Your search keyword '"Wu, A. (author)"' showing total 7 results

1. Lipid detection in atherosclerotic human coronaries by spectroscopic intravascular photoacoustic imaging

Author

Jansen, K. (author), Wu, M. (author), Van der Steen, A.F.W. (author), Van Soest, G. (author), Jansen, K. (author), Wu, M. (author), Van der Steen, A.F.W. (author), and Van Soest, G. (author)

Abstract

The presence of lipids in atherosclerotic coronary lesions is an important determinant of their potential to trigger acute coronary events. Spectroscopic intravascular photoacoustic imaging (sIVPA) has the potential to automatically detect lipids in atherosclerotic lesions. For realtime in vivo imaging, limiting the number of excitation wavelengths is crucial. We explored methods for plaque lipid detection using sIVPA, with the aim to minimize the number of laser pulses per image line. A combined intravascular ultrasound (IVUS) and photoacoustic imaging system was used to image a vessel phantom and human coronary arteries ex vivo. We acquired co-registered cross-sectional images at several wavelengths near 1200 nm, a lipid-specific absorption band. Correlating the photoacoustic spectra at 6 or 3 wavelengths from 1185 to 1235 nm with the absorption spectrum of cholesterol and peri-adventitial tissue, we could detect and differentiate the lipids in the atherosclerotic plaque and peri-adventitial lipids, respectively. With two wavelengths, both plaque and peri-adventitial lipids were detected but could not be distinguished., ImPhys/Imaging Physics, Applied Sciences

Published

2013

2. Lipid detection in atherosclerotic human coronaries by spectroscopic intravascular photoacoustic imaging

Author

Jansen, K. (author), Wu, M. (author), Van der Steen, A.F.W. (author), Van Soest, G. (author), Jansen, K. (author), Wu, M. (author), Van der Steen, A.F.W. (author), and Van Soest, G. (author)

Abstract

The presence of lipids in atherosclerotic coronary lesions is an important determinant of their potential to trigger acute coronary events. Spectroscopic intravascular photoacoustic imaging (sIVPA) has the potential to automatically detect lipids in atherosclerotic lesions. For realtime in vivo imaging, limiting the number of excitation wavelengths is crucial. We explored methods for plaque lipid detection using sIVPA, with the aim to minimize the number of laser pulses per image line. A combined intravascular ultrasound (IVUS) and photoacoustic imaging system was used to image a vessel phantom and human coronary arteries ex vivo. We acquired co-registered cross-sectional images at several wavelengths near 1200 nm, a lipid-specific absorption band. Correlating the photoacoustic spectra at 6 or 3 wavelengths from 1185 to 1235 nm with the absorption spectrum of cholesterol and peri-adventitial tissue, we could detect and differentiate the lipids in the atherosclerotic plaque and peri-adventitial lipids, respectively. With two wavelengths, both plaque and peri-adventitial lipids were detected but could not be distinguished., ImPhys/Imaging Physics, Applied Sciences

Published

2013

3. Linear variable optical filter-based ultraviolet microspectrometer

Author

Emadi, A. (author), Wu, H. (author), De Graaf, G. (author), Enoksson, P. (author), Higino Correia, J. (author), Wolffenbuttel, R. (author), Emadi, A. (author), Wu, H. (author), De Graaf, G. (author), Enoksson, P. (author), Higino Correia, J. (author), and Wolffenbuttel, R. (author)

Abstract

An IC-compatible linear variable optical filter (LVOF) for application in the UV spectral range between 310 and 400 nm has been fabricated using resist reflow and an optimized dry-etching. The LVOF is mounted on the top of a commercially available CMOS camera to result in a UV microspectrometer. A special calibration technique has been employed that is based on an initial spectral measurement on a xenon lamp. The image recorded on the camera during calibration is used in a signal processing algorithm to reconstruct the spectrum of the mercury lamp and the calibration data is subsequently used in UV spectral measurements. Experiments on a fabricated LVOF-based microspectrometer with this calibration approach implemented reveal a spectral resolution of 0.5 nm., Microelectronics, Electrical Engineering, Mathematics and Computer Science

Published

2012

4. Design and implementation of a sub-nm resolution microspectrometer based on a Linear-Variable Optical Filter

Author

Emadi, A. (author), Wu, H. (author), De Graaf, G. (author), Wolffenbuttel, R.F. (author), Emadi, A. (author), Wu, H. (author), De Graaf, G. (author), and Wolffenbuttel, R.F. (author)

Abstract

In this paper the concept of a microspectrometer based on a Linear Variable Optical Filter (LVOF) for operation in the visible spectrum is presented and used in two different designs: the first is for the narrow spectral band between 610 nm and 680 nm, whereas the other is for the wider spectral band between 570 nm and 740 nm. Design considerations, fabrication and measurement results of the LVOF are presented. An iterative signal processing algorithm based on an initial calibration has been implemented to enhance the spectral resolution. Experimental validation is based on the spectrum of a Neon lamp. The results of measurements have been used to analyze the operating limits of the concept and to explain the sources of error in the algorithm. It is shown that the main benefits of a LVOF-based microspectrometer are in case of implementation in a narrowband application. The realized LVOF microspectrometers show a spectral resolution of 2.2 nm in the wideband design and 0.7 nm in the narrowband design., Microelectronics, Electrical Engineering, Mathematics and Computer Science

Published

2011

5. Design and implementation of a sub-nm resolution microspectrometer based on a Linear-Variable Optical Filter

Author

Emadi, A. (author), Wu, H. (author), De Graaf, G. (author), Wolffenbuttel, R.F. (author), Emadi, A. (author), Wu, H. (author), De Graaf, G. (author), and Wolffenbuttel, R.F. (author)

Abstract

In this paper the concept of a microspectrometer based on a Linear Variable Optical Filter (LVOF) for operation in the visible spectrum is presented and used in two different designs: the first is for the narrow spectral band between 610 nm and 680 nm, whereas the other is for the wider spectral band between 570 nm and 740 nm. Design considerations, fabrication and measurement results of the LVOF are presented. An iterative signal processing algorithm based on an initial calibration has been implemented to enhance the spectral resolution. Experimental validation is based on the spectrum of a Neon lamp. The results of measurements have been used to analyze the operating limits of the concept and to explain the sources of error in the algorithm. It is shown that the main benefits of a LVOF-based microspectrometer are in case of implementation in a narrowband application. The realized LVOF microspectrometers show a spectral resolution of 2.2 nm in the wideband design and 0.7 nm in the narrowband design., Microelectronics, Electrical Engineering, Mathematics and Computer Science

Published

2011

6. High-resolution microspectrometer with an aberration-correcting planar grating

Author

Grabarnik, S. (author), Emadi, A. (author), Wu, H. (author), De Graaf, G. (author), Wolffenbuttel, R.F. (author), Grabarnik, S. (author), Emadi, A. (author), Wu, H. (author), De Graaf, G. (author), and Wolffenbuttel, R.F. (author)

Abstract

A concept for a highly miniaturized spectrometer featuring a two-component design is presented. The first component is a planar chip that integrates an input slit and aberration-correcting diffraction grating with an image sensor and is fabricated using microelectromechanical systems (MEMS) technologies. Due to the fabrication in a simple MEMS batch process the essential elements of the spectrometer are automatically aligned, and a low fabrication cost per device can be achieved. The second component is a spherical mirror, which is the only external part. The optimized grating structure compensates for aberrations within the spectrometer operating range, resulting in a diffraction-limited performance of the spectrometer optics. The prototype of the device has been fabricated and characterized. It takes a volume of 0:5cm³ and provides a FWHM spectral resolution of 0:7nm over a 350nm bandwidth from 420nm to 770nm combined with an etendue of 7:4 × 10?5 mm² sr., Micro Electronics, Electrical Engineering, Mathematics and Computer Science

Published

2008

7. High-resolution microspectrometer with an aberration-correcting planar grating

Author

Grabarnik, S. (author), Emadi, A. (author), Wu, H. (author), De Graaf, G. (author), Wolffenbuttel, R.F. (author), Grabarnik, S. (author), Emadi, A. (author), Wu, H. (author), De Graaf, G. (author), and Wolffenbuttel, R.F. (author)

Abstract

A concept for a highly miniaturized spectrometer featuring a two-component design is presented. The first component is a planar chip that integrates an input slit and aberration-correcting diffraction grating with an image sensor and is fabricated using microelectromechanical systems (MEMS) technologies. Due to the fabrication in a simple MEMS batch process the essential elements of the spectrometer are automatically aligned, and a low fabrication cost per device can be achieved. The second component is a spherical mirror, which is the only external part. The optimized grating structure compensates for aberrations within the spectrometer operating range, resulting in a diffraction-limited performance of the spectrometer optics. The prototype of the device has been fabricated and characterized. It takes a volume of 0:5cm³ and provides a FWHM spectral resolution of 0:7nm over a 350nm bandwidth from 420nm to 770nm combined with an etendue of 7:4 × 10?5 mm² sr., Micro Electronics, Electrical Engineering, Mathematics and Computer Science

Published

2008