J.J. Niederhauser scite author profile

In optoacoustic imaging, short laser pulses irradiate highly scattering human tissue and adiabatically heat embedded absorbing structures, such as blood vessels, to generate ultrasound transients by means of the thermoelastic effect. We present an optoacoustic vascular imaging system that records these transients on the skin surface with an ultrasound transducer array and displays the images online. With a single laser pulse a complete optoacoustic B-mode image can be acquired. The optoacoustic system exploits the high intrinsic optical contrast of blood and provides high-contrast images without the need for contrast agents. The high spatial resolution of the system is determined by the acoustic propagation and is limited to the submillimeter range by our 7.5-MHz linear array transducer. A Q-switched alexandrite laser emitting short near-infrared laser pulses at a wavelength of 760 nm allows an imaging depth of a few centimeters. The system provides real-time images at frame-rates of 7.5 Hz and optionally displays the classically generated ultrasound image alongside the optoacoustic image. The functionality of the system was demonstrated in vivo on human finger, arm and leg. The proposed system combines the merits and most compelling features of optics and ultrasound in a single high-contrast vascular imaging device.

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Optoacoustic imaging using a three-dimensional reconstruction algorithm

Köstli¹,

Frauchiger²,

Niederhauser³

et al. 2001

IEEE J. Select. Topics Quantum Electron.

106

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Detection of seizure precursors from depth-EEG using a sign periodogram transform

Niederhauser

Esteller

Echauz³

et al. 2003

IEEE Trans. Biomed. Eng.

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Brief bursts of focal, low amplitude rhythmic activity have been observed on depth electroencephalogram (EEG) in the minutes before electrographic onset of seizures in human mesial temporal lobe epilepsy. We have found these periods to contain discrete, individualized synchronized activity in patient-specific frequency bands ranging from 20 to 40 Hz. We present a method for detecting and displaying these events using a periodogram of the sign-limited temporal derivative of the EEG signal, denoted joint sign periodogram event characterization transform (JSPECT). When applied to continuous 2-6 day depth-EEG recordings from ten patients with temporal lobe epilepsy, JSPECT demonstrated that these patient-specific EEG events reliably occurred 5-80 s prior to electrical onset of seizures in five patients with focal, unilateral seizure onsets. JSPECT did not reveal this type of activity prior to seizures in five other patients with bilateral, extratemporal or more diffuse seizure onsets on EEG. Patient-specific, localized rhythmic events may play an important role in seizure generation in temporal lobe epilepsy. The JSPECT method efficiently detects these events, and may be useful as part of an automated system for predicting electrical seizure onset in appropriate patients.

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Real-time three-dimensional optoacoustic imaging using an acoustic lens system

Niederhauser

Jaeger

Frenz

2004

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In medical optoacoustics (photoacoustics), absorbing structures, such as blood vessels, hidden inside scattering media are illuminated with short laser pulses resulting in the generation of thermoelastic pressure transients. This initial three-dimensional (3D) acoustic pressure distribution, which exactly resembles the absorption distribution, was imaged into a water container with a 4f acoustic lens system. An optical dark-field stereo imaging system using a 30ns flash illumination light was used to capture a snapshot of the pressure-induced refraction index changes in the water container at a predetermined time after the original laser pulse. The imaging system works at 20Hz frame rate and was designed toward a theoretical resolution of 50μm. The proposed method directly provides 3D images of absorbing structures without the need of computational reconstruction algorithms.

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Transparent ITO coated PVDF transducer for optoacoustic depth profiling

Niederhauser

Jaeger

Hejazi

et al. 2005

Optics Communications

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J.J. Niederhauser

Combined ultrasound and optoacoustic system for real-time high-contrast vascular imaging in vivo

Optoacoustic imaging using a three-dimensional reconstruction algorithm

Detection of seizure precursors from depth-EEG using a sign periodogram transform

Real-time three-dimensional optoacoustic imaging using an acoustic lens system

Transparent ITO coated PVDF transducer for optoacoustic depth profiling

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