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Letter to the Editor: Response to ‘Localization of white-matter lesions and effect of vascular risk factors in late-onset major depression’

Published online by Cambridge University Press:  21 April 2010

ANNE M. GROOL
Affiliation:
Julius Center for Health Sciences and Primary Care, University Medical Center Utrecht, The Netherlands
KOEN L. VINCKEN
Affiliation:
Image Sciences Institute, University Medical Center Utrecht, The Netherlands
YOLANDA VAN DER GRAAF
Affiliation:
Julius Center for Health Sciences and Primary Care, University Medical Center Utrecht, The Netherlands
MIRJAM I. GEERLINGS*
Affiliation:
Julius Center for Health Sciences and Primary Care, University Medical Center Utrecht, The Netherlands
*
Author for correspondence: Dr M. I. Geerlings, University Medical Center Utrecht, Julius Center for Health Sciences and Primary Care, Stratenum 6.131, PO Box 85500, 3508GAUtrecht, The Netherlands (Email: m.geerlings@umcutrecht.nl)
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Abstract

Type
Correspondence
Copyright
Copyright © Cambridge University Press 2010

Recently, Dalby and colleagues published an interesting paper on the associations of localization, number and volume of deep white-matter lesions (DWMLs) with late-onset depression, using a case-control design in which they compared 22 patients with late-onset major depression to 22 healthy controls (Dalby et al. Reference Dalby, Chakravarty, Ahdidan, Sorensen, Frandsen, Jonsdottir, Tehrani, Rosenberg, Ostergaard and Videbech2009). The authors found a relationship between DWML localization and late-onset depression, whereas no associations of DWML number and volume with late-onset depression were found. We read this paper with great interest, and although their findings could be of importance, we have a number of considerations when interpreting the findings.

First, DWMLs were identified on axial FLAIR images (matrix 224×256, slice thickness 5 mm) and manually labelled by one trained neuroradiologist. When axially viewed, deep lesions may appear to be present on MRI. However, when sagittal and coronal orientations are viewed, many of these lesions are actually contiguous with the ventricular lining and may therefore be incorrectly classified as ‘deep’ (DeCarli et al. Reference DeCarli, Fletcher, Ramey, Harvey and Jagust2005). Moreover, volume estimations from manually labelled WMLs have a lower reproducibility and objectivity than estimations from automated segmentation programmes, and often lead to a relative volume overestimation. When WMLs are visually labelled, all hyperintensities are given the same probability of being lesion volumes, since no distinctions are made in hyperintensity range. In addition, less hyperintense voxels around and within lesions are also counted as WML volume, which is likely to result in greater WML volumes than probabilistically estimated volumes. The aforementioned situations could result in a relative overestimation of DWML volume, which is in agreement with the high number of individuals displaying DWMLs in Dalby et al.'s study sample (17/22 patients, 21/22 controls). The authors did not report the median volume of DWMLs in patients and controls, but when we calculated this from their Figure 1, it was approximately 0.4 ml for patients and 0.5 ml for controls. These volumes are quite high, given the relatively young age and low prevalence of vascular risk factors in this population. Recently, we reported that volumetrically assessed median DWML volume was 0.4 ml in a large sample of patients with symptomatic atherosclerotic disease (mean age 58±10 years), while they had more vascular risk factors than Dalby et al.'s study sample (Geerlings et al. Reference Geerlings, Appelman, Vincken, Algra, Witkamp, Mali and van der Graaf2009). Another study, in patients with evidence of vascular disease or at high risk of developing vascular disease of considerably older age (mean age 75±3 years), found a median DWML volume of 0.5 ml (Versluis et al. Reference Versluis, van der Mast, van Buchem, Bollen, Blauw, Eekhof, van der Wee and de Craen2006).

Second, because of the relatively small sample size, patients with extremely high or low values of DWML volume seem to distort the findings. In Figure 1, three patients with extremely high values are seen in the control group. When these patients are left out, the median volume seems to decrease to 0.18 ml. Further, in the patient group three outliers are seen with low values. Exclusion of these outliers seems to increase median DWML volume to 0.53 ml. A significant difference in WML volume between depressed and control subjects could have been present if these outliers were excluded from the analyses. Hence, it would have been preferable to use a larger sample size.

Third, when control subjects are recruited through advertisement, it is important to take the possibility of selection bias into consideration. Since not all people have access to the source of the advertisement, some members of the population are less likely to be included than others, leading to a biased and unrepresentative sample. Self-selection can also play an important role in recruitment through advertisement. A participants' decision to participate may be correlated with traits that affect the study, creating a non-representative control sample, thereby inducing incomparability between patients and controls.

Finally, the last hypothesis tested by the authors was that vascular risk factors have a significant effect on WML load. Most previous studies found that vascular risk factors, including hypertension and diabetes mellitus, are significantly associated with WML load. Dalby et al. did not find a significant effect of these variables on WML load. This may be a result of matching the depressed patients with control subjects for age, gender and vascular risk factors. A consequence of matching is that these factors can no longer be studied as a determinant of the outcome, because all variation is ‘matched away’. However, a significant difference was found in social class between depressed and control subjects. Unfortunately, the authors did not adjust for the difference in socioeconomic class, whereas such an adjustment might have influenced the results.

Declaration of Interest

None.

References

Dalby, RB, Chakravarty, MM, Ahdidan, J, Sorensen, L, Frandsen, J, Jonsdottir, KY, Tehrani, E, Rosenberg, R, Ostergaard, L, Videbech, P (2009). Localization of white-matter lesions and effect of vascular risk factors in late-onset major depression. Psychological Medicine. Published online: 9 November 2009. doi:10.1017/S0033291709991656.Google ScholarPubMed
DeCarli, C, Fletcher, E, Ramey, V, Harvey, D, Jagust, WJ (2005). Anatomical mapping of white matter hyperintensities (WMH): exploring the relationships between periventricular WMH, deep WMH, and total WMH burden. Stroke 36, 5055.CrossRefGoogle ScholarPubMed
Geerlings, MI, Appelman, AP, Vincken, KL, Algra, A, Witkamp, TD, Mali, WP, van der Graaf, Y (2009). Brain volumes and cerebrovascular lesions on MRI in patients with atherosclerotic disease. The SMART-MR study. Atherosclerosis. Published online: 10 November 2009. doi:10.1016/j.atherosclerosis.2009.10.039.Google ScholarPubMed
Versluis, CE, van der Mast, RC, van Buchem, MA, Bollen, EL, Blauw, GJ, Eekhof, JA, van der Wee, NJ, de Craen, AJ (2006). Progression of cerebral white matter lesions is not associated with development of depressive symptoms in elderly subjects at risk of cardiovascular disease: the PROSPER Study. International Journal of Geriatric Psychiatry 21, 375381.CrossRefGoogle Scholar