Dose length product to effective dose coefficients in adults

ObjectivesThe most accurate method for estimating patient effective dose (a principal 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. We developed new adult effective dose coefficients using actual patient scans and assessed their agreement with Monte Carlo simulation.MethodsA multicenter sample of 216,906 adult CT scans was prospectively assembled in 2015-2020 from the University of California San Francisco International CT Dose Registry and the University of Florida library of computational phantoms. We generated effective dose coefficients for eight body regions, stratified by patient sex, diameter, and scanner manufacturer. We applied the new coefficients to DLPs to calculate effective doses and assess their correlations with Monte Carlo radiation transport-generated effective dose.ResultsEffective dose coefficients varied by body region and decreased in magnitude with increasing patient diameter. Coefficients were approximately twofold higher for torso scans in smallest compared with largest diameter categories. For example, abdomen and pelvis coefficients decreased from 0.027 to 0.013 mSv/mGy-cm between the 16-20 cm and 41+ cm categories. There were modest but consistent differences by sex and manufacturer. Diameter-based coefficients used to estimate effective dose produced strong correlations with the reference standard (Pearson correlations 0.77-0.86). The reported conversion coefficients differ from previous studies, particularly in neck CT.ConclusionsNew effective dose coefficients derived from empirical clinical scans can be used to easily estimate effective dose using scanner-reported DLP.Clinical relevance statementScalar coefficients multiplied by DLP offer a simple approximation to effective dose, a key radiation dose metric. New effective dose coefficients from this study strongly correlate with gold standard, Monte Carlo-generated effective dose, and differ somewhat from previous studies.Key Points center dot Previous effective dose coefficients were derived from theoretical models rather than real patient data.center dot The new coefficients (from a large registry/phantom library) differ from previous studies.center dot The new coefficients offer reasonably reliable values for estimating effective dose.Key Points center dot Previous effective dose coefficients were derived from theoretical models rather than real patient data.center dot The new coefficients (from a large registry/phantom library) differ from previous studies.center dot The new coefficients offer reasonably reliable values for estimating effective dose.Key Points center dot Previous effective dose coefficients were derived from theoretical models rather than real patient data.center dot The new coefficients (from a large registry/phantom library) differ from previous studies.center dot The new coefficients offer reasonably reliable values for estimating effective dose.

Automated summary

New adult effective dose coefficients were developed using actual patient scans and were found to be consistent with Monte Carlo simulation, which is clinically relevant.