Background: An MRI is potentially hazardous for patients with retained ferromagnetic bullets. Recent studies have aimed to develop  dual-energy computed tomography (DECT) as a screening tool for recognising highly ferromagnetic bullets. Inconsistent findings have been ascribed to inherent CT technology differences. Previous research demonstrated significant Hounsfield unit (HU) measurement  variation among single-source CT machines.

Objectives: This study investigated the theoretical dual-energy index (DEI) variation  between DECT machines when evaluating the potential ferromagnetic properties within the same sample of ex vivo bullets and metal  phantoms.

Method: An experimental ex vivo study was conducted on eight metal phantoms and 10 unused bullets individually  positioned in the same Perspex head phantom and scanned on two DECT machines. Two senior radiology registrars independently  recorded the HU readings, and DEI values were calculated. Statistical analysis was performed using non-parametric methods for paired  data, namely the Signed Rank Test. The DEI values based on mean HU readings between the DECT machines were compared.

Results:  Inter- and intra-reader agreement was not statistically significant. The metal phantoms had poor interscanner agreement, with an  overlap of the ferromagnetic and non-ferromagnetic ranges. The bullets had good interscanner agreement, with a similar ferromagnetic  to nonferromagnetic relationship.

Conclusion: The use of DEI values negates the previous assumption that significant interscanner  variability exists among different DECT technologies while assessing highly attenuative ex vivo bullets.

Contribution: This investigation  demonstrated that even though HU readings may be variable, the implementation of the DEI equation translates this into comparable  values with good interscanner agreement.