Your search keyword '"Chu PW"' showing total 4 results

1. Correction to: Dose length product to effective dose coefficients in children.

Author

Chu PW, Kofler C, Mahendra M, Wang Y, Chu CA, Stewart C, Delman BN, Haas B, Lee C, Bolch WE, and Smith-Bindman R

Published

2023

2. Dose length product to effective dose coefficients in children.

Author

Chu PW, Kofler C, Mahendra M, Wang Y, Chu CA, Stewart C, Delman BN, Haas B, Lee C, Bolch WE, and Smith-Bindman R

Subjects

Infant, Humans, Child, Adolescent, Young Adult, Adult, Radiation Dosage, Computer Simulation, Phantoms, Imaging, Monte Carlo Method, Radiometry methods, Tomography, X-Ray Computed methods

Abstract

Background: The most accurate method for estimating effective dose (the most widely understood metric for tracking patient radiation exposure) from computed tomography (CT) requires time-intensive Monte Carlo simulation. A simpler method multiplies a scalar coefficient by the widely available scanner-reported dose length product (DLP) to estimate effective dose., Objective: Develop pediatric effective dose coefficients and assess their agreement with Monte Carlo simulation., Materials and Methods: Multicenter, population-based sample of 128,397 pediatric diagnostic CT scans prospectively assembled in 2015-2020 from the University of California San Francisco International CT Dose Registry and the University of Florida library of highly realistic hybrid computational phantoms. We generated effective dose coefficients for seven body regions, stratified by patient age, diameter, and scanner manufacturer. We applied the new coefficients to DLPs to calculate effective doses and assessed their correlations with Monte Carlo radiation transport-generated effective doses., Results: The reported effective dose coefficients, generally higher than previous studies, varied by body region and decreased in magnitude with increasing age. Coefficients were approximately 4 to 13-fold higher (across body regions) for patients  <1 year old compared with patients 15-21 years old. For example, head CT (54% of scans) dose coefficients decreased from 0.039 to 0.003 mSv/mGy-cm in patients  <1 year old vs. 15-21 years old. There were minimal differences by manufacturer. Using age-based conversion coefficients to estimate effective dose produced moderate to strong correlations with Monte Carlo results (Pearson correlations 0.52-0.80 across body regions)., Conclusions: New pediatric effective dose coefficients update existing literature and can be used to easily estimate effective dose using scanner-reported DLP., (© 2023. The Author(s).)

Published

2023

3. Reference phantom selection in pediatric computed tomography using data from a large, multicenter registry.

Author

Chu PW, Yu S, Wang Y, Seibert JA, Cervantes LF, Kasraie N, Chu CA, and Smith-Bindman R

Subjects

Adult, Child, Humans, Phantoms, Imaging, Radiation Dosage, Registries, Thorax, Tomography, X-Ray Computed methods

Abstract

Background: Radiation dose metrics vary by the calibration reference phantom used to report doses. By convention, 16-cm diameter cylindrical polymethyl-methacyrlate phantoms are used for head imaging and 32-cm diameter phantoms are used for body imaging in adults. Actual usage patterns in children remain under-documented., Objective: This study uses the University of California San Francisco International CT Dose Registry to describe phantom selection in children by patient age, body region and scanner manufacturer, and the consequent impact on radiation doses., Materials and Methods: For 106,837 pediatric computed tomography (CT) exams collected between Jan. 1, 2015, and Nov. 2, 2020, in children up to 17 years of age from 118 hospitals and imaging facilities, we describe reference phantom use patterns by body region, age and manufacturer, and median and 75th-percentile dose-length product (DLP) and volume CT dose index (CTDI vol ) doses when using 16-cm vs. 32-cm phantoms., Results: There was relatively consistent phantom selection by body region. Overall, 98.0% of brain and skull examinations referenced 16-cm phantoms, and 95.7% of chest, 94.4% of abdomen and 100% of cervical-spine examinations referenced 32-cm phantoms. Only GE deviated from this practice, reporting chest and abdomen scans using 16-cm phantoms with some frequency in children up to 10 years of age. DLP and CTDI vol values from 16-cm phantom-referenced scans were 2-3 times higher than 32-cm phantom-referenced scans., Conclusion: REFERENCE PHANTOM SELECTION IS HIGHLY CONSISTENT, WITH A SMALL BUT SIGNIFICANT NUMBER OF ABDOMEN AND CHEST SCANS (~5%) USING 16-CM PHANTOMS IN YOUNGER CHILDREN, WHICH PRODUCES DLP VALUES APPROXIMATELY TWICE AS HIGH AS EXAMS REFERENCED TO 32-CM PHANTOMS., (© 2021. The Author(s).)

Published

2022

4. Molecular and ultrastructural analysis of heavy membrane fractions associated with the replication of Kunjin virus RNA.

Author

Chu PW and Westaway EG

Subjects

Animals, Cell Fractionation, Centrifugation, Density Gradient, Flavivirus metabolism, Flavivirus physiology, Flavivirus ultrastructure, Intracellular Membranes metabolism, Intracellular Membranes ultrastructure, Octoxynol, Polyethylene Glycols pharmacology, RNA, Viral ultrastructure, RNA-Dependent RNA Polymerase metabolism, Vero Cells, Virus Replication, Flavivirus genetics, Intracellular Membranes microbiology, RNA, Viral biosynthesis

Abstract

In subcellular extracts of Kunjin virus-infected cells prepared by lysis and differential centrifugation, the viral RNA polymerase, RNA and proteins were associated mainly with cytoplasm. When the cytoplasmic extract (500 g supernate) of infected cells labelled for 3 h from 24 h post-infection was further fractionated by rapid centrifugation through a sucrose density gradient, all viral products were located only in dense or "heavy membrane" fractions, which contained three types of virus-induced morphologically distinct membrane structures. These dense fractions were treated with 0.5% NP40 and the soluble material was again centrifuged through a sucrose gradient for analyses as before. Viral RNA polymerase activity was retained and was associated with replicative intermediate RNA and some replicative form RNA in the peak enzyme fractions sedimenting at 20S to 40S. Enrichment of NS3 and of the small nonstructural proteins NS2A and NS2B/NS4A was apparent in these fractions which were well separated from the slow sedimenting structural proteins. No detergent-resistant structures in the "heavy membrane" fractions other than ribosome-like particles were visible. The data show that the RNA polymerase complex cosedimented with virus-induced membrane structures and remained associated with specific nonstructural proteins and replicative intermediate RNA after detergent treatment.

Published

1992