John P. van Houten scite author profile

The objective of this retrospective study was to determine the incidence and types of cranial ultrasound abnormalities in full-term infants with congenital heart disease (CHD). We reviewed the cranial ultrasound scans of 49 full-term infants with CHD and compared them to 42 healthy full-term control infants. The relationship of each abnormality with the type of CHD, the presence of cyanosis, and cardiac catheterization and cardiac surgery were examined. We found that infants with CHD had a higher incidence of cranial ultrasound abnormalities than control infants (59% versus 14%; p < 0.001). Cerebral atrophy and linear echodensities in the basal ganglia and thalamus were the most common sonographic findings in infants with CHD, particularly in those with coarctation of the aorta or ventricular septal defect. Intraventricular hemorrhage occurred more often in infants with acryanotic CHD than in those with cyanotic CHD. Cardiac catheterization and cardiac surgery had no significant effects on cranial ultrasound findings. We conclude that cranial ultrasound abnormalities are very frequent in full-term infants with CHD. These findings emphasize the importance of cranial ultrasonography and long-term neurodevelopmental follow-up of infants with CHD.

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Bedside Imaging of Intracranial Hemorrhage in the Neonate Using Light: Comparison with Ultrasound, Computed Tomography, and Magnetic Resonance Imaging

Hintz

Cheong

Houten

et al. 1999

Pediatr Res

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Medical optical imaging (MOI) uses light emitted into opaque tissues to determine the interior structure. Previous reports detailed a portable time-of-flight and absorbance system emitting pulses of near infrared light into tissues and measuring the emerging light. Using this system, optical images of phantoms, whole rats, and pathologic neonatal brain specimens have been tomographically reconstructed. We have now modified the existing instrumentation into a clinically relevant headband-based system to be used for optical imaging of structure in the neonatal brain at the bedside. Eight medical optical imaging studies in the neonatal intensive care unit were performed in a blinded clinical comparison of optical images with ultrasound, computed tomography, and magnetic resonance imaging. Optical images were interpreted as correct in six of eight cases, with one error attributed to the age of the clot, and one small clot not seen. In addition, one disagreement with ultrasound, not reported as an error, was found to be the result of a mislabeled ultrasound report rather than because of an inaccurate optical scan. Optical scan correlated well with computed tomography and magnetic resonance imaging findings in one patient. We conclude that light-based imaging using a portable time-of-flight system is feasible and represents an important new noninvasive diagnostic technique, with potential for continuous monitoring of critically ill neonates at risk for intraventricular hemorrhage or stroke. Further studies are now underway to further investigate the functional imaging capabilities of this new diagnostic tool.

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Imaging Brain Injury Using Time-Resolved Near Infrared Light Scanning

et al. 1996

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Conventional brain imaging modalities are limited in that they image only secondary physical manifestations of brain injury, which may occur well after the actual insult to the brain and represent irreversible structural changes. A real-time continuous bedside monitor that images functional changes in cerebral blood flow or oxygenation might allow for recognition of brain tissue ischemia or hypoxia before the development of irreversible injury. Visible and near infrared light pass through human bone and tissue in small amounts, and the emerging light can be used to form images of the interior structure of the tissue and measure tissue blood flow and oxygen utilization based on light absorbance and scattering. We developed a portable time-of-flight and absorbance system which emits pulses of near infrared light into tissue and measures the transit time of photons through the tissue. Images can then be reconstructed mathematically using either absorbance or scattering information. Pathologic brain specimens from adult sheep and human newborns were studied with this device using rotational optical tomography. Images generated from these optical scans show that neonatal brain injuries such as subependymal and intraventricular hemorrhages can be successfully identified and localized. Resolution of this system appears to be better than 1 cm at a tissue depth of 5 cm, which should be sufficient for imaging some brain lesions as well as for detection of regional changes in cerebral blood flow and oxygenation. We conclude that light-based imaging of cerebral structure and function is feasible and may permit identification of patients with impending brain injury as well as monitoring of the efficacy of intervention. Construction of real-time images of brain structure and function is now underway using a fiber optic headband and nonmechanical rotational scanner allowing comfortable, unintrusive monitoring over extended periods of time.

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Stationary Headband for Clinical Time‐of‐Flight Optical Imaging at the Bedside

Hintz

Benaron

Houten

et al. 1998

Photochem & Photobiology

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Conventional brain-imaging modalities may be limited by high cost, difficulty of bedside use, noncontinuous operation, invasiveness or an inability to obtain measurements of tissue function, such as oxygenation during stroke. Our goal was to develop a bedside clinical device able to generate continuous, noninvasive, tomographic images of the brain using low-power nonionizing optical radiation. We modified an existing stage-based time-of-flight optical tomography system to allow imaging of patients under clinical conditions. First, a stationary head-band consisting of thin, flexible optical fibers was constructed. The headband was then calibrated and tested, including an assessment of fiber lengths, the existing system software was modified to collect headband data and to perform simultaneous collection of data and image reconstruction, and the existing hardware was modified to scan optically using this headband. The headband was tested on resin models and allowed for the generation of tomographic images in vitro; the headband was tested on critically ill infants and allowed for optical tomographic images of the neonatal brain to be obtained in vivo.

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Early Clinical Results of Time-of-Flight Optical Tomography in a Neonatal Intensive Care Unit

Benaron¹,

Houten²,

Cheong³

et al. 1996

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John P. van Houten

High Incidence of Cranial Ultrasound Abnormalities in Full-Term Infants with Congenital Heart Disease

Bedside Imaging of Intracranial Hemorrhage in the Neonate Using Light: Comparison with Ultrasound, Computed Tomography, and Magnetic Resonance Imaging

Imaging Brain Injury Using Time-Resolved Near Infrared Light Scanning

Stationary Headband for Clinical Time‐of‐Flight Optical Imaging at the Bedside

Early Clinical Results of Time-of-Flight Optical Tomography in a Neonatal Intensive Care Unit

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