Incidental Head and Neck Findings on MRI in Young Healthy Volunteers: Prevalence and Clinical Implications

Discussion

We found a high prevalence of incidental brain and head and neck abnormalities (9.4% and 36.7%, respectively) in a population of healthy young adult volunteers (18–35 years of age) when scans were retrospectively read by an experienced head and neck radiologist or neuroradiologist; 4.4% of the brain findings and 5.5% of the head and neck findings were classified as in need of referral (clinically relevant), including 2 findings classified as urgent referral. Of the 19 findings categorized as in need of referral, only 1 (skull lesion consistent with fibrous dysplasia) was actually referred at the time of the study (5.2%).

Our finding of an incidence of 36.7% of MR imaging scans with any incidental finding is quite similar to that recently reported,¹⁴ in which an incidental finding of any kind was found in 42.9% of the brain examinations. However, our prevalence rate of potentially clinically relevant incidental brain abnormalities is higher than that reported previously in a similar age group of healthy volunteers⁹: 5.8% versus 9.4% in this study. The most likely explanation is that in the present study, all scans were read by an experienced neuroradiologist, whereas this was not the case in the study by Weber and Knopf.⁹ Both studies used high-resolution contrast-enhanced T1-weighted sequences; therefore, technique-related issues are not a plausible explanation for the observed difference.

In a postmortem study including 4069 consecutive cases, a prevalence of 2.5% of developmental venous anomaly (the most frequent cerebral vascular malformation) was reported. In the present study, we report a prevalence rate of 2.0%, whereas Weber and Knopf⁹ reported a prevalence rate of only 0.12%, suggesting that brain abnormalities were underscored in the study by Weber and Knopf. A recent meta-analysis on incidental findings revealed an overall prevalence rate of incidental brain findings on brain MR imaging scans of 2.7%.¹⁵ However, most of the studies included in the meta-analysis did not use high-resolution MR imaging sequences (eg, section thickness of <3 mm), a factor that does affect the detection rate, as pointed out in the meta-analysis. In addition, the use of low-field MR imaging scanners (1T) and interpretation by unspecified observers (nonradiologists) make it difficult to compare the 2 datasets and likely explain the discrepancy between this study and the meta-analysis.

There are 2 other studies that included young adult subjects and reported on the incidence of brain abnormalities in which scans were read by a neuroradiologist. However, these included very heterogeneous age groups: in subjects 18–90 years of age, which included a “younger ” cohort,¹⁰ and in subjects 9–50 years of age.⁷ In the first study,¹⁰ 6.6% needed referral, and in the latter, 10.2%. Similar to our study, the latter study involved high-resolution images, which were, however, obtained at 3T. Their prevalence rate was higher than the 4.4% reported in the current study. Thus, incidental brain abnormalities on MR imaging scans are also common in healthy young adult volunteers when the scans are read by a neuroradiologist, by using high-resolution MR imaging sequences and a homogeneous age group.

To our knowledge, no previous studies looked into incidental head and neck findings. The high occurrence of abnormal findings (36.7%) in the upper head and neck region is mainly explained by simple sinus disease. Excluding simple sinus disease from our analyses would reduce the incidence to 14.4%. The incidence of clinically relevant head and neck findings was similar to clinically relevant brain findings (5.4% versus 4.4%), though none were referred at the time of study.

The most frequent incidental findings classified as routine referral were important white matter lesion and a retention cyst or sinonasal polyp. Although extensive white matter changes have been shown to be associated with increased risks of stroke and cognitive decline, none of our subjects met these criteria (Fazekas 2 or higher). A retention cyst or polyp in the maxillary sinuses is never an indication for surgical treatment. Bilateral cervical lymphadenopathy, however, should be evaluated to differentiate between serious disease (eg, malignant lymphoma, inflammatory or granulomatous disease) and reactive changes.

Other incidental routine referral findings that we found are sporadically associated with complications or may be an explanation for a “subsymptomatic ” state of the participant (eg, cognitive impairment due to gray matter heterotopia). The clinical relevance of incidental findings classified as urgent referral is expected to be much more evident because these require an urgent referral within weeks of the study for any abnormality that will need further yet nonemergent evaluation (hence the name).

However, at the time of the study, only 1 of the 19 relevant findings that were later categorized as in need of referral (5.2%) was actually referred, suggesting that the clinical predictive value of an abnormal research MR imaging scan is quite low. This is in line with a previous study in which only 2.2% of the incidental brain findings on MR imaging received further action.¹⁴ This probably relates to the fact that abnormal findings on scans were classified on their potential clinical relevance and that the currently used (and previously frequently used) classification system does not take into account the risks and benefits associated with incidental brain findings.¹³

When applying a recently suggested classification system that takes the potential benefit in disclosing an incidental brain finding to the research participant into account,¹³ the results are more in accordance with our observations: Nearly all abnormal findings on scans (94.7%) would be classified as of unlikely benefit to the participant (no serious health condition, only a burden for the participant in receiving this information). Only 2 findings in 203 subjects (<1%) would be considered of possible benefit to the participant (a serious condition that cannot be treated but is likely to be important to the participant), namely the findings classified as urgent referral: an osseous skull lesion and extensive bilateral lymphadenopathy. Findings of possible benefit may be disclosed to research participants, unless they elect not to know; findings that are unlikely to be of benefit should not be disclosed to the research participant, as suggested by Wolf et al.¹³

A major strength of our study is that all scans were read by an experienced head and neck radiologist or neuroradiologist (along with the high technical quality of the MR images), leading to a high number of detected abnormalities. As pointed out by Illes et al,³ the time has come when we must balance the benefit of involving medical personnel trained to read (brain) scans and interact with participants against the legal risk and financial burden of clinical assessment of all MR imaging scans of the participants and the workload that comes with it. Although the findings of the present study suggest that there is a need for specialized medical personnel to review all MR images (a high prevalence of potential clinically relevant incidental findings and a higher number of detected abnormalities than reported in the literature), there is no benefit from a clinical point of view, or from a participant's point of view, in having all brain MR imaging scans evaluated by specialized medical personnel. This is in line with recommendations made by Wolf et al,¹³ pointing out that researchers have no duty to search for incidental findings because the goal of research is to seek generalizable knowledge, not to provide health information to individuals. In line with this recommendation, Orme et al¹⁴ recently demonstrated not only that incidental findings are common in MR imaging of the head but that most incidental (brain) findings are of “unclear significance.” On the other hand, in several opinion pieces,^16⇓–18 it was stated that research centers should have trained imagers to provide appropriate follow-up imaging or care to research participants and that a protocol for reporting and initiating treatment should be mandated in all neuroimaging research.