Fluorodeoxyglucose–Positron-Emission Tomography, Single-Photon Emission Tomography, and Structural MR Imaging for Prediction of Rapid Conversion to Alzheimer Disease in Patients with Mild Cognitive Impairment: A Meta-Analysis

Identification and Eligibility of Relevant Studies

MEDLINE through OVID was used to identify studies. The search strategy was based on a combination of terms: 1) positron-emission tomography or tomography, emission-computed, single-photon OR MR imaging; 2) mild cognitive impairment AND Alzheimer Disease AND predict*. Searches were limited to human subjects. Abstracts were read by 2 reviewers (Y.Y., Z.-X.G.) for all articles retrieved. For relevant abstracts, full articles were obtained and examined. References of retrieved articles were screened for additional studies. Further articles citing these articles were also examined by using the Social Sciences Citation Index (1998 to present) through the Web of Science.

The following inclusion criteria were adopted to conform variables that may introduce bias or explain heterogeneity of the results on the basis of the Quality Assessment of Diagnostic Accuracy Assessment (QUADAS) tool⁶: 1) published between January 1990 and April 2008; 2) peer-reviewed; 3) original studies; 4) reported in English; 5) including at least 10 subjects; 6) patients at baseline who could not be classified as healthy or demented but were cognitively impaired; 7) longitudinal studies that retrospectively analyzed the initial characteristics of those who were progressive and those who remained stable; 8) not visually rated; 8) either clinical diagnosis (AD based on the National Institute of Neurologic and Communicative Disorders and Stroke-Alzheimer disease and Related Disorders Association criteria,⁷ dementia based on the Diagnostic and Statistical Manual criteria [DSM-IV],⁸) or histopathologic diagnosis used as the reference standard; 9) sufficient data provided either directly or indirectly through a 2 × 2 table to enable calculation of point estimates and 95% confidence intervals (CIs) for the operating characteristics; 10) the largest or the most recent articles for reports including overlapped patients; 11) for PET studies, only those using [¹⁸F] fluorodeoxyglucose (¹⁸F-FDG) as tracer, and for MR imaging, only structural MR imaging; and 12) only articles in which the answer yes for the 14 questions in the QUADAS quality assessment tool⁶ was given more than 9 times. The studies with results of different diagnostic methods that were presented in combination and could not be separated were excluded.

Data Extraction

In each report, 2 investigators (Y.Y., Z.-X.G.) extracted and recorded data on author names, year of publication, number of patients analyzed, age, male-female distribution, years of education, score of the Mini-Mental State Examination (MMSE) at baseline, inclusion and exclusion criteria, reference standard, follow-up interval, image and data analytic methods, the regions of cerebral analysis, and a 2 × 2 contingency table. We also extracted the following imaging features: for FDG-PET and SPECT, the tracer used (FDG-PET tests exclusively selected ¹⁸F-FDG as tracer) and amount of tracer; for MR imaging, magnetic field strength. To resolve disagreement between reviewers, a third reviewer (W.-S.W.) assessed all discrepant items, and the majority opinion was used for analysis.

Data Synthesis and Statistical Analysis

Stata, Version 8.2 (Stata, College Station, Tex) and Meta-DiSc (Javier Zamora, Boston, Mass)⁹ were used for statistical analysis. For each study, we constructed a 2 × 2 contingency table in which all participants were classified as having positive or negative imaging results at baseline and as being cognitively progressive or stable during the follow-up interval. To calculate the log OR (log odds of true positive rate and log odds of false positive rate), we added 0.5 to each cell in any 2 × 2 table with zero. For each technique, we estimated the weighted summary sensitivity, specificity, positive and negative likelihood ratios (LR+, LR−), and OR and described a set of operating characteristics across eligible studies by constructing a summary receiver operating characteristic (ROC) curve. We defined the maximum joint sensitivity and specificity as point Q* on a symmetric ROC curve, which is a global measure of test accuracy, similar to the area under the ROC curve (AUC). To determine whether these values were significantly affected by heterogeneity between individual studies, we performed meta-regression analysis. We considered variates to be explanatory if their regression coefficients were statistically significant (P < .05). Publication bias was examined by using funnel plots with the log OR plotted against the standard error of the log OR in each study.

Eligible Studies

Tables 2–4 summarize the included studies, classified according to technique.^10–33 Our search strategy identified 326 articles. After we ruled out the obviously irrelevant abstracts, 66 studies were left, and their full texts were obtained, 19 of which satisfied all inclusion criteria.^{11,13,14,16–21,23–28,30–33} Forty-seven articles were excluded for the following reasons: 1) enrolling exclusively demented (n = 16) or healthy subjects (n = 3); 2) cross-sectional studies (n = 4) or longitudinal studies not following clinical diagnosis or histopathologic diagnosis as a reference standard (n = 1); 3) presented results from a combination of other diagnostic modalities such as neuropsychological tests that could not be differentiated (n = 3); 4) not presenting sufficient data to create a 2 × 2 contingency table (n = 16); 5) review or symposium (n = 3); and 6) clinical trials of medicine (n = 1).

Although the imaging analytic method was not available in the study by Silverman et al,¹⁵ it was stated that to avoid bias, at the time the scan findings were reported, readers were blinded to clinical follow-up data of scanned patients; therefore, the study was also included. Our manual search of the reference lists of retrieved articles and several reviews and articles citing these articles identified 5 articles that met all inclusion criteria.^{10,12,15,22,29} Although the article of Huang et al, published in 2003,²² overlapped another eligible study published in 2002,²³ the end point of patients in the latter was diagnosis of AD, which was more relevant to the aim of our meta-analysis than the former with the end point of dementia; thus, analyses were also done including the article in 2002. Therefore, 24 eligible studies^10–33 (6 FDG-PET, 8 SPECT, and 10 MR imaging) were finally included in the meta-analysis.

Some enrolled patients were diagnosed with synonyms of MCI as mentioned before. Because these criteria were similar to those of MCI, we accepted these patients as having MCI (Table 1). Four studies narrowed their included patients to those having amnestic MCI,^11,13,21,32 the most common form of MCI with a higher risk of progressing to AD (10%–30% per year).⁵ Although other forms of MCI were not so tightly associated with memory disturbance and might progress to disorders other than AD, we still treated these studies as eligible, taking into account the limited number of included studies. To evaluate and explain the heterogeneity, we performed subgroup analyses between studies enrolling patients of different diagnoses. Although most articles adopted the diagnosis of AD as an end point, progression was evaluated according to patients’ changes in MMSE scores in the study of Silverman et al.¹⁵ In the 4 other studies, patients progressed to AD as well as to other types of dementia.^17,22,27,29 Taking into account the relatively small portion of dementia other than AD (non-AD-dementia/all subjects, 16.9%), we still enrolled these studies. Subgroup analyses were executed afterward to evaluate the contribution of the 4 studies to the heterogeneity. Allowing both between- and within-study variation, we selected a random-effects model whose results were more conservative than those with a fixed-effects model.

Data Synthesis

For each technique, the weighted summary of sensitivity, specificity, LR, OR, and their 95% CIs, P value for heterogeneity, and I² value are summarized in Table 5. No 95% CI of OR and LR included 1, confirming the diagnostic value of all modalities. Although no statistically significant difference was found (P > .05) for each technique in pooled sensitivity, sensitivity, and LR−, FDG-PET had the highest pooled OR and LR+ (P < .05). No statistical difference was confirmed between SPECT and MR imaging. The summary ROC curves, Q* index, and AUC for FDG-PET, SPECT, and MR imaging are shown in Fig 1. The Q* index estimates for FDG-PET, SPECT, and MR imaging were 0.86, 0.75, and 0.76, respectively. No significant difference was found in analyses, including the article of Huang et al in 2002.²³

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Fig 1.

A−C, Summary ROC curves for PET, SPECT, and MR imaging. The middle black line is the summary ROC (SROC) curve, and the 2 lines beside it are 95% CIs. SE(AUC) indicates standard error of area under the ROC curve; SE(Q*), standard area of Q*; MRI, MR imaging.

I² is an index for heterogeneity: I² = (Q − [k − 1]) / Q × 100%, where Q is the χ² value of heterogeneity and k is the number of studies included. Along with P < .05 for heterogeneity, I² > 50% further indicates heterogeneity between studies. The heterogeneity in the LR− test of FDG-PET and the LR+ test of SPECT was highly statistically significant (P < .001 and I² > 80%), confirming that there was strong evidence of between-study heterogeneity (Table 5). To assess possible explanations for the heterogeneity, we applied single-factor meta-regression analysis by adding the publication year, age, male-female distribution, follow-up interval, years of education, and mean score of the MMSE at baseline separately as variates. No apparent relationships were found between these variables and log OR (P > .05). Statistical significance (P = .027) was found only between technique and log OR, with a regression coefficient of −0.575. Subgroup analyses for diagnoses at baseline (MCI versus synonyms of MCI) and patients’ end points (exclusively AD versus dementia including AD) were also executed regardless of technique, due to the limited amount of studies. The OR of studies evaluating patients converting to AD was higher than that evaluating patients with dementia (P = .03), whereas the sensitivity, specificity, LR+, and LR− showed no statistical difference (P > .05). No significant difference was found between studies differing in inclusive diagnoses. Fig 2 demonstrates the funnel plots of all modalities. Marked asymmetry, with studies missing from the bottom left quadrant, suggests a publication bias; additional studies with an OR of approximately 1 might have been conducted but not published because of unfavorable results.³⁴

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Fig 2.

Funnel plot of with pseudo-95% CIs.