actions is an important factor for hamstring injury risk. In current practice, physical player load is measured at the field by deriving the global location of the player with GPS and RFID systems. However, these systems are not able to monitor leg movement and to distinguish demanding actions like kicking, cutting and jumping.In order to monitor these actions in the field, a novel design is being developed. The design consists of five sensor nodes with IMUs (Inertial measurement units), integrated in sports tights. IMUs can measure linear accelerations, angular velocities and magnetic fields in three directions. From these measurements, 3D kinematics of the lower limbs can be derived. An iterative design approach is used to develop the tights. Four prototypes will be developed. Each prototype is tested in a football specific setting, to identify areas of improvement from a technical point of view as well as from a user’s perspective. The final aim of this research is to develop sensor tights that can be worn unobtrusively by football players in the field. Real-time data are retrieved by the coach. This allows the coach to intervene when there is a high injury risk.

  9. Development of a microfluidic collection system to measure electrolyte variations in sweat during exercise
    Steijlen, ASM; Bastemeijer, J; Groen, WA; Jansen, KMB; French, PJ; Bossche, A;
    In 2020 42nd Annual International Conference of the IEEE Engineering in Medicine \& Biology Society (EMBC),
    IEEE, pp. 4085--4088, 2020. DOI: 10.1109/EMBC44109.2020.9176123
    Abstract: ... A wide variety of electrochemical sweat sensors are recently being developed for real-time monitoring of biomarkers. However, from a physiological perspective, little is known about how sweat biomarkers change over time. This paper presents a method to collect and analyze sweat to identify inter and intraindividual variations of electrolytes during exercise. A new microfluidic sweat collection system is developed which consists of a patch covering the collection surface and a sequence of reservoirs. Na + , Cl - and K + are measured with ion chromatography afterwards. The measurements show that with the new collector, variations in these ion concentrations can be measured reliably over time.

  10. A Low-Power MEMS IDE Capacitor with Integrated Microhotplate: Application as Methanol Sensor using a Metal-Organic Framework Coating as Affinity Layer
    Venkatesh, Manjunath R; Sachdeva, Sumit; El Mansouri, Brahim; Wei, Jia; Bossche, Andre; Bosma, Duco; de Smet, Louis CPM; Sudhölter, Ernst JR; Zhang, Guo Qi;
    Sensors,
    Volume 19, Issue 4, pp. 888, 2019.
    Abstract: ... Capacitors made of interdigitated electrodes (IDEs) as a transducer platform for the sensing of volatile organic compounds (VOCs) have advantages due to their lower power operation and fabrication using standard micro-fabrication techniques. Integrating a micro-electromechanical system (MEMS), such as a microhotplate with IDE capacitor, further allows study of the temperature dependent sensing response of VOCs. In this paper, the design, fabrication, and characterization of a low-power MEMS microhotplate with IDE capacitor to study the temperature-dependent sensing response to methanol using Zeolitic imidazolate framework (ZIF-8), a class of metal-organic framework (MOF), is presented. A Titanium nitride (TiN) microhotplate with aluminum IDEs suspended on a silicon nitride membrane is fabricated and characterized. The power consumption of the ZIF-8 MOF-coated device at an operating temperature of 50 °C is 4.5 mW and at 200 °C it is 26 mW. A calibration methodology for the effects of temperature of the isolation layer between the microhotplate electrodes and the capacitor IDEs is developed. The device coated with ZIF-8 MOF shows a response to methanol in the concentration range of 500 ppm to 7000 ppm. The detection limit of the sensor for methanol vapor at 20 °C is 100 ppm. In situ study of sensing properties of ZIF-8 MOF to methanol in the temperature range from 20 °C to 50 °C using the integrated microhotplate and IDE capacitor is presented. The kinetics of temperature-dependent adsorption and desorption of methanol by ZIF-8 MOF are fitted with double-exponential models. With the increase in temperature from 20 °C to 50 °C, the response time for sensing of methanol vapor concentration of 5000 ppm decreases by 28%, whereas the recovery time decreases by 70%.

  11. A Low-Power MEMS IDE Capacitor with Integrated Microhotplate: Application as Methanol Sensor using a Metal-Organic Framework Coating as Affinity Layer
    Venkatesh, M.R.; Sachdeva, S.; El Mansouri, B.; Wei, J.; Bossche, A.; Bosma, D.; de Smet; L. C. P. M.; Sudhölter, E. J. R.; GuoQi Zhang;
    Sensors (Basel, Switzerland),
    2019. DOI: 10.3390/s19040888

  12. Analyzing sweat to determine state of fatigue
    Miguel Thomas; Andre Bossche; Pim Groen; Jeroen Bastemeijer; Annemarijn Steijlen; Paddy French;
    In Proceedings SSI conference,
    Barcelona, Spain, April 2019.

  13. MEMS for biofuel composition measurement based on thermal impedance spectroscopy
    Ghaderi, Mohammadamir; Jiang, Bo; Bossche, Andre; Visser, Jaco H; Wolffenbuttel, Reinoud F;
    Sensors and Actuators B: Chemical,
    Volume 277, pp. 281--288, December 2018. DOI: 10.1016/j.snb.2018.08.098
    Abstract: ... Continuous monitoring of the composition of E85 biofuel is essential for a quick start and clean and efficient operation of Flex-Fuel Vehicles. The actual ethanol concentration in E85 fuel is in the range 50%–85% and fuel-line sensors are used for ethanol-gasoline composition measurement. However, also a small amount of water is typically present, which cannot be reliably detected using state-of-the-art capacitive fuel-line sensors. Thermal impedance spectroscopy has been investigated as a non-destructive technique to determine the composition of ternary mixtures of biofuels. The principle of the thermal conductivity detector has been extended for measuring both the thermal conductivity and the thermal capacity of biofuel in the range up to 10 kHz using an AC-operated polysilicon heater for injecting a sinusoidal heat flux, and another polysilicon strip at a well-defined spacing or thermopile sensors for measuring the in-phase and quadrature components of the resulting AC temperature difference. Measurements on the components are in reasonable agreement with simulations, with a −3 dB cut-off frequency at 422.5 Hz and 340.8 Hz for ethanol and gasoline, respectively. However, the cut-off frequency of water was found to be significantly lower than simulations due to its high surface tension, thus limiting access to the detector.

  14. Sensitive and Reversible Detection of Methanol and Water Vapor by In Situ Electrochemically Grown CuBTC MOFs on Interdigitated Electrodes
    S. Sachdeva; M.R. Venkatesh; B.E. Mansouri; J. Wei; A. Bossche; F. Kapteijn; G.Q. Zhang; J. Gascon; L.C.P.M. de Smet; E.J.R. Sudhölter;
    Small,
    Volume 13, Issue 29, 08 2017. DOI: 10.1002/smll.201604150
    Abstract: ... The in situ electrochemical growth of Cu benzene-1,3,5-tricarboxylate (CuBTC) metal-organic frameworks, as an affinity layer, directly on custom-fabricated Cu interdigitated electrodes (IDEs) is described, acting as a transducer. Crystalline 5-7 µm thick CuBTC layers are grown on IDEs consisting of 100 electrodes with a width and a gap of both 50 µm and a height of 6-8 µm. These capacitive sensors are exposed to methanol and water vapor at 30 °C. The affinities show to be completely reversible with higher affinity toward water compared to methanol. For exposure to 1000 ppm methanol, a fast response is observed with a capacitance change of 5.57 pF at equilibrium. The capacitance increases in time followed diffusion-controlled kinetics (k = 2.9 mmol s-0.5 g-1CuBTC ). The observed capacitance change with methanol concentration follows a Langmuir adsorption isotherm, with a value for the equilibrium affinity Ke = 174.8 bar-1 . A volume fraction fMeOH = 0.038 is occupied upon exposure to 1000 ppm of methanol. The thin CuBTC affinity layer on the Cu-IDEs shows fast, reversible, and sensitive responses to methanol and water vapor, enabling quantitative detection in the range of 100-8000 ppm.

  15. Multi-domain spectroscopy for composition measurement of water-containing bio-ethanol fuel
    L.M. Middelburg; G. de Graaf; A. Bossche; J. Bastemeijer; M. Ghaderi; F.S. Wolffenbuttel; J. Visser; R. Soltis; R.F. Wolffenbuttel;
    Fuel Processing Technology,
    Volume 167, pp. 127-135, 2017. DOI: 10.1016/j.fuproc.2017.06.007
    Abstract: ... Measuring the ethanol/water ratio in biofuel of high ethanol content, such as E85, is important when used in a flex-fuel engine. A capacitive probe is generally used for measuring the ethanol/gasoline ratio. However, the water content in E85 biofuel cannot be disregarded or considered constant and full composition measurement of biofuel is required. Electric impedance spectroscopy with a customized coaxial probe operating in the 10 kHz to 1 MHz frequency range was investigated. An in-depth investigation of the electrical impedance domain has led to the conclusion that additional information is required to unambiguously determine the composition of the ternary biofuel mixture. Among the different options of measurement domains and techniques, optical absorption spectroscopy in the UV spectral range between 230 and 300 nm was found to be the most appropriate. The typical absorbance in the UV range is highly dominated by gasoline, while ethanol and water are almost transparent. This approach is experimentally validated using actual fuels.

  16. Multi-domain spectroscopy for composition measurement of water-containing bio-ethanol fuel
    L.M. Middelburg; G. de Graaf; A. Bossche; J.Bastemeijer; M. Ghaderi; F.S. Wolffenbuttel; J. Visser; R. Soltis; R.F. Wolffenbuttel;
    Fuel Processing Technology,
    Volume 167, pp. 127-135, 2017.

  17. Sensitive and Reversible Detection of Methanol and Water Vapor by In Situ Electrochemically Grown CuBTC MOFs on Interdigitated Electrodes
    Sumit Sachdeva; Manjunath R. Venkatesh; Brahim El Mansouri; Jia Wei; Andre Bossche; Freek Kapteijn; GuoQi Zhang; Jorge Gascon; Louis C. P. M. de Smet; Ernst J. R. Sudhölter;
    Small,
    Volume 13, Issue 29, pp. 1604150, 2017.

  18. Combining impedance spectroscopy with optical absorption spectroscopy in the UV for biofuel composition measurement
    L. Middelburg; M. Ghaderi; A. Bossche; J. Bastemeijer; G. de Graaf; R.F. Wolffenbuttel; R. Soltis; J. Visser;
    In Instrumentation and Measurement Technology Conference (I2MTC), 2017 IEEE International,
    IEEE, IEEE, pp. 1-6, 05 2017. DOI: 10.1109/i2mtc.2017.7969676
    Abstract: ... A capacitive probe is generally used in a flex-fuel engine for measuring the ethanol content in biofuel. However, the water content in biofuel of high ethanol content cannot be disregarded or considered constant and the full composition measurement of ethanol, gasoline and water in biofuel is required. Electrical impedance spectroscopy with a customized capacitive probe operating in the 10 kHz to 1 MHz frequency range is combined with optical absorption spectroscopy in the UV spectral range between 230 and 300 nm for a full composition measurement. This approach is experimentally validated using actual fuels and the results demonstrate that electrical impedance spectroscopy when supplemented with optical impedance spectroscopy can be used to fully determine the composition of the biofuel and applied for a more effective engine management. A concept for a low-cost combined measurement system in the fuel line is presented.

  19. Microstructure for Thermal Impedance Spectroscopy for Biofuel Composition Measurement
    B. Jiang; M. Ghaderi; A. Bossche; J.H. Visser; R.F. Wolffenbuttel;
    In Multidisciplinary Digital Publishing Institute Proceedings,
    pp. 396, 2017. DOI: 10.3390/proceedings1040396
    Abstract: ... Thermal impedance spectroscopy has been investigated as a non-destructive technique to determine the composition of ternary mixtures of biofuels. The principle of the thermal conductivity detector has been extended for measuring both the thermal conductivity and the thermal capacity of biofuel in the range between 1 to 100 Hz, using an AC-operated polysilicon heater for injecting a sinusoidal heat flux, and another polysilicon strip at a well-defined spacing or thermopile sensors for measuring the in-phase and quadrature components of the resulting AC temperature difference.

  20. Combining impedance spectroscopy with optical absorption spectroscopy in the UV for biofuel composition measurement
    Luke Middelburg; Mohammadamir Ghaderi; Andre Bossche; Jeroen Bastemeijer; Ger de Graaf; Reinoud Wolffenbuttel;
    In Instrumentation and Measurement Technology Conference (I2MTC), 2017 IEEE International,
    2017.

  21. Optical Spectroscopy for Biofuel Composition Sensing
    L.M. Middelburg; G. de Graaf; M. Ghaderi; A. Bossche; J.H. Bastemeijer; J.H. Visser; R.F. Wolffenbuttel;
    In Procedia Engineering (Proceedings of the 30th Eurosensors Conference), vol. 168,
    Elsevier, pp. 55-58, 2016.

  22. Electro-thermal analysis and design of a combined MEMS impedance and micro hotplate device for gas sensing applications
    M.R. Venkatesh; B. El Mansouri; J. Wei; A. Bossche; G.Q. Zhang;
    In 2016 17th International Conference on Thermal, Mechanical and Multi-Physics Simulation and Experiments in Microelectronics and Microsystems (EuroSimE),
    IEEE, pp. 1-9, 2016.

  23. Reliable inkjet-printed interconnections on foil type Li-ion batteries
    N.B. Palacios Aguilera; H.A. Visser; A. Sridhar; U. Balda-Irurzun; L.D. Vargas Llona; J. Zhou; R. Akkerman; P.J. French; A. Bossche;
    IEEE Transactions on Device and Materials Reliability,
    Volume 13, Issue 1, pp. 136-145, 2013.

  24. Low-cost technology for the integration of micro-and nanochips into fluidic systems on printed circuit board: Fabrication challenges
    N.B. Palacios-Aguilera; J. Bastemeijer; J.R. Mollinger; A. Bossche; V.R.S.S. Mokkapati RSS; H.A. Visser; R. Akkerman;
    International Journal on Advances in Systems and Measurements,
    Volume 5, Issue 1 & 2, pp. 11-21, 2012.

  25. Performance of inkjet-printed structures on different substrate materials under high humidity and elevated temperature conditions
    N.B. Palacios-Aguilera; H.A. Visser; L.D. Vargas-Llona; U. Balda Irurzun; A. Sridhar; R. Akkerman; A. Bossche;
    In 4th Electronic System-Integration Technology Conference (ESTC),
    pp. 5, 2012.

  26. Microfluidic cell trapping device based on standard PCB technology
    N.B. Palacios Aguilera; T. Zhou; J. Bastemeijer; J.R. Mollinger; A. Bossche;
    In V Ovchinnikov; P Dini (Ed.), Proceedngs Sixth International Conference on Quantum, Nano and Micro Technologies,
    IARIA / Curran Associates INc., pp. 1-6, 2012.

  27. Performance of inkjet-printed structures on different substrate materials under high humidity and elevated temperature conditions
    N.B. Palacios Aguilera; H.A. Visser; L.D. Vargas Llona; U. Balda Irurzun; A. Sridhar; R. Akkerman; A. Bossche;
    In {Paulasto-Krockel et al}, M (Ed.), Proceedings 4th Electronics System Integration Technologies Conference 2012,
    pp. -, 2012.

  28. A method to calibrate spring constant of cantilevers used in scanning force microscopy
    A. Bossche; J.F.L. Goosen; H. Sadeghian Marnani; C.K. Yang; A. van Keulen; P.J. French;
    Patent, 2005687, OCT-10-039 2012.

  29. DNA tracking within a nanochannel: device fabrication and experiments
    V.R.S.S. Mokkapati; V. di Virgilio; C. Shen; J. Mollinger; J. Bastemeijer; A. Bossche;
    Lab on a Chip,
    Volume 11, Issue 16, pp. 2711-2719, 2011.

  30. Effects of size and surface on the elasticity of silicon nanoplates: molecular dynamics and semi-continuum approaches
    H. Sadeghian; J.F.L Goosen; A. Bossche; B.J. Thijsse; F. van Keulen;
    Thin Solid Films,
    Volume 520, Issue 1, pp. 391-399, 2011.

  31. On the size-dependent elasticity of silicon nanocantilevers: impact of defects
    H. Sadeghian; J.F.L Goosen; A. Bossche; B.J. Thijsse; F. van Keulen;
    Journal of Physics D: Applied Physics,
    Volume 44, Issue 7, pp. 072001, 2011.

  32. Low temperature encapsulation of nanochannels with water inside
    C. Shen; V.R.S.S. Mokkapati; F. Santagata; A. Bossche; P.M. Sarro;
    In 16th International Solid-State Sensors, Actuators and Microsystems Conference (TRANSDUCERS 2011),
    Beijing, China, pp. 854-857, Jun. 2011. ISBN 978-1-4577-0157-3; DOI 10.1109/TRANSDUCERS.2011.5969464.

  33. Low temperature encapsulation of nanochannels with water inside
    C. Shen; VRSS. Mokkapati; F. Santagata; A. Bossche; P.M. Sarro;
    In {Fan et al}, L-S (Ed.), 16th International Solid-State Sensors, Actuators and Microsystems Conference (TRANSDUCERS 2011),
    IEEE, pp. 854-857, 2011.

  34. Shapeable Li-ion batteries as substrate: printed electronics reliability
    N.B. Palacios-Aguilera; U. Balda Irurzun; A. Sridhar; J. Bastemeijer; J.R. Mollinger; R. Akkerman; J. Zhou; P.J. French; A. Bossche;
    In International Conference on Electronics Packaging proceedings,
    Nara, Japan, pp. 844-848, April 2011.

  35. Limitations of Gluing as a Replacement of Ultrasonic Welding: Attaching Lithium Battery Contacts to PCBs
    N.B. Palacios-Aguilera; J.R. Mollinger; J. Bastemeijer; J. Zhou; P.J. French; A. Bossche;
    In 6th International Microsystems, Packaging Assembly and Circuits Technology (IMPACT),
    Taipei, Taiwan, IEEE, pp. 251-254, 2011.

  36. Dry Film Resist Microfluidic Channels on Printed Circuit Board and its Application as Fluidic Interconnection for Nanofluidic Chips: Fabrication Challenges
    N.B. Palacios-Aguilera; S. Mokkapati; J. Bastemeijer; J.R. Mollinger; A. Bossche;
    In V Privman; V Ovchinnikov (Ed.), 5th International Conference on Quantum, Nano and Micro Technologies 2011 (ICQNM),
    IARIA, pp. 71-76, 2011.

  37. Low temperature encapsulation of nanochannels with water inside
    C. Shen; V.R.S.S Mokkapati; F. Santagata; A. Bossche; P.M. Sarro;
    In 2011 16th International Solid-State Sensors, Actuators and Microsystems Conference,
    IEEE, pp. 854-857, 2011.

  38. Some considerations of effects-induced errors in resonant cantilevers with the laser deflection method
    H. Sadeghian; C.K. Yang; K. Babaei Gavan; J.F.L. Goosen; EW.J.M. van der Drift; H.S.J. van der Zant; A. Bossche; P.J. French; F. van Keulen;
    Journal of Micromechanics and Microengineering,
    Volume 20, Issue 10, pp. 105027-105036, 2010.

  39. Effects of size and defects on the elasticity of silicon nanocantilevers
    H. Sadeghian Marnani; C.K. Yang; J.F.L. Goosen; A. Bossche; U. Staufer; P.J. French; F. van Keulen;
    Journal of Micromechanics and Microengineering,
    Volume 20, Issue 064012, pp. 1-8, 2010.

  40. Application of electrostatic pull-in instability on sensing adsorbate stiffness in nanomechanical resonators
    H. Sadeghian Marnani; J.F.L. Goosen; A. Bossche; F. van Keulen;
    Thin Solid Films,
    Volume 518, Issue 17, pp. 5018-5021, 2010.

  41. Surface reconstruction and elastic behavior of silicon nanobeams: The impact of applied deformation
    H. Sadeghian Marnani; J.F.L. Goosen; A. Bossche; B.J. Thijsse; F. van Keulen;
    Thin Solid Films,
    Volume 518, pp. 3273-3275, 2010.

  42. Temperature sensitivity of silicon cantilevers' elasticity with the electrostatic pull-in instability
    H. Sadeghian Marnani; D. Yang; J.F.L. Goosen; A. Bossche; P.J. French; F. van Keulen;
    Sensors and Actuators A: Physical: an international journal devoted to research and development of physical and chemical transducers,
    Volume 162, pp. 220-224, 2010.

  43. Li-ion shapeable batteries: a flexible platform for system-in-package
    N.B. Palacios Aguilera; A. Sridhar; U. Balda Irurzun; L. Giangrande; J. Bastemeijer; J.R. Mollinger; D.J. Van Dijck; J. Zhou; P.J. French; A. Bossche;
    In {French et al}, P (Ed.), Proceedings 13th SAFE Workshop of the STW.ICT Conference 2010,
    STW, pp. 131-135, 2010.

  44. Nanochannels fabrication, filling and DNA manipulation
    VRSS. Mokkapati; V. di Virgilio; J.R. Mollinger; J. Bastemeijer; A. Bossche;
    In P Decuzzi; {Cao et al}, J (Ed.), Proceedings ASME 2010 First Global Congress on NanoEngineering for Medicine and Biology,
    ASME, pp. 135-138, 2010. NEO.

  45. Quantitative analysis and decoupling of mass and stiffness effects in cantilever mass sensors
    H. Sadeghian Marnani; C.K. Yang; H. Goosen; A. Bossche; P.J. French; F. van Keulen;
    In {Fedder et al}, G (Ed.), Proceedings Sensors 2010,
    IEEE, pp. 631-634, 2010.

  46. Evaluation of encapsulation materials for glued Li ion battery contacts
    N.B. Palacios Aguilera; L. Giangrande; J. Zhou; J.R. Mollinger; J. Bastemeijer; P.J. French; A. Bossche;
    In {French et al}, P (Ed.), Proceedings of 13th SAFE Workshop of the STW.ICT Conference 2010,
    STW, pp. 127-130, 2010.

  47. Method for determining a spring constant for a deformable scanning probe microscope element, and scanning probe microscope and calibration device arranged for determing a spring constant for a probe element
    H. Sadeghian Marnani; C. Yang; F. van Keulen; J.F.L. Goosen; A. Bossche;
    2010.

  48. Surface stress-induced change in overall elastic behavior and self-bending of ultrathin cantilever plates
    H. Sadeghian Marnani; J.F.L. Goosen; A. Bossche; F. van Keulen;
    Applied Physics Letters,
    Volume 94, Issue 231908, pp. 1-3, 2009.

  49. Characterizing size-dependent effective elastic modulus of silicon nanocantilevers using electrostatic pull-in instability
    H. Sadeghian Marnani; C.K. Yang; J.F.L. Goosen; E. Drift; A. Bossche; P.J. French; F. van Keulen;
    Applied Physics Letters,
    Volume 94, Issue 221903, pp. 1-3, 2009.

  50. Effects of surface stress on nanocantilevers
    H. Sadeghian Marnani; C.K. Yang; K. Babaei Gavan; J.F.L. Goosen; EW.J.M. van der Drift; H.S.J. van der Zant; A. Bossche; P.J. French; F. van Keulen;
    E-Journal of Surface Science and Nanotechnology,
    Volume 7, pp. 161-166, 2009.

  51. Wireless sensor network project PLEISTER Package label electronics including sensing talkative radio
    J. Bastemeijer; J.R. Mollinger; L. Giangrande; Berenice Palacios Aguilera; P.J. French; A. Bossche;
    conference, 2009. NEO IEEE Sensors.

  52. Surface contamination induced resonance frequency shift of cantilevers
    H. Sadeghian; C.K. Yang; K. Babaei Gavan; J.F.L. Goosen; EW.J.M. van der Drift; H.S.J. van der Zant; P.J. French; A. Bossche; F. van Keulen;
    s.n. (Ed.);
    IEEE Computer Society, , pp. 396-399, 2009.

  53. Low voltage plug dispersion compensation for moving field capillary electrophoresis with flow loss via the side channels
    L. Zhang; A. Bossche;
    s.n. (Ed.);
    IEEE, , pp. 581-584, 2009.

  54. Fabrication of a microfluidic device with insulated electrodes on top and bottom sides of the channel
    L. Zhang; A. Bossche;
    S Teo; AQ Liu; H Li; B Tarik (Ed.);
    Trans Tech Publications, , pp. 183-186, 2009.

  55. Gluing as an alternative to solder flexible batteries for its use in system-in-a-package: preliminary results
    N.B. Palacios Aguilera; J.R. Mollinger; J. Bastemeijer; J. Zhou; P.J. French; A. Bossche;
    In s.n. (Ed.), Proceedings of 11th Electronics packaging technology conference,
    IEEE, pp. 550-555, 2009.

  56. Fabrication and experimental verification of a dielectrophoretic separation device
    L. Zhang; J. Bastemeijer; J.R. Mollinger; A. Bossche;
    In s.n. (Ed.), Proceedings of 8th annual IEEE sonference on sensors,
    IEEE, pp. 1168-1171, 2009.

  57. Fabrication and testing of a TMMF S2030 based microfluidic device for single cell analysis
    S. Mokkapati; L. Zhang; R. hanfoug; J. Bastemeijer; J.R. Mollinger; A. Bossche;
    In s.n. (Ed.), Fabrication and testing of a TMMF S2030 based microfluidic device for single cell analysis,
    International conference on quantum, nano and microtechnologies (ICQNM), pp. 86-89, 2009.

  58. Effect of Laser Deflection on Resonant Cantilever Sensors
    C.K. Yang; A. Bossche; P.J. French; H. Sadeghian Marnani; J.F.L. Goosen; F. van Keulen; K. Babaei Gavan; H.S.J. van der Zant; EW.J.M. van der Drift;
    In {Makhopadhyay, S.C.} (Ed.), Proceedings of the IEEE Sensors 2009 Conference, 25-28 October 2009, Christchurch, New Zealand,
    IEEE, pp. 869-872, 2009.

  59. Fabrication of a lab-on-a-chip device for single cell analysis using TMMF S2030
    S. Mokkapati; L. Zhang; F. postma; J. Bastemeijer; J.R. Mollinger; A. Bossche;
    In s.n. (Ed.), Proceedings of ICMEMS 2009,
    ICMEMS, pp. 1-4, 2009.

  60. Comparision of conductive glues and ultrasonic welding to contact formable batteries for its use in system-in-a-package: preliminary results
    N.B. Palacios Aguilera; J. Bastemeijer; J.R. Mollinger; J. Zhou; P.J. French; A. Bossche;
    In s.n. (Ed.), Proceedings of SAFE 2009,
    STW, pp. 99-102, 2009.

  61. Nanochannels fabrication with nearly-flat walls and embedded electrodes for nano-bio sensing
    S. Mokkapati; V. di Virgilio; J.R. Mollinger; J. Bastemeijer; A. Bossche;
    In s.n. (Ed.), Proceedings of SAFE 2009,
    STW, pp. 40-43, 2009.

  62. Size dependent elastic behavior of silicon nanofilms molecular dynamics study
    H. Sadeghian Marnani; J.F.L. Goosen; A. Bossche; B.J. Thijsse; F. van Keulen;
    In s.n. (Ed.), Proceedings of the ASME 2009 International Mechanical Engineering Congress d344c05bce504fc6a756492d950402b8 Exposition IMECE2009, November 13-19, 2009, Lake Buena Vista, Florida, USA,
    ASME, pp. 1-6, 2009.

  63. On the size-dependent elastic behavior of silicon nanocantilevers
    H. Sadeghian Marnani; C.K. Yang; J.F.L. Goosen; A. Bossche; U. Staufer; P.J. French; F. van Keulen;
    In s.n. (Ed.), Proceedings of the MicroMechanics Europe 2009 Conference, September 20-22, 2009, Toulouse, France,
    MME, pp. 1-4, 2009.

  64. Surfaces Induce Errors in Resonance-Shift Sensing
    C.K. Yang; H. Sadeghian Marnani; K. Babaei Gavan; J.F.L. Goosen; E. Drift; H.S.J. van der Zant; A. Bossche; F. van Keulen; P.J. French;
    In s.n. (Ed.), Proceedings of the Sense of Contact 11, 8 April 2009, Zeist, The Netherlands,
    Sense of Contact 2009, pp. 1-6, 2009.

  65. A novel device for particle batch separation based on dielectrophoresis
    L. Zhang; A. Bossche;
    In s.n. (Ed.), Proceedings of Transducers 2009,
    Transducers, pp. 2151-2154, 2009.

  66. Size effects on the bending stiffness of silicon nanocantilevers
    H. Sadeghian Marnani; C.K. Yang; J.F.L. Goosen; A. Bossche; P.J. French; F. van Keulen;
    In s.n. (Ed.), Proceedings of ProRISC 2009, 20th Annual Workshop on circuits, Systems and Signal Processing, SAFE 2009, 12th Annual Workshop on Semiconductor Advances for Future Electronics and Sensors, November 26-27, 2009, Veldhoven, The Netherlands,
    ProRISC en SAFE, pp. 108-111, 2009.

  67. Fabrication of nanochannels with nearly flat walls and embedded titanium nitride electrodes for nano bio sensing
    S. Mokkapati; L. Zhang; J. Bastemeijer; J.R. Mollinger; A. Bossche;
    In s.n. (Ed.), Fabrication of nanochannels with nearly flat walls and embedded titanium nitride electrodes for nano bio sensing,
    MME, pp. 01-04, 2009.

  68. Temperature Sensitivity of Silicon Cantilevers with the Pull-in Instability Method
    H. Sadeghian Marnani; C.K. Yang; J.F.L. Goosen; A. Bossche; P.J. French; F. van Keulen;
    In {Brugger, J.}; {Briand, D.} (Ed.), Proceedings of the Eurosensors XXIII Conference, 6-9 September 2009, Lausanne, Switzerland,
    Elsevier, pp. 1387-1390, 2009.

  69. Temperature Sensitivity of Silicon Cantilevers with the Pull-in Instability Method
    H. Sadeghian Marnani; C.K. Yang; J.F.L. Goosen; A. Bossche; P.J. French; F. van Keulen;
    In {Brugger, J.}; {Briand, D.} (Ed.), Proceedings of the Eurosensors XXIII Conference, 6-9 September 2009, Lausanne, Switzerland,
    Elsevier, pp. 1387-1390, 2009.

  70. ¿/6 Suspended Patch Antenna
    L. Giangrande; J.R. Mollinger; J. Bastemeijer; A. Bossche;
    In s.n. (Ed.), STW, pp. 143-146, 2009.

  71. System and method for micro- and nanoelectromechanical sample mass measurement
    H. Sadeghian Marnani; C.K. Yang; F. van Keulen; J.F.L. Goosen; A. Bossche; P.J. French;
    2009. Op naam van TU Delft; 2003643; Op naam van TU Delft.

  72. Method for measuring a temperature, electromechanical device for measuring a temperature
    H. Sadeghian Marnani; F. van Keulen; C.K. Yang; J.F.L. Goosen; A. Bossche;
    2009. Op naam van TU Delft; 2003431; Op naam van TU Delft.

  73. Fabrication and optical characterization of nano-hole arrays in gold and gold/palladium films on glass
    O.M. Piciu; M.W. Docter; M. van der KrogtC; Y. Garini; I.T. Young; P.M. Sarro; A. Bossche;
    Institution of Mechanical Engineers. Proceedings. Part N: Journal of Nanoengineering and Nanosystems,
    Volume 221, Issue 3, pp. 107-114, 2008.

  74. Size-dependent trajectories of DNA macromolecules due to insulative dielectrophoresis in submicrometer-deep fluidic channels
    G.O.F. Parikesit; A.P. Markesteijn; O.M. Piciu; A. Bossche; J. Westerweel; I.T. Young; Y. Garini;
    Biomicrofluidics,
    Volume 2, Issue 024103, pp. 1-14, 2008.

  75. A mechanistic model for adsorption-induced change in resonance response of submicron cantilevers
    H. Sadeghian Marnani; J.F.L. Goosen; A. Bossche; F. van Keulen;
    SA Tadigadapa; BA Parviz; AK Henning (Ed.);
    SPIE, , pp. 1-8, 2008.

  76. Continuous dielectrophoretic separation in the iterative curves using DC biased AC electric fields
    L. Zhang; J. Bastemeijer; J.R. Mollinger; A. Bossche;
    s.n. (Ed.);
    IEEE, , pp. 864-868, 2008.

  77. Lab-on-a-chip device:testing,alignment,bonding and trapping of polystyrene beads
    S. Mokkapati; O.M. Piciu; L. Zhang; J.R. Mollinger; J. Bastemeijer; A. Bossche;
    In s.n. (Ed.), Proceedings of MME 2008,
    MME, pp. 213-216, 2008.

  78. PDMS-glass bonded microfluidic device for single cell analysis:testing, alignment,bonding and trapping of polystyrene beads
    S. Mokkapati; O.M. Piciu; L. Zhang; J.R. Mollinger; J. Bastemeijer; A. Bossche;
    In s.n. (Ed.), Proceedings of SAFE 2008,
    SAFE, pp. 415-419, 2008.

  79. Plug dispersion compensation for moving field capillary electrophoresis by low voltage electroosmotic pump
    L. Zhang; R. Lindken; A. Bossche;
    In s.n. (Ed.), Proceedings of IEEE Sensors 2008,
    IEEE, pp. 1175-1178, 2008.

  80. PDMS-glass bonded lab-on-a-chip device for single cell analysis
    S. Mokkapati; O.M. Piciu; L. Zhang; J.R. Mollinger; J. Bastemeijer; A. Bossche;
    In {S.Hascik, J.Osvald} (Ed.), Proceedings of ASDAM 2008,
    ASDAM, pp. 211-214, 2008.

  81. Lab-on-a-chip device for single cell analysis:trapping polystyrene beads
    S. Mokkapati; O.M. Piciu; L. Zhang; J.R. Mollinger; J. Bastemeijer; A. Bossche;
    In s.n. (Ed.), Proceedings of APCTP-ASEAN workshop on Advanced Material Science and Nanotechnology,
    Academic press of vietnam academy of science and technology, pp. 1093-1097, 2008.

  82. Particle deflection in the electrode arrays by dielectrophoresis and AC electroosmosis
    L. Zhang; A. Bossche;
    In s.n. (Ed.), Proceedings Eurosensors XXII,
    Eurosensors, pp. 321-324, 2008.

  83. An investigation on the particle movement in the slanted planar electrode arrays
    L. Zhang; A. Bossche;
    In s.n. (Ed.), apcot, pp. 1-4, 2008.

  84. Structured illumination microscopy using extraordinary transmission through sub-wavelength hole-arrays
    M.W. Docter; P.M. van den Berg; P.F.A. Alkemade; V.G. Kutchoukov; O.M. Piciu; A. Bossche; I.T. Young; Y. Garini;
    Journal of Nanophotonics,
    Volume 1, Issue 011665, pp. 1-10, 2007.

  85. Nanoned report (1-01-2007 to 01-07-2007)
    O.M. Piciu; A. Bossche;
    Nanoned, , 2007.

  86. Nano-hole Arrays in Thin Au/Pd Film on Glass, for High Speed Molecular Analysis
    O.M. Piciu; M. van der KrogtC; F. Tatar; P.M. Sarro; A. Bossche; M.W. Docter; Y. Garini; I.T. Young;
    In s.n. (Ed.), Proceedings of 5th IEEE Conference on Sensors,
    IEEE, pp. 608-611, 2007.

  87. Microfluidic prototype fabrication in dry film resist
    L. Zhang; J.R. Mollinger; J. Bastemeijer; A. Bossche;
    In {A. Liu, J. Wu, C.Lu}; {C.D. Reddy} (Ed.), MEMS technology and devices,
    pan Stanford, pp. 414-417, 2007. Voor de telling krijft deze ND ipv ID.

  88. Plug dispersion compensation in moving field capillary electrophoresis applications
    F. Tatar; L. Zhang; J. Bastemeijer; J.R. Mollinger; A. Bossche;
    In s.n. (Ed.), International Solid-State Sensors, Actuators and Microsystems Conference, 2007. TRANSDUCERS 2007.,
    IEEE, pp. 779-782, 2007.

  89. Sub-wavelength apertures in Au/Pd film for fluorescence measurements
    O.M. Piciu; M. van der KrogtC; M.W. Docter; Y. Garini; I.T. Young; P.M. Sarro; A. Bossche;
    In s.n. (Ed.), Sense of Contact 2009, pp. 1-4, 2007.

  90. Adsorption-induced Resonance Frequency Change in Submicron Structures
    H. Sadeghian Marnani; J.F.L. Goosen; A. Bossche; F. van Keulen;
    In P.J. French; K DeMeyer; W Krautschneider; L.K. Nanver; {van de Sanden}, MCM; J Schmitz (Ed.), Proceedings SAFE 2007, 10th Annual Workshop on Semiconductor Advances for Future Electronics and Sensors,
    Technology Foundation STW, pp. 621-624, 2007.

  91. Lab-on-a-chip device for single cell analysis
    S. Mokkapati; O.M. Piciu; A. Bossche;
    In s.n. (Ed.), SAFE,
    SAFE, pp. 612-616, 2007.

  92. Measuring the Wavelength-dependent divergence of transmission through sub-wavelength hole-arrays by spectral imaging
    M.W. Docter; I.T. Young; O.M. Piciu; A. Bossche; P.F.A. Alkemade; P.M. van den Berg; Y. Garini;
    Optics Express,
    Volume 14, Issue 20, pp. 9477-9482, 2006.

  93. Measuring the near-field of extra-ordinary transmission through a periodic hole-array
    M.W. Docter; I.T. Young; O.M. Piciu; A. Bossche; P.F.A. Alkemade; P.M. van den Berg; Y. Garini;
    Proceedings of SPIE- International Society for Optical Engineering,
    Volume 6195, 2006.

  94. CE-MICROMODULE (STW project) Progress report (November 2005-April 2006) (U-SP-2-I-ICT)
    A. Bossche;
    STW, Volume STW , 2006.

  95. NANONED-Periodic progress report (U-SP-2-I-ICT)
    A. Bossche;
    Nanoned/Nanoimpuls, Volume Nanoned , 2006.

  96. Shape Vision (STW project) Final report (U-SP-2-I-ICT)
    A. Bossche;
    STW, Volume STW , 2006.

  97. CE-MICROMODULE (STW project) progress report (may 2006-November 2006) (U-SP-2-I-ICT)
    A. Bossche;
    STW, Volume STW , 2006.

  98. Shape Vision (STW project) progress report (November 2005-April 2006) (U-SP-2-I-ICT)
    A. Bossche;
    STW, Volume STW , 2006.

  99. Continuous Electrodeless Dielectrophoretic Separation in a Circular Channel (U-SP-2-I-ICT)
    L. Zhang; F. Tatar; P. Turmezei; J. Bastemeijer; J.R. Mollinger; O.M. Piciu; A. Bossche;
    {Francis E.H. tay, Miao Jianmin}; {John Bergstrom, Ciprian Iliesc} (Ed.);
    s.l., , pp. 527-532, 2006.

  100. Continuous Electrokinetic Separation by Electrodeless Dielectrophoresis (U-SP-2-I-ICT)
    L. Zhang; F. Tatar; J.R. Mollinger; A. Bossche;
    {Peter Enoksson} (Ed.);
    Eurosensors, , pp. 1-4, 2006.

  101. Design, simulation and fabrication of a dielectrophoretic separation device using topographic channel structure (U_SP_2_I_IC_T)
    L. Zhang; F. Tatar; J.R. Mollinger; A. Bossche;
    IEEE, , pp. 435-438, 2006.

  102. ATTO-Liter Periodical Cavities for Optical BIO-Molecular Detection
    O. Piciu; M. van der Krogt; M. Docter; P.M. Sarro; A. Bossche;
    In Proc. IEEE Sensors 2005,
    Irvine, California, USA, pp. 452-456, Oct. 2006.

  103. Particle sorter in Microchannels (U-SP-2-I-ICT)
    A. Meilan-Garcia; O.M. Piciu; J. Bastemeijer; J.R. Mollinger; A. Bossche;
    In s.n. (Ed.), Proceedings of the Sense of Contact VIII,
    STW, pp. 1-5, 2006.

  104. Fabrication Technology of Periodical Nano-cavities for Bio-analytical Applications (U-SP-2-I-ICT)
    O.M. Piciu; M. van der KrogtC; P.M. Sarro; A. Bossche; M.W. Docter;
    In s.n. (Ed.), Proceedings of the Sense of Contact VIII,
    STW, pp. 1-6, 2006.

  105. Technique for plug dispersion compensation in moving field capillary electrophoresis application (U_SP_2_I_IC_T)
    F. Tatar; L. Zhang; J. Bastemeijer; P. Turmezei; J.R. Mollinger; A. Bossche;
    In s.n. (Ed.), Proceedings of the 5th IEEE Conference on Sensors 2006,
    IEEE, pp. 109-112, 2006.

  106. Fabrication and Optical Characterization of Nano-hole Arrays for Molecular Detections (U-SP-2-I-ICT)
    O.M. Piciu; M. van der KrogtC; P.M. Sarro; A. Bossche; M.W. Docter;
    In s.n. (Ed.), Proceedings of the 10th MicroTAS Conference 2006,
    MicroTAS, pp. 666-669, 2006.

  107. Optical Nano-hole Arrays for Molecular Recognition and Detection (U-SP-2-I-ICT)
    O.M. Piciu; M. van der KrogtC; P.M. Sarro; A. Bossche; M.W. Docter;
    In s.n. (Ed.), Proceedings of the Asia-Pacific Conference of Transducers and Micro-Nano Technology¿APCOT 2006,
    apcot, pp. 1-4, 2006.

  108. Nano-hole arrays in thin Au/Pd film on glass for high speed molecular analysis
    O. Piciu; M. van der Krogt; M. Docter; P.M. Sarro; A. Bossche;
    In S. Lee; M Esashi (Ed.), Proc. IEEE Sensors 2006 Conference,
    IEEE, pp. 608-611, 2006.

  109. Plug dispersion compensation technique in moving field capillary electrophoresis applications (U-SP-2-I-ICT)
    F. Tatar; P. Turmezei; L. Zhang; J.R. Mollinger; J. Bastemeijer; A. Bossche;
    In s.n. (Ed.), Plug dispersion compensation technique in moving field capillary electrophoresis applications,
    Eurosensors, pp. 1-4, 2006.

  110. High Throughput Continuous Separation by Electrodeless Dielectrophoresis (U-SP-2-I-ICT)
    L. Zhang; F. Tatar; A. Bossche;
    In T Kitamori; S Hasabe; F Hiroyuki (Ed.), 10th International Conference on Miniaturized Systems for Chemistry and Life Sciences, (MicroTas, 2006),
    CBMS, pp. 909-911, 2006.

  111. Moving Field Capillary Electrophoresis With Plug Dispersion Compensation (U-SP-2-I-ICT)
    F. Tatar; P. Turmezei; L. Zhang; J.R. Mollinger; J. Bastemeijer; A. Bossche;
    In s.n. (Ed.), Proceedings of the Asia-Pacific Conference of Transducers and Micro-Nano Technology¿APCOT 2006,
    apcot, pp. 1-4, 2006.

  112. Fabrication of nanofluidic devices in glass with polysilicon electrodes
    V. G. Kutchoukov; L. Pakula; G. O. F Parikesit; Y. Garini; L. K. Nanver; A. Bossche;
    Sensors and Actuators A,
    Volume 123-124, pp. 602-607, 2005.

  113. A novel concept for a mid-field microscope
    M.W. Docter; I.T. Young; V.G. Kutchoukov; A. Bossche; P.F.A. Alkemade; Y. Garini;
    Proceedings of SPIE- International Society for Optical Engineering,
    Volume 5703, pp. 118-126, 2005.

  114. Fabrication of nanofluidic devices in glass with polysilicon electrodes
    V.G. Kutchoukov; L. Pakula; G.O.F. Parikesit; Y. Garini; L.K. Nanver; A. Bossche;
    Sensors and Actuators A: Physical: an international journal devoted to research and development of physical and chemical transducers,
    Volume 123-124, pp. 602-607, 2005. 100% EI.

  115. Electroosmotic flow analysis of a branched U-turn nanofluidic device
    G.O.F. Parikesit; A.P. Markesteijn; V.G. Kutchoukov; O.M. Piciu; A. Bossche; J. Westerweel; Y. Garini; I.T. Young;
    Lab On a Chip: microfluidic and nanotechnologies for chemistry, biology, and bioengineering,
    Issue 5, pp. 1067-1074, 2005.

  116. Nanoliter array advances: miniaturized, high-speed PCR sensing & control
    I.T. Young; V.P. Iordanov; H.R.C. Dietrich; A. Bossche;
    IEEE Sensors Journal,
    pp. 2919-2922, 2005.

  117. Optical detection of electrokinetically manipulated single molecules in a nanofluidic chip
    G.O.F. Parikesit; V.G. Kutchoukov; A. Bossche; I.T. Young; Y. Garini;
    Proceedings of SPIE- International Society for Optical Engineering,
    Volume 5718, pp. 133-141, 2005.

  118. Optical detection of single molecules in nanofluidic chips
    G.O.F. Parikesit; V.G. Kutchoukov; W. van Oel; G.F. Liqui Lung; A. Bossche; I.T. Young; Y. Garini;
    Proceedings of SPIE- International Society for Optical Engineering,
    Volume 5718, pp. 133-141, 2005. phpub 39.

  119. Shape vision - progress report (October 2004-March 2005)
    A. Bossche;
    STW, , 2005.

  120. CE-micromodule - progress report (December 2004-May 2005)
    A. Bossche;
    STW, , 2005.

  121. Shape vision - progress report (June 2005-November 2005)
    A. Bossche;
    STW, , 2005.

  122. Single molecule detection in nanochannels
    O.M. Piciu; A. Bossche;
    STW, , 2005.

  123. CE-micromodule - progress report (May 2005-October 2005)
    A. Bossche;
    STW, , 2005.

  124. Single molecule detection
    O.M. Piciu; A. Bossche;
    STW, , 2005.

  125. Fabrication of nanofluidic devices in glass with polysilicon electrodes
    V. G. Kutchoukov; L. Pakula; G. O. F. Parikesit; Y. Garini; L. K. Nanver; A. Bossche;
    In Proc. Eurosensors XVIII-18th European Conference on Solid-State Sensors,
    Rome, Italy, pp. 32-35, Sep. 2005.

  126. Particle separation by dielectrophoresis
    L. Zhang; F. Tatar; P. Turmezei; J. Bastemeijer; J.R. Mollinger; A. Bossche;
    In s.n. (Ed.), SAFE f4b9ffddfab04085879c224259517fcb ProRISC,
    Dutch Technology Foundation, pp. 186-191, 2005. Editor onbekend JH/STW.

  127. SU-8 in microfluidic platform design
    P. Turmezei; J.R. Mollinger; A. Bossche;
    In s.n. (Ed.), Proceedings of the Sense of Contact 7 workshop,
    Sense of Contact 2009, pp. 1-6, 2005. Editor onbekend JH.

  128. Numerical simulation of electrokinetic force fields for particle manipulation and sorting in branched-u-turn 2D-like nanofluidic device
    G.O.F. Parikesit; A.P. Markesteijn; O.M. Piciu; V.G. Kutchoukov; J. Westerweel; A. Bossche; Y. Garini; I.T. Young;
    In s.n. (Ed.), Proceedings of the 9th International Conference on Miniaturized Systems for Chemistry and Life Sciences,
    TRF, pp. 841-843, 2005. Editor onbekend JH.

  129. 3D particle shape sensor utilizing electro-orientation
    P. Turmezei; J.R. Mollinger; A. Bossche;
    In s.n. (Ed.), Proceedings of the 9th International conference on miniaturized systems for chemistry and life sciences,
    MicroTAS, pp. 1111-1114, 2005. editors onbekend -sb.

  130. ATTO-Liter Periodical Cavities for Optical BIO-Molecular Detection
    O.M. Piciu; M. van der KrogtC; M.W. Docter; P.M. Sarro; A. Bossche;
    In s.n. (Ed.), Proceedings of IEEE Sensors, 2005,
    s.l., pp. 452-456, 2005. NEO.

  131. Electro-orientation of micro-particles in an on-chip flow cytometer
    P. Turmezei; J.R. Mollinger; A. Bossche;
    In {R Reus}, de; {S Bouwstra} (Ed.), Eurosensors XIX, Proceedings,
    IEEE, pp. 1-4, 2005.

  132. The fabrication of optical hole-arrays for use in the atto-liter titer plate device for single molecule detection
    O.M. Piciu; M. van der KrogtC; M.W. Docter; P.M. Sarro; A. Bossche;
    In {R Reus}, de; {S Bouwstra} (Ed.), Eurosensors XIX,
    IEEE, pp. 1-4, 2005.

  133. Two-frequency method for measuring the position of surgical tools with ¿m precision
    F. Tatar; J. Bastemeijer; J.R. Mollinger; A. Bossche;
    In {R Reus}, de; {S Bouwstra} (Ed.), Eurosensors XIX, proceedings,
    IEEE, pp. -, 2005. Editor onbekend.

  134. Werkwijze voor het vervaardigen van nanokanalen en nanokanalen daarmee vervaardigd
    V.G. Kutchoukov; A. Bossche; F.P.J. Laugere; W. van der Vlist;
    2005. TUD / 25%/75% ECTM/EI, sb; 1024033; TUD / 25%/75% ECTM/EI, sb.

  135. Method of manufacturing nanochannels and nanochannels thus fabricated
    V.G. Kutchoukov; A. Bossche; F.P.J. Laugere; W. van der Vlist;
    2005. TUD - 25%/75% ECTM/EI, sb; WO 2005/012159 A1; TUD - 25%/75% ECTM/EI, sb.

  136. Inrichting voor het uitvoeren van een reactie
    V.P. Iordanov; J. Bastemeijer; A. Bossche; P.M. Sarro;
    2005. TUD 25/75 ECTM/EI-sb; 1024578; TUD 25/75 ECTM/EI-sb.

  137. Microfluidic device for carrying out a reaction
    V.P. Iordanov; J. Bastemeijer; A. Bossche; P.M. Sarro;
    2005. TUD - 25/75 ECTM/EI, sb; WO2005037433; TUD - 25/75 ECTM/EI, sb.

  138. Fabrication of nanofluidic devices using glass-to-glass anodic bonding
    V.G. Kutchoukov; F. Laugere; W. van der Vlist; L. Pakula; Y. Garini; A. Bossche;
    Sensors and Actuators A: Physical: an international journal devoted to research and development of physical and chemical transducers,
    Volume 114, Issue 2-3, pp. 521-527, 2004. phpub 18.

  139. Nano-array advances: Light measurement & temperature control
    I.T. Young; V.P. Iordanov; A.R. Kroon; H.R.C. Dietrich; L.R. van den Doel; A. Bossche; P.M. Sarro; G. van DedemWK;
    Cytometry,
    Volume 59A, Issue 1, pp. 53-53, 2004. phpub 31.

  140. Through-wafer interconnect technology for silicon
    V.G. Kutchoukov; M. Shikida; J.R. Mollinger; A. Bossche;
    Journal of Micromechanics and Microengineering,
    Volume 14, pp. 1029-1036, 2004.

  141. Toward the development of a three-dimensional midfield microscope
    Y. Garini; V.G. Kutchoukov; A. Bossche; P.F.A. Alkemade; M.W. Docter; P.W. Verbeek; L. van VlietJ; I.T. Young;
    Proceedings of SPIE- International Society for Optical Engineering,
    Volume 5327, pp. 115-122, 2004. phpub 13.

  142. Filter-protected photodiodes for high-throughput enzymatic analysis
    V.P. Iordanov; J. Bastemeijer; R. Ishihara; P.M. Sarro; A. Bossche; M.J. Vellekoop;
    IEEE Sensors Journal,
    Volume 4, Issue 5, pp. 584-588, 2004. 50-50 ECTM-EI.

  143. Nano impulse progress report May 2004; optical titre plate for molecular detection
    O.M. Piciu; A. Bossche; P.M. Sarro;
    s.n., , 2004.

  144. Nanoscale elecrophoresis: a new technology for biomolecular applications
    V.G. Kutchoukov; A. Bossche;
    FOM, , 2004.

  145. Nanochannels in glass with poly-silicon electrodes
    V.G. Kutchoukov; L. Pakula; G.O.F. Parikesit; Y. Garini; L.K. Nanver; A. Bossche;
    In Proc. Eurosensors XVIII,
    Rome, Italy, Sep. 2004.

  146. Nanofluidic devices in glass with Poly-Si electrodes
    V.G. Kutchoukov; L. Pakula; G.O.F. Parikesit; L.K. Nanver; A. Bossche;
    In s.n. (Ed.), SAFE 337f38aeae344dd3ad3d46be444f765b ProRISC 2004; Proceedings of semiconductor advances for future electronics,
    STW Technology Foundation, pp. 764-768, 2004.

  147. Integrated nanoliter sensors reactor chamber for DNA multiplication - thermal characterization
    V.P. Iordanov; B.P. Iliev; J. Bastemeijer; A. Bossche; P.M. Sarro; I.T. Young; G. van DedemWK; M.J. Vellekoop;
    In G.C.M. Meijer (Ed.), The sense of contact VI; sensor workshop for industry and science,
    s.n., pp. 1-6, 2004. verdeling?.

  148. Integrated nanoliter sensors reactor chamber for PCR analysis - from the idea to a complete system
    B.P. Iliev; V.P. Iordanov; J. Bastemeijer; A. Bossche; P.M. Sarro; I.T. Young; G. van DedemWK; M.J. Vellekoop;
    In G.C.M. Meijer (Ed.), The sense of contact VI,
    s.n., pp. 1-6, 2004. phpub 32.

  149. Twin nanochannels for fluidic applications
    V.G. Kutchoukov; O.M. Piciu; J.R. Mollinger; A. Bossche;
    In G.C.M. Meijer (Ed.), The sense of contact VI; Sensor workshop for industry and science,
    s.n., pp. 1-5, 2004.

  150. Integrated sensors for nanoliter bioluminescence and fluorescence bio-chemical analysis
    V.P. Iordanov; B.P. Iliev; J. Bastemeijer; A. Bossche; P.M. Sarro; I.T. Young; H.R.C. Dietrich; L.R. van den Doel; G. van DedemWK; A.R. Kroon; M.J. Vellekoop;
    In G.C.M. Meijer (Ed.), The sense of contact VI,
    s.n., pp. 1-6, 2004. phpub 34.

  151. Microfluidic platform design from photosensitive epoxy for .-TAS
    P.B. Turmezei; J.R. Mollinger; A. Bossche;
    In The sense of contact 6: where industry meets science workshop sensortechnology,
    s.n., pp. 1-4, 2004. ed. is niet bekend.

  152. Nanochannels in Glass with Poly-Silicon Electrodes
    V.G. Kutchoukov; L. Pakula; G.O.F. Parikesit; Y. Garini; L.K. Nanver; A. Bossche;
    In s.n. (Ed.), Technical Digest of Eurosensors XVIII,
    s.n., pp. 32-35, 2004. phpub 40.

  153. Ultrasound system for measuring position and orientation of laparoscopic surgery tools
    F. Tatar; J.R. Mollinger; A. Bossche;
    In The sense of contact 6; workshop sensortechnology 2004,
    STW Technology Foundation, pp. 1-4, 2004. editor onbekend.

  154. An ultrasound system based on phase switch method for measuring position and orientation of laparoscopic surgery tools
    F. Tatar; J.R. Mollinger; A. Bossche;
    In s.n. (Ed.), Technical Digest of Eurosensors XVIII,
    s.n., pp. 1005-1008, 2004.

  155. Motion of particles in in a particle shape detector
    P.B. Turmezei; J.R. Mollinger; A. Bossche;
    In SAFE 7454339981d840bfbfb87060e9d6802e ProRISC 2004; Proceedings of semiconductor advances for future electronics,
    STW Technology Foundation, pp. 1-4, 2004. ed. is niet bekend.

  156. Fabrication of biochemical nanodevices with self-aligned electrodes
    V.G. Kutchoukov; G.O.F. Parikesit; Y. Garini; L.K. Nanver; A. Bossche;
    In s.n. (Ed.), Proceedings of the International conference on electrical engineering 2004 (ICEE 2004), Joint conference with Asia-Pacific conference of transducers and micro-nano technology 2004 (APCOT MNT 2004),
    IEEJ, pp. 1-6, 2004. ed. is niet bekend/100% ECTM.

  157. Time of flight technique used for measuring position and orientation of laparoscopic surgery tools
    F. Tatar; J.R. Mollinger; J. Bastemeijer; A. Bossche;
    In s.n. (Ed.), Proceedings of the third IEEE international conference on sensors,
    IEEE, pp. 1480-1483, 2004. niet eerder opgevoerd -sb.

  158. Integrated sensor arrays for bioluminescence and fluorescence bio-chemical analysis
    V.P. Iordanov; B.P. Iliev; A. Bossche; J. Bastemeijer; P.M. Sarro; I.T. Young; G. van DedemWK; M.J. Vellekoop;
    In D. Rocha; P.M. Sarro; M.J. Vellekoop (Ed.), Proceedings of IEEE Sensors, 2004,
    IEEE, Piscataway, pp. 810-813, 2004. niet eerder opgevoerd 50/50 EI/ECTM.

  159. New ultrasound system for measuring position and orientation of laparoscopic surgery tools
    F. Tatar; J.R. Mollinger; V.G. Kutchoukov; A. Bossche;
    In ICEE2004; Conference proceedings of the international conference on electrical engineering 2004,
    The Institute of Electrical Engineers of Japan, pp. 847-850, 2004. ed. is niet bekend.

  160. SU-8 microfluidic platform design
    P.B. Turmezei; M. Achtsnick; J.R. Mollinger; A. Bossche;
    In S.n. (Ed.), EUROSENSORS XVIII; 18th European conference on solid-state sensors,
    s.n., pp. 1-4, 2004. ed. is niet bekend.

  161. Miniaturized analytical assays in biotechnology
    R.M. van Guijt; R. Moerman; A.R. Kroon; G. van DedemWK; R. van den Doel; L. van Vliet; I.T. Young; F.P.J. Laugere; A. Bossche; P.M. Sarro;
    Biotechnology Advances: research reviews,
    Volume 21, Issue 5, pp. 431-444, 2003. 50/50 EI/ECTM.

  162. Monitoring enzymatic reactions with in situ sensors
    I.T. Young; V.P. Iordanov; A.R. Kroon; H.R.C. Dietrich; R. Moerman; L.R. van den Doel; G. van DedemWK; A. Bossche; B.L. Gray; P.M. Sarro; P.W. Verbeek; L. van VlietJ;
    Proceedings of SPIE- International Society for Optical Engineering,
    Volume 4966, pp. 76-82, 2003.

  163. On-chip contactless four-electrode conductivity detection for capillary electrophoresis devices
    F.P.J. Laugere; R.M. van Guijt; J. Bastemeijer; G. van der Steen; A. Berthold; H.A. Baltussen; P.M. Sarro; G. van DedemWK; M.J. Vellekoop; A. Bossche;
    Analytical Chemistry,
    Volume 75, Issue 2, pp. 306-312, 2003.

  164. Monitoring enzymatic reactions in nanolitre wells
    I.T. Young; R. Moerman; L.R. van den Doel; V.P. Iordanov; A.R. Kroon; H.R.C. Dietrich; G. van DedemWK; A. Bossche; B.L. Gray; P.M. Sarro; P.W. Verbeek; L. van VlietJ;
    Journal of Microscopy,
    Volume 212, Issue 3, pp. 254-263, 2003. 50/50 EI/ECTM.

  165. Near-field optical sensors for particle shape measurements
    J.H. Nieuwenhuis; J. Bastemeijer; A. Bossche; M.J. Vellekoop;
    IEEE Sensors Journal,
    Volume 3, Issue 5, pp. 646-651, 2003.

  166. Toward the development of a three-dimentional mid-field microscope
    Y. Garini; V.G. Kutchoukov; A. Bossche; P.F.A. Alkemade; I.T. Young;
    s.n. (Ed.);
    European Optical Society, , pp. 70-71, 2003.

  167. Fabrication of Nanochannels Using Glass to Glass Anodic Bonding
    V.G. Kutchoukov; F. Laugere; W. van der Vlist; L. Pakula; Y. Garini; P.F.A. Alkemade; A. Bossche;
    In Transducers,
    Boston, Massachuesetts, USA, pp. 1327-1330, Jun. 2003. ISBN 0-7803-7731-1.

  168. Low-Cost Microfilter for Red Blood Cell Membrane Stiffness Measurement Using Photosensitive BCB
    P. Turmezei; A. Polyakov; J.R. Mollinger; M. Bartek; A. Bossche; J.N. Burghartz;
    In Transducers,
    Boston, Massachuesetts, USA, pp. 107-110, Jun. 2003. ISBN 0-7803-7731-1.
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  169. Microfluidic device constructed from photosensitive BCB for erythrocyte membrane deformability measurement
    P. Turmezei; A. Polyakov; J.R. Mollinger; M. Bartek; A. Bossche; J.N. Burghartz;
    In Proc. Eurosensors XVII,
    University of Minho, Guimaraes, Portugal, pp. 193-196, Sep. 2003.

  170. Low-cost microfilter for red blood cell membrane stiffness measurement using photosensitive BCB
    P.B. Turmezei; A. Poliakov; J.R. Mollinger; M. Bartek; A. Bossche; J.N. Burghartz;
    In TRANSDUCERS'03 Twelfth international conference on solid-state sensors, actuators and microsystems,
    IEEE, pp. 107-110, 2003. CD-ROM.

  171. Fabrication of nanochannels using glass to glass anodic bonding
    V.G. Kutchoukov; F.P.J. Laugere; W. van der Vlist; L. Pakula; Y. Garini; P.F.A. Alkemade; A. Bossche;
    In s.n. (Ed.), TRANSDUCERS'03 Twelfth international conference on solid-state sensors, actuators and microsystems,
    IEEE, pp. 1327-1330, 2003. CD-ROM.

  172. Nanochannel fabrication technique for fluidic applications
    V.G. Kutchoukov; L. Pakula; Y. Garini; J.R. Mollinger; A. Bossche;
    In s.n. (Ed.), SAFE 2003 Semiconductor advances for future electronics,
    Stichting voor de Technische Wetenschappen, pp. 702-706, 2003. CD-ROM.

  173. Ultrasound system for measuring position and orientation of laparoscopic surgery tools
    F. Tatar; J.R. Mollinger; A. Bossche;
    In IEEE Sensors 2003,
    IEEE, pp. 987-990, 2003. CD-ROM.

  174. PCR Array on chip - thermal characterization
    V.P. Iordanov; J. Bastemeijer; A. Bossche; P.M. Sarro; M. Malatek; I.T. Young; G. van DedemWK; M.J. Vellekoop;
    In s.n. (Ed.), IEEE Sensors 2003,
    IEEE, pp. 1045-1048, 2003. CD-rom 50/50 EI/ECTM.

  175. Fabrication technology for nanofluidic channel devices for biochemical applications
    V.G. Kutchoukov; L. Pakula; Y. Garini; J.R. Mollinger; A. Bossche;
    In s.n. (Ed.), MME 2003 14th Micromechanics Europe workshop,
    s.n., pp. 167-170, 2003.

  176. Investigating cross correlation method for measuring position and orientation of laparoscopic surgery tools
    F. Tatar; J.R. Mollinger; A. Bossche;
    In s.n. (Ed.), IMTC 2003 20th IEEE instrumentation and measurement technology conference,
    IEEE, pp. 283-286, 2003. CD-ROM.

  177. Cross-correlation method applied to an ultrasound system for measuring position and orientation of laproscopic surgery tools
    F. Tatar; J.R. Mollinger; P.B. Turmezei; A. Bossche;
    In D Ilic; M Borsic; J Butorac (Ed.), IMEKO 2003 17th IMEKO World congress; Metrology in the third millennium,
    IMEKO, pp. 1506-1509, 2003.

  178. Digital processing techniques used to improve the measuring accuracy for the position and orientation of laparoscopic surgery tools
    F. Tatar; J.R. Mollinger; A. Bossche;
    In s.n. (Ed.), WC 2003 World congress on medical physics and biomedical engineering,
    World Congress on Medical Physics and Biomedical Engineering, pp. 1-4, 2003. CD-ROM.

  179. Microfluidic device constructed from photosensitive BCB for erythrocyte membrane deformability measurement
    P.B. Turmezei; A. Poliakov; J.R. Mollinger; M. Bartek; A. Bossche; J.N. Burghartz;
    In EUROSENSORS 17th European conference on solid-state transducers,
    University of Minho, pp. 293-296, 2003.

  180. Fabrication technology for twin nanochannels
    V.G. Kutchoukov; L. Pakula; J.R. Mollinger; A. Bossche;
    In s.n. (Ed.), EUROSENSORS 17th European conference on solid-state transducers,
    University of Minho, pp. 623-626, 2003. CD-ROM.

  181. Digital processing technique applied to new ultrasound system for measuring position and orientation of laparoscopic surgery tools
    F. Tatar; J.R. Mollinger; P.B. Turmezei; A. Bossche;
    In s.n. (Ed.), EUROSENSORS 17th European conference on solid-state transducers,
    University of Minho, pp. 752-755, 2003.

  182. The improvement in measuring position and orientation of laparoscopic toolls using the cross correlation method
    F. Tatar; J.R. Mollinger; R.C. den Dulk; W.A. van Duyl; J.F.L. Goosen; A. Bossche;
    In s.n. (Ed.), ProRISC 2003 Program for research on integrated systems and circuits,
    Stichting voor de Technische Wetenschappen, pp. 437-440, 2003. CD-ROM.

  183. Environment-induced failure modes of thin film resensors
    R. Kazinczi; J.R. Mollinger; A. Bossche;
    Journal of Microlithography, Microfabrication, and Microsystems,
    Volume 1, Issue 1, pp. 63-69, 2002.

  184. Ultrasonic sensor system for measuring position and orientation of laproscopic surgery tools
    F. Tatar; J.R. Mollinger; R.C. den Dulk; W.A. van Duyl; J.F.L. Goosen; A. Bossche;
    Xiamen University Press, , pp. 457-460, 2002.

  185. Adsorption-induced failure modes of thin-film resonators
    R. Kazinczi; J.R. Mollinger; A. Bossche;
    CS Ozkan; {et al.} (Ed.);
    Materials Research Society, , pp. 1-6, 2002.

  186. Design of low-cost resonant mode sensors
    R. Kazinczi; P.B. Turmezei; J.R. Mollinger; A. Bossche;
    PD Franzon (Ed.);
    SPIE - The International Society for Optical Engineering, , pp. 54-61, 2002.

  187. CMOS-compatible wells for integrated high-speed screening arrays
    B.L. Gray; R. Moerman; L.R. van den Doel; H.R. Dietrich; V.P. Iordanov; N.P. Pham; L.M. Sarro; A. Bossche; M.J. Vellekoop;
    In Proc. SPIE: Biomedical Nanotechnology Architectures and Applications,
    pp. 103-108, Jan. 2002.

  188. Photoresist wells for integrated high-speed screening arrays
    B.L. Gray; R. Moerman; L.R. van den Doel; V.P. Iordanov; N.P. Pham; P.M. Sarro; A. Bossche; M.J. Vellekoop;
    In Proc. SESENS 2002,
    Veldhoven, The Netherlands, pp. 791-794, Nov. 2002. ISBN 90-73461-28-6.

  189. Filtered Photodiode Arrays for NADH Fluorescence Analysis
    V.P. Iordanov; J. Bastemeijer; R. Ishihara; P.M. Sarro; A. Bossche; M. Vellekoop;
    In Proc. SeSens 2002,
    Veldhoven, The Netherlands, STW, pp. 627-630, Nov. 2002. ISBN 90-73461-33-2.

  190. Fluorescence Measurements in Thick-Film Polymer Wells
    B.L. Gray; V.P. Iordanov; R. van den Doel; P.M. Sarro; A. Bossche;
    In Proc. SeSens 2002,
    Veldhoven, The Netherlands, STW, pp. 622-626, Nov. 2002. ISBN 90-73461-33-2.

  191. CMOS-Compatible Optical Filter for High-Throughput Enzymatic-Analysis Devices
    V.P. Iordanov; R. Ishihara; P.M. Sarro; J. Bastemeijer; A. Bossche; M.J. Vellekoop;
    In IEEE Sensors 2002,
    Hyatt Orlando, Orlando, Florida, USA, pp. 9.6/1-9.6/4, Jun. 2002. ISBN 0-7803-7455-X.

  192. Electronic baseline-suppression for liquid conductivity detection in a capillary electrophoresis microchip
    F. Laugere; J. Bastemeijer; G. van der Steen; M.J. Vellekoop; P.M. Sarro; A. Bossche;
    In IEEE Sensors 2002,
    Hyatt Orlando, Orlando, Florida, USA, pp. 20.3/1-20.3/4, Jun. 2002. ISBN 0-7803-7455-X.

  193. Ultrasonic sensor system for measuring position and orientation of laproscopic instruments in minimal invasive surgery
    F. Tatar; J.R. Mollinger; R.C. den Dulk; W.A. van Duyl; J.F.L. Goosen; A. Bossche;
    In Second annual international IEEE-EMBS special topic conference on microtechnologies in medice and biology: proceedings,
    IEEE, pp. 301-304, 2002.

  194. A novel readout system for microacoustic viscosity sensors
    J. Bastemeijer; B.H. Jakoby; A. Bossche; M.J. Vellekoop;
    In s.n. (Ed.), Proceedings of the 2002 IEEE ultrasonics symposium,
    IEEE, pp. 489-492, 2002. CD-ROM.

  195. Filtered photodiode arrays for NADH fluorescence analysis
    V.P. Iordanov; J. Bastemeijer; R. Ishihara; P.M. Sarro; A. Bossche; M.J. Vellekoop;
    In Proceedings of SeSens 2002,
    STW Stichting voor de Technische Wetenschappen, pp. 627-630, 2002.

  196. Fluorescence measurements in thick-film polymer wells
    B.L. Gray; V.P. Iordanov; P.M. Sarro; A. Bossche;
    In Proceedings of SeSens 2002,
    STW Stichting voor de Technische Wetenschappen, pp. 622-626, 2002.

  197. Frequency detection method for measuring position and orientation of laproscopic surgery tools
    F. Tatar; J.R. Mollinger; R.C. den Dulk; W.A. van Duyl; J.F.L. Goosen; A. Bossche;
    In Proceedings of SeSens 2002,
    STW Stichting voor de Technische Wetenschappen, pp. 684-687, 2002.

  198. P1.1: Dynamic particle-shape measurements using a near-field optical sensor
    J.H. Nieuwenhuis; J. Bastemeijer; A. Bossche; M.J. Vellekoop;
    In Proceedings of IEEE sensors 2002: first international conference on sensors,
    IEEE, pp. 130-133, 2002.

  199. Separation and detection of organic acids in a CE microchip with contactless four-electrode conductivity detection
    F.P.J. Laugere; G. van der Steen; J. Bastemeijer; R.M. van Guijt; P.M. Sarro; M.J. Vellekoop; A. Bossche;
    In Y Baba; S Shoji; {van den Berg}, A (Ed.), Micro total analysis systems 2002: proceedings of the µTAS 2002 symposium, held in Nara, Japan, 3-7 November 2002,
    Kluwer Academic Publishers, pp. 491-493, 2002.

  200. 9.6: CMOS compatible optical filter for high-throughput enzymatic analysis devices
    V.P. Iordanov; R. Ishihara; P.M. Sarro; J. Bastemeijer; A. Bossche; M.J. Vellekoop;
    In Proceedings of IEEE sensors 2002: first IEEE international conference on sensors. Vol. I,
    IEEE, pp. 225-228, 2002.

  201. 20.3: Electronic baseline-suppression for liquid conductivity detection in a capillary electrophoresis microchip
    F.P.J. Laugere; J. Bastemeijer; G. van der Steen; M.J. Vellekoop; P.M. Sarro; A. Bossche;
    In Proceedings of IEEE sensors 2002: first IEEE international conference on sensors. Vol. 1,
    IEEE, pp. 450-453, 2002.

  202. Copper film microgrid through-wafer metalization
    V.G. Kutchoukov; G. Craciun; S. Sakarya; J.R. Mollinger; A. Bossche;
    In MME'02 micromechanics Europe,
    Nat. Inst. for Res. an developmnet in Microtechnologies, pp. 91-94, 2002.

  203. SU-8 structures for integrated high-speed screening
    B.L. Gray; V.P. Iordanov; P.M. Sarro; A. Bossche;
    In Y Baba; S Shoji; {van den Berg}, A (Ed.), Micro total analysis systems 2002; proceedings of the µTAS 2002 symposium,
    Kluwer Academic Publishes, pp. 464-466, 2002.

  204. Integrated particle shape sensor
    P.B. Turmezei; J.H. Nieuwenhuis; J.R. Mollinger; A. Bossche;
    In Kandó conference 2002: 60 years of engineering training,
    Budapest Polytechnic, pp. 1-4, 2002. CD-Rom.

  205. Measurement position and orientation of surgery tools inside the human body using ultrasound
    F. Tatar; J.R. Mollinger; R.C. den Dulk; W.A. van Duyl; J.F.L. Goosen; A. Bossche;
    In I Margineanu; {et al.} (Ed.), International conference on optimization of electrical and electronic equipments - OPTM 2002,
    Transilvania University Press, pp. 721-724, 2002.

  206. Full-decoupling technique for onecolumn liquid-conductivity detection in capillary electrophoresis microchip
    F.P.J. Laugere; J. Bastemeijer; M.J. Vellekoop; A. Bossche;
    In Eurosensors 2002,
    Czech Technical University, pp. 505-508, 2002.

  207. CMOS-compatible wells for integrated high-speed screening arrays
    B.L. Gray; R. Moerman; L.R. van den Doel; H.R.C. Dietrich; V.P. Iordanov; N.P. Pham; P.M. Sarro; A. Bossche; M.J. Vellekoop;
    In DJ Bornhop; DA Dunn; RP Mariella; CJ Murphy; DV Nicolau; Shuming Nie; M Palmer; R Raghavachari (Ed.), Biomedical Nanotechnology Architectures and Applications, Proceedings,
    SPIE, pp. 103-108, 2002. ISSN 0277-786X, phpub 31.

  208. Suitabilty of FEA software for shealth flow simulation
    P.B. Turmezei; J.H. Nieuwenhuis; J.R. Mollinger; A. Bossche;
    In Proceedings od SeSens 2002,
    STW Stichting voor de Technische Wetenschappen, pp. 692-695, 2002.

  209. Patterning of polyimide and metal in deep trenches
    V.G. Kiutchoukov; J.R. Mollinger; M. Shikida; A. Bossche;
    Sensors and Actuators A: Physical: an international journal devoted to research and development of physical and chemical transducers,
    Volume 92, pp. 208-213, 2001.

  210. Reliability issues on MEMS resonators
    R. Kazinczi; J.R. Mollinger; A. Bossche;
    s.n., , 2001. DEL.3780.

  211. Progress report biomas project
    F.P.J. Laugere; M.J. Vellekoop; A. Bossche;
    s.n., , 2001. NV:DST 4351.

  212. Polycrystalline silicon thin-film on glass as a UV filter for NADH fluorescence measuremants
    V.P. Jordanov; R. Ishihara; P.M. Sarro; M.J. Vellekoop; R.F. Wolffenbuttel; J. Bastemeijer; A. Bossche;
    STW Technology Foundation, , pp. 799-802, 2001.

  213. Photoresist wells for integrated high-speed screening arrays
    B.L. Gray; R. Moerman; L.R. van den Doel; V.P. Jordanov; P.N. Pham; P.M. Sarro; A. Bossche; M.J. Vellekoop;
    In SAFE - ProRISC - SeSense 2001: proceedings. Semiconductor Advances for Future Eelctornics - Program for Research on Integrated Systems and Circuits - Semiconductor Sensor and Actuator Technology,
    STW Technology Foundation, pp. 791-794, 2001.

  214. FEM study on the dependence of resonant frequency shift on mechanical stress of thin film resonator
    SS. Lee; R. Kazinczi; J.R. Mollinger; M.J. Vellekoop; A. Bossche;
    In SAFE - ProRISC - SeSens 2001: proceedings. Semiconductor Advances for Fututre Electronics - Program for Research on Integrated Systems and Circuits - Semiconductor Sensor and Actuator Technology,
    STW Technology Foundation, pp. 817-820, 2001.

  215. New fabrication technology for wafer-through hole interconnects
    V.G. Kiutchoukov; E. Boellaard; J.R. Mollinger; A. Bossche;
    In SAFE - ProRISC - SeSens: proceedings. Semiconductor Advances for Future Electronics - Program for Research on Integrated Systems and Circuits - Semiconductor Sensor and Actuator Technology,
    STW Technology Foundation, pp. 813-817, 2001.

  216. Photodiode structures to measure the shape of particles and cells
    J.H. Nieuwenhuis; SS. Lee; J. Bastemeijer; A. Bossche; M.J. Vellekoop;
    In SAFE - ProRISC - SeSens 2001: proceedings. Semiconductor Advances for Future Electronics - Program for Research on Integrated Systems and Circuits - Semiconductor Sensor and Actuator Technology,
    STW Technology Foundation, pp. 839-842, 2001.

  217. Acoustic sensor system for measuring position and orientation of laproscopic instruments in minimal invasive surgery
    F. Tatar; J.R. Mollinger; R.C. den Dulk; W.A. van Duyl; A. Bossche;
    In SAFE - ProRISC - SeSens 2001: proceedings. Semiconductor Advances for Future Electronics - Program for Research on Integrated Systems and Circuits - Semiconductor Sensor and Actuator Technology,
    STW Technology Foundation, pp. 873-877, 2001.

  218. 3- D resonator bridges as sensing elements
    R. Kazinczi; J.R. Mollinger; A. Bossche;
    In SAFE - ProRISC - SeSens 2001: proceeding. Semiconductor Advances for Future Electronics - Program for Research on Integrated System and Circuits - Semiconductor sensor and Actuator Technology,
    STW Technology Foundation, pp. 803-808, 2001.

  219. Design of low-cost resonant mode sensors
    R. Kazinczi; P.B. Turmezei; J.R. Mollinger; A. Bossche;
    In {PD Franzon} (Ed.), Proceedings of SPIE Vol. 4593,
    SPIE Press, pp. 54-61, 2001.

  220. Novel wafer-through technique for interconnects
    V.G. Kiutchoukov; J.R. Mollinger; A. Bossche;
    In {PD Franzon} (Ed.), Proceedings of SPIE Vol. 4593,
    SPIE Press, pp. 274-282, 2001.

  221. Forming rounded convex corner by using two-step anisotropic koh wet etching
    V.G. Kiutchoukov; M. Shikida; M. Bao; J.R. Mollinger; A. Bossche;
    In {M Elwenspoek} (Ed.), Proceedings,
    Kluwer, pp. 161-166, 2001.

  222. Corner rounding-powerful tool for uniform photoresist coating
    V.G. Kutchoukov; M. Bao; M. Shikida; J.R. Mollinger; A. Bossche;
    In Electronics ET'2001: proceedings of the conference book 1,
    Technical University Sofia, pp. 73-80, 2001. niet eerder opgevoerd.

  223. Inexpensive mems packaging
    R. Kazinczi; J.R. Mollinger; A. Bossche;
    In {M Elwenspoek} (Ed.), Proceedings,
    Kluwer, pp. 59-64, 2001.

  224. Versatile tool for characterising long-term stability and reliabity of micromechanical structures
    R. Kazinczi; J.R. Mollinger; A. Bossche;
    Sensors and Actuators A: Physical: an international journal devoted to research and development of physical and chemical transducers,
    Volume 85, Issue 1-3, pp. 84-89, 2000.

  225. New photoresist coating method for 3-D structured wafers
    V.G. Kiutchoukov; J.R. Mollinger; A. Bossche;
    Sensors and Actuators A: Physical: an international journal devoted to research and development of physical and chemical transducers,
    Volume 85, Issue 1-3, pp. 377-383, 2000.

  226. Report on moulding experiments with soft structured mould inserts
    A. Bossche;
    s.n., , 2000.

  227. Coating of deep anisotropically etched grooves with polymide and photoresist
    V.G. Kiutchoukov; J.R. Mollinger; A. Bossche;
    In {JP Veen} (Ed.), SAFE-ProRISC-SeSens 2000: proceedings,
    STW Technology Foundation, pp. 655-658, 2000.

  228. Long-term stability of SiC resonators
    R. Kazinczi; J.R. Mollinger; A. Bossche;
    In SAFE-ProRISC-SeSens 2000: proceedings,
    STW Technology Foundation, pp. 647-650, 2000.

  229. Environment induced failure modes of thin film resonators
    R. Kazinczi; J.R. Mollinger; A. Bossche;
    In {AR Wilson}; {H Asanuma} (Ed.), Proceedings of SPIE. Vol. 4234,
    International Society for Optical Engineering, pp. 1-11, 2000.

  230. New failure mechanism in silicon nitride resonators
    R. Kazinczi; J.R. Mollinger; A. Bossche;
    In MEMS 2000: proceedings,
    IEEE, pp. 229-234, 2000.

  231. Down-scale problems of resonant SiC devices
    R. Kazinczi; J.R. Mollinger; A. Bossche;
    In {AP Lee} (Ed.), Micro-Electro-Mechanical Systems (MEMS) 2000, vol. 2,
    ASME, pp. 221-225, 2000.

  232. Patterning of polyimide and metal in deep grooves
    V.G. Kiutchoukov; J.R. Mollinger; A. Bossche;
    In {R Reus}, de; {S Bouwstra} (Ed.), Eurosensors XIV,
    Mikroelektronik Centret, pp. 467-470, 2000.

  233. Etching behavior of KOH at the convex corner
    V.G. Kiutchoukov; M. Bao; A. Bossche;
    In ET'2000: proceedings book 2,
    s.n., pp. 128-133, 2000.

  234. Application of the integrated reliability analysis system (IRAS)
    G. Kócza; A. Bossche;
    Reliability Engineering & System Safety,
    Volume 64, pp. 99-107, 1999.

  235. Finite element analysis of the open window plastic package for optical sensors
    C.V.B. Cotofana; A. Bossche;
    Sensors and Actuators A: Physical: an international journal devoted to research and development of physical and chemical transducers,
    Volume 76, Issue 1-3, pp. 386-394, 1999.

  236. Reliability of silicon nitride as structural material in MEMS
    R. Kazinczi; J.R. Mollinger; A. Bossche;
    {Y Vladimirsky}; {CR Friedrich} (Ed.);
    International Society for Optical Engineering, , pp. 174-183, 1999.

  237. Uniform photoresist coating of anisotropically etched cavities in silicon
    V.G. Kiutchoukov; J.R. Mollinger; A. Bossche;
    In SAFE99: proceedings. ProRISC99:proceedings,
    STW Technology Foundation, pp. 697-700, 1999.

  238. Mechanical aspects of reliability of micromechanical structures
    R. Kazinczi; J.R. Mollinger; A. Bossche;
    In SAFE99: proceedings. ProRISC99: proceedings [CD-ROM],
    STW Technology Foundation, pp. 225-232, 1999.

  239. A study of the reliability of passivation layers for sensor applications
    P.J. Trimp; J.R. Mollinger; A. Bossche; F.R. Riedijk; P.J. French;
    In {M. Bartek} (Ed.), Eurosensors XIII: proceedings [CD-ROM],
    Delft University of Technology, pp. 823-826, 1999.

  240. Versatile tool for characterising long term stability and reliability of micromechanical structures
    R. Kazinczi; J.R. Mollinger; A. Bossche;
    In {M. Bartek} (Ed.), Eurosensors XIII: proceedings [CD-ROM],
    Delft University of Technology, pp. 1-5, 1999.

  241. Novel method for spinning of photoresist on wafers with through-holes
    V.G. Kiutchoukov; J.R. Mollinger; A. Bossche;
    In {M. Bartek} (Ed.), Eurosensors XIII: proceedings [CD-ROM],
    Delft University of Technology, pp. 277-280, 1999.

  242. Novel method for spinning of photoresist on wafers with through-holes
    V.G. Kiutchoukov; A. Bossche; J.R. Mollinger;
    In {M. Bartek} (Ed.), Eurosensors XIII: book of abstracts,
    Delft University of Technology, pp. 137-138, 1999.

  243. Rounding of wafer - hole corners in -oriented silicon wafer by anisotropic etching
    V.G. Kiutchoukov; J.R. Mollinger; A. Bossche;
    In Electronics '99,
    Technical University Sofia, pp. 102-106, 1999.

  244. Magnetic-field measurements using an integrated resonant magnetic-field sensor [niet eerder opgevoerd]
    Z. Kádár; A. Bossche; P.M. Sarro; J.R. Mollinger;
    Sensors and Actuators A: Physical: an international journal devoted to research and development of physical and chemical transducers,
    Volume 70, pp. 225-232, 1998.

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