Trainee Misinterpretations on Pediatric Neuroimaging Studies: Classification, Imaging Analysis, and Outcome Assessment

Discussion

The trainee discrepancy rate for pediatric neuroimaging studies was low at 4.1%. This is similar to that in previous studies that evaluated trainee discrepancy rates for neuroimaging studies performed primarily in adults. The overall trainee discrepancy rates described in studies primarily evaluating adult patients have ranged from 2% to 8% (most commonly 3%–5%).^1–7 Most of the discrepancies in our study, as in previous reports, were classified as minor.

Concerning the type of findings most commonly missed on pediatric neuroimaging studies, fractures were the most common, occurring in 28 cases and making up 20% of all trainee discrepancies. Missed fractures were also common in some of the studies of adult patients.^1,5 ICH was the second most common source of discrepancies, occurring in 23 cases and making up 16% of all trainee misinterpretations. Other common misinterpreted findings included focal brain parenchymal abnormalities and misinterpretations of ventricular size. In our experience, multiplanar reformats are an important tool in the interpretation of head CT for trauma, especially in the depiction of subtle extra-axial hemorrhage (Fig 4C, -D). This technique has been recently documented in the literature⁹ and has been adopted as standard protocol at our institution in this patient population.

Overcalls were not uncommon in our series, occurring in 37 cases. The most frequent cause of trainee overcalls was the misidentification of fractures, typically related to asymmetric or accessory sutures. We believe the presence of unfused or partially fused sutures in children may play a role in the high incidence of overcalled fractures. As previously reported in the literature,^10,12 multiplanar 2D and especially 3D reconstructions are helpful for better delineation of an area of questionable skull abnormality, and the use of this technique is emphasized to our trainees in our educational curriculum.

There were only 6 major (life-threatening) discrepancies, for a rate of 0.17%. This low rate of major discrepancies is similar to that in previous studies evaluating trainee misinterpretations.^1–7 The most common cause of major discrepancies was the misinterpretation of brain edema (4 cases). Misinterpretation in these cases was due to failure in recognizing diffuse (3 cases) or focal (1 case) loss of gray-white matter differentiation. The 3 cases in which diffuse loss of gray-white matter differentiation was missed were the result of diffuse brain edema from hypoxic-ischemic insult. This is an important finding in our study that differs from that in previous studies based primarily on the adult population. Although misinterpretation of brain attenuation has been described as a cause of major discrepancies in some adult studies,⁸ those cases were typically the result of focal stroke or vasogenic edema, rather than diffuse brain insult as in our study. Findings of diffuse brain edema can be subtle,^13,14 and misidentification may result in inadequate or delayed treatment. Although in our study the correct identification of these findings by the staff radiologist did not lead to a specific treatment change on the part of the clinical team because the diagnosis was also suspected clinically, in a different clinical scenario, the misinterpretation could have been much more clinically significant. On the basis of the findings in this study, the imaging appearances of diffuse brain edema/injury on CT should be specifically emphasized during resident and fellow training.

As has been previously suggested,⁴ the final interpretation by the staff radiologist was an imperfect criterion standard. A recent study noted an 8.3% discrepancy rate between different board-certified subspecialty-trained neuroradiologists in interpreting outside imaging studies in a tertiary care setting, though only 1.2% were clinically important.¹⁵ In our study, 15 (9.5%) of the reports initially described as discrepancies in trainee interpretation by the original interpreting radiology staff did not harbor a true discrepancy when subsequently evaluated by the 2 expert reviewers. In most of these cases, the faculty essentially restated the trainee interpretation with no change in the original findings or differential diagnosis. In 4 cases (2.8% of reviewed examinations), the expert reviewers disagreed with the initial attending radiologist's interpretation. In 1 important case (Fig 2), the initial trainee interpretation suggested the correct finding, only to be overruled by the attending radiologist's interpretation. Follow-up CT performed to assess new symptoms showed an enlarging epidural hematoma necessitating surgical evacuation. Because the trainee was not definitive in identifying hemorrhage, as well as the importance of the case, this was classified as a type 1 trainee misinterpretation for the purposes of this study.

The most common neuroimaging examination type in which discrepancies were noted was head CT (72%). This is also the most common neuroimaging study performed on off-hour shifts. Educational programs aimed at training rotating residents and fellows for off-hour shifts should focus on CT and, in particular, head CT interpretation. Of CT examinations, those of the face and neck had the highest discrepancy rates and should also be emphasized early in trainee education, particularly with regard to fracture patterns and normal variants that may cause diagnostic confusion.

Although the relatively small number of examinations read by resident trainees (versus fellows) in this study and our study design limit our ability to reach definitive conclusions regarding the effect of resident training experience and error rate, there are some significant findings: Third- and fourth-year residents committed more errors (12.4%) than fellows (3.7%) or first- and second-year residents (1.9%) during the study period. This finding is not intuitive, because error rates would be expected to decrease with more experience. Similar trainee-level patterns of discrepancies have been described by other researchers with body CT (major discrepancies)¹⁶ and head CT⁵ interpretations. Because of the small number of cases read by residents in this study, bias from sampling error cannot be discounted as a cause.

Independent reading cannot be assured in all cases interpreted by trainees in our study. Fellows and residents in our institution share the same reading room and are on call at the same time, and the fellows can be easily consulted on cases before dictation. It may be that the first- and second-year residents seek out second opinions from the fellows more commonly than the third- and fourth-year residents who are more confident in their ability to read independently. Experience in pediatric-specific imaging is still relatively limited for most residents during training, and pediatric rotations are commonly interrupted by many months of nonpediatric imaging. It seems reasonable to have residents of all training levels undergo basic pediatric neuroradiology−specific training, focusing on commonly misinterpreted findings, before each rotation throughout their training. Building an educational curriculum around common errors has been shown to improve trainee performance,^9,17 and continued diligence in resident training with feedback on commonly missed findings is important to help limit these errors.

Concerning patient management and outcome, 98% of the discrepancies noted in this study had either no effect on clinical management or outcome or had no direct treatment change but did lead to imaging or clinical follow-up related to the discrepancy. There was no permanent harm related to the discrepancies and no directly related mortality. Some of the misinterpretations in a different clinical scenario could have had a more direct and significant impact on outcome (diffuse edema, missed epidural hematoma). Although they were small in number in our study, the performance of unnecessary follow-up imaging examinations based on a misinterpretation adds to the cost of medical care and, in the case of CT, adds an additional risk of unnecessary exposure to ionizing radiation.

We recognize some limitations to our study, in addition to those described above. First, the identification of a report as discrepant is dependent on the faculty using the official macro for changing preliminary reports. Faculty use of this process is randomly audited as part of our quality assurance process and has demonstrated high compliance during the past 2 years. Second, the assessment of outcome was subjective, based on chart review and the best clinical judgment of the expert reviewers. Although this type of assessment can potentially lead to bias, every effort was made, by detailed chart review, to accurately identify any changes in clinical management based on the misinterpretation. Although it has some limitations, this method is practical and is similar to that in previous studies of trainee misinterpretations.^1,4