Reduced Patient Radiation Exposure during Neurodiagnostic and Interventional X-Ray Angiography with a New Imaging Platform

Discussion

While serious deterministic eye and skin injuries including cataracts are rare, erythema, and epilation as a consequence of interventional procedures are likely in a very small percentage of patients.^16,17 Several joint-society initiatives have been launched in response to increased recognition of the need to address such deterministic and long-term stochastic adverse events by carefully considering radiation exposure across medical imaging procedures, particularly in pediatric populations. The Image Wisely campaign was unveiled by the Joint Task Force on Adult Radiation Protection, an initiative established in 2009 by the American College of Radiology and the Radiological Society of North America.¹⁸ Around the same time, the Alliance for Radiation in Pediatric Imaging introduced the Image Gently, Step Lightly campaign to encourage dose reduction in pediatric interventional radiologic procedures.¹⁹

General effort to minimize the risk of skin injury during fluoroscopic procedures entails using proper applied x-ray tube potential and beam filtration, limiting exposure duration for fluoroscopy, DSA, and non-DSA digital acquisitions, modifying the x-ray beam geometry by appropriate collimation and by placing the imaging detector close to the patient, and by ensuring minimal biplane overlap.²⁰ Besides educating interventional practitioners and technical staff on As Low As Reasonably Achievable practices, improvement in angiographic systems technology is needed to achieve further dose reductions while maintaining acceptable image quality.

The introduction of the IP_DRT with flexible selection of dose-reduction protocols to suit clinical needs was associated with an overall reduction in CP_KA of 53.2% across all diagnostic and interventional procedures in our academic neurointerventional practice. For diagnostic examinations, which constituted the largest fraction of studies, the mean CP_KA of 139.4 Gy × cm² (95% CI, 131.6–147.6 Gy × cm²) observed in this study for the IP_R is lower than the 162.2 ± 231.7 Gy × cm² (95% CI, 129.0–195.4 Gy × cm²) reported by Söderman et al.⁵ In this study, the flexible use of dose-reduction protocols with the default setting of a quarter-dose protocol for the IP_DRT reduced the cumulative dose (kerma)-area product to 51.1 Gy × cm² (95% CI, 47–55.6 Gy × cm²) constituting a 63.3% reduction with respect to the IP_R, similar to the 62% reduction in CP_KA with the fixed quarter-dose protocol reported by Söderman et al. Fig 3 shows a sample case highlighting improved visualization of perforators in diagnostic angiography with the half-dose and quarter-dose protocols.

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Fig 3.

Diagnostic angiography was performed to assess the source of bleeding in a 43-year-old man who presented with diffuse SAH. During the examination, angiograms after contrast administration into the right ICA were obtained on IP_DRT platform by using the “full-dose” protocol (left), which is identical to the reference platform in terms of hardware and software settings, “half-dose” protocol (middle), and “quarter-dose” protocol (right). Magnified views of the dashed area highlight improved visualization of small perforators (white arrows) with the “half-dose” and “quarter-dose” protocols (lower panels).

Previous surveys of dose reports from a variety of interventional practices were used to infer reference dose values.^{21⇓⇓–24} In addition, estimates of radiation doses for smaller groups of patients and for various neurointerventional procedures have been reported.^25⇓–27 For the reference platform (IP_R), our CP_KA estimate of 139.4 Gy × cm² (95% CI, 131.6–147.6 Gy × cm²) for diagnostic procedures is consistent with earlier reports by Kien et al²³ (173.9 ± 90.9 Gy × cm²), D'Ercole et al²⁴ (142.1 ± 75.5 Gy × cm²), Söderman et al⁵ (162.2 ± 231.7 Gy × cm²; 95% CI, 129.0–195.4 Gy × cm²), and Alexander et al²⁵ (102.4 ± 43.4 Gy × cm²). In addition, for aneurysm coil embolization, our CP_KA estimates of 330.3 Gy × cm² (95% CI, 285.6–381.9 Gy × cm²) for IP_R are not markedly different from those reported by Miller et al²¹ (282.7 Gy × cm²; 95% CI, 261.1–304.3 Gy × cm²), D'Ercole et al²⁸ (413 Gy × cm²; 95% CI, 343–482 Gy × cm²), Kien et al²³ (275.7 ± 145.1 Gy × cm²), D'Ercole et al²⁴ (369.5 ± 162.3 Gy × cm²), Vano et al²⁷ (293 ± 188 Gy × cm² and 317 ± 234 Gy × cm²), and Alexander et al²⁵ (172.3 ± 67.7 Gy × cm²).

The wide range of CP_KA reported in this and prior studies reflects the diverse nature of neurointerventional procedures performed with varying degrees of complexity, partly due to the expanded repository of neurointerventional devices such as Onyx (Covidien, Irvine, California), which is known to increase the procedure duration for AVM embolization,²⁹ and to the enhanced capabilities of the imaging equipment, such as the ability to perform 3DRA and CBCT. The procedural CP_KA reported in this study is inclusive of 3DRA and CBCT. Hence, caution is warranted while comparing results from this study with those of earlier studies, in which such 3D acquisitions were not prevalent, different devices were used, and case complexity was difficult to assess. The advantage of our analysis for comparison of IP_DRT and IP_R is that it is adjusted for operator and patient characteristics under identical practice standards with independent confirmation of system-reported CP_KA.

For the IP_DRT, the dose-reduction technology and the reduced air kerma rates are active only during 2D acquisitions such as fluoroscopy and DSA. For procedures requiring CBCT scans and depending on the number and type of CBCT scans, the relative benefit of the IP_DRT in terms of cumulative dose (kerma)-area product is reduced. For instance, flow-diverter placement at our institution commonly requires 3DRA before device deployment and at least 2 CBCT image volumes following implantation to confirm proper deployment and the absence of intraprocedural hemorrhage. Moreover, because flow-diverter placement is generally accompanied only by several angiograms before and after device deployment, the opportunities for dose reduction are relatively limited. For flow-diverter placement, the mean CP_KA for the IP_R and IP_DRT was 269.1 and 187 Gy × cm², respectively, constituting a significant (P = .0015) but relatively modest 30.5% reduction. Even in aneurysm coil embolization, an initial 3DRA and final CBCT are performed as standard of practice at our institution. Analysis of a subset of cases in which P_KA measurements were available separately for fluoroscopy, DSA, and CBCT suggests that there was no difference in the relative contribution of CBCT to the procedural CP_KA between the IP_R and IP_DRT for diagnostic cases, while results acquired on the IP_DRT indicate that the relative contribution of the CBCT to the CP_KA may vary with procedure type (On-line Figs 1 and 2 and On-line Table).

The study observed CP_KA reduction with the IP_DRT for each procedure type, with the exception of dural AVFs and brain AVMs. On occasion, an operator may repeat an acquisition at a higher dose for verification. However, in practice these situations arose sporadically, such as when examining highly complex brain AVMs, and rarely occurred during most of the diagnostic and other treatment procedures. The limited sample size for brain AVMs (10 and 6 treated on the IP_R and IP_DRT, respectively) and dural AVFs (7 and 3 treated on the IP_R and IP_DRT, respectively) could have also contributed to a nonsignificant reduction (P > .15) to the procedure CP_KA.

Despite significant reductions in CP_KA and across most procedure types, overall, we observed a marginal difference (P = .0491) in total fluoroscopy duration between the 2 platforms, with an additional 5.2 minutes of fluoroscopy duration with the IP_DRT. On our systems, the default is fluoroscopy mode II and is typically used for interventions. Generally, fluoroscopy mode I was used for diagnostic examinations, and fluoroscopy mode III was reserved for complex cases involving flow-diverter placement and AVM embolization. There was no indication that the use of these modes was different between the IP_R and the IP_DRT. Significant differences in total fluoroscopy duration between the 2 platforms were observed for diagnostic examinations (P = .0002) and flow-diverter placement (P = .0038), with an increase of 1.7 and 14.9 minutes, respectively, with IP_DRT. Additional analyses for these procedures indicated that the total fluoroscopy duration with IP_DRT increased for 1 operator by 2.3 minutes for diagnostic examinations (P < .0001) and 10.7 minutes for flow-diverter placement (P = .0026). Also, for flow-diverter placement, procedures involving >1 operator contributed to a substantial 34.5-minute (P = .0203) increase with IP_DRT. In our academic practice, the extent to which the assisting fellows are involved and the nature of their contribution to a case, depending on the procedure, may vary. Regarding the total administered contrast volume, overall, the difference between the 2 platforms was nonsignificant (P = .1616), with an increase of 15.3 mL (6.7%) with IP_DRT. Overall, the marginal increase in fluoroscopy duration and the nonsignificant change in administered contrast volume suggest that workflow was unaffected by the use of the IP_DRT.

Our study had limitations. This retrospective study precluded randomization of the operator and imaging platform. We did not analyze the partial contributions to CP_KA from fluoroscopy, angiography, and 3D imaging for all cases because these data were not recorded uniformly. For each procedure type, the sample-size distribution was not uniform for the 2 platforms in this retrospective study. Another confounding factor is the smaller x-ray detector for the LAT plane of the FD20/10 system, which was used for all IP_DRT examinations and part of the IP_R examinations. The smaller detector size may contribute to lower P_KA for that acquisition or may contribute to higher procedural CP_KA, because adjacent regions were additionally imaged when clinically needed. At our institution, all neurointerventional systems are from a single vendor; hence, our analysis is restricted to that vendor. Our study considered CP_KA alone as the metric for analysis and does not address the skin-dose distribution and the peak skin dose³⁰ because the imaging geometry relative to the patient and anatomic region was not collected. CP_KA is relevant to the estimation of stochastic effects, while peak skin dose is directly related to skin effects.