Metformin in Amnestic Mild Cognitive Impairment: Results of a Pilot Randomized Placebo Controlled Clinical Trial

Abstract

Diabetes and hyperinsulinemia may be risk factors for Alzheimer’s disease (AD). We conducted a pilot study of metformin, a medication efficacious in treating and preventing diabetes while reducing hyperinsulinemia, among persons with amnestic mild cognitive impairment (aMCI) with the goal of collecting preliminary data on feasibility, safety, and efficacy. Participants were 80 men and women aged 55 to 90 years with aMCI, overweight or obese, without treated diabetes. We randomized participants to metformin 1000 mg twice a day or matching placebo for 12 months. The co-primary clinical outcomes were changes from baseline to 12 months in total recall of the Selective Reminding Test (SRT) and the score of the Alzheimer’s Disease Assessment Scale-cognitive subscale (ADAS-cog). The secondary outcome was change in relative glucose uptake in the posterior cingulate-precuneus in brain fluorodeoxyglucose positron emission tomography. Change in plasma Aβ₄₂ was an exploratory outcome. The mean age of participants was 65 years. Fifty percent of participants were women. The only baseline variable that was different between the arms was the ADAS-Cog. Metformin could not be tolerated by 7.5% of participants; 15% tolerated 500 mg/day, 35% tolerated 1000 mg/day, 32.5% tolerated 1500 mg/day, and only 10% tolerated the maximum dose. There were no serious adverse events related to metformin. The 7.5% of persons who did not tolerate metformin reported gastrointestinal symptoms. After adjusting for baseline ADAS-cog, changes in total recall of the SRT favored the metformin group (9.7±8.5 versus 5.3±8.5; p = 0.02). Differences for other outcomes were not significant. A larger trial seems warranted to evaluate the efficacy and cognitive safety of metformin in prodromal AD.

Keywords

Amnestic mild cognitive impairment insulin memory metformin randomized clinical trial

INTRODUCTION

The most common cause of late onset dementia is Alzheimer’s disease (AD) [1], comprising between 60 and 80% of cases. Vascular dementia is the second most common cause, comprising about 10% of cases, but approximately 50% of cases of dementia have a vascular component [1]. Nearly half of persons 85 years and older have late onset AD [2] and the prevalence worldwide will quadruple by mid-century [3]. A key process in AD causation is the deposition of amyloid-β (Aβ) in the brain [4], but other factors, such as cerebrovascular disease, may also be important [5]. The natural history of AD starts slowly in late middle age with mild memory deficits that progress to amnestic mild cognitive impairment (aMCI) [6], which in turn progresses to dementia [7]. Thus, aMCI is considered a high risk group for dementia [6] and has become a common target for secondary prevention. Clinical trials in aMCI and AD have thus far been disappointing [8] and an expert panel from NIH concluded in 2010 that there was insufficient evidence to recommend treatment of aMCI or prevention for AD [9]. In this context, the search for strategies for the prevention and treatment of AD continues. Type 2 diabetes (T2D) and its correlates and antecedents, insulin resistance and elevated adiposity (overweight and obesity), have shown strong associations with AD in observational studies [10, 11]. These observations have enormous public health implications because two-thirds of adult Americans are overweight or obese (body mass index (BMI)≥25 m/k²) [12], and are at high risk for insulin resistance and T2D [13]. Among persons 60 years and older, a group with high prevalence of aMCI [14, 15] and AD, 69% were overweight or obese in 2008 [12], and 60% have pre-T2D or T2D [16]. Thus, a majority of Americans in the age group at risk for AD have insulin resistance and T2D [17]. Insulin resistance and T2D are known cerebrovascular risk factors[18], and it seems reasonable to postulate that insulin resistance and T2D could increase AD risk through cerebrovascular disease, a factor increasingly accepted to be important in AD manifestation [5 , 19–21]. However, peripheral insulin resistance and hyperinsulinemia may also affect AD directly [22]. Since insulin resistance could increase the risk of AD through both cerebrovascular and Aβ-related mechanisms [11], it has been hypothesized that pharmacologic strategies effective in preventing diabetes while decreasing insulin resistance may prevent AD [11]. One of these strategies is the use of the medication metformin. Metformin is a safe, inexpensive medication available in generic form with proven efficacy in treating and preventing T2D though the reduction of peripheral glucose and insulin levels [23, 24]. Thus, we conducted a pilot study of AD prevention among persons with aMCI at risk for T2D to obtain preliminary evidence of feasibility, safety, and efficacy.

MATERIALS AND METHODS

Design

This study was a double-blind placebo-controlled randomized pilot trial of metformin 1000 mg twice a day versus matching placebo for 12 months in 80 subjects with aMCI. Participants were randomized to metformin or placebo in a 1:1 ratio. To balance factors that may influence treatment outcome, randomization was stratified and blocked. The only stratification variable was the presence or absence of APOE-ɛ4 genotype. The rationale for this stratification was that observational studies have shown that APOE-ɛ4 genotype modifies the association of hyperinsulinemia and diabetes with AD (risk is much higher in those with APOE-ɛ4) [25 –27], and a pilot randomized trial of the insulin sensitizer rosiglitazone reported that this medication was only efficacious among persons without APOE-ɛ4 [28]. Allocation concealment was maintained by randomly alternating block sizes. Participants were seen once a week in the first 4 weeks of the study during metformin titration and were then evaluated at months 3, 6, 9, and 12, including the neuropsychological battery. Half the sample (40 participants) were invited to participate in a brain imaging sub-study.

All participants were invited to undergo brain imaging at baseline and after the 12-month visit and were selected if they agreed to undergo brain imaging and if they had no exclusion criteria for brain imaging.

Setting

The study was a single site study based at Columbia University Medical Center in New York City.

Participants

Table 1 summarizes the main inclusion and exclusion criteria. Participants were 80 subjects aged 55 to 90 years with aMCI defined by the Petersen criteria [29], without treated diabetes, and with a BMI of 25 kg/m² or higher (overweight or obese by National Heart, Lung, and Blood Institute) criteria [30]). The rationale for limiting the study to aMCI was that aMCI is a transitional stage from normal cognition to dementia that is considered a target for secondary prevention of dementia [31]. The rationale for the age group was that the 55- to 90-year-old group is considered most susceptible to cognitive impairment and thus commonly evaluated in treatment trials of aMCI such as the Alzheimer’s Disease Cooperative Study (ADCS) clinical trial of vitamin E and donepezil [32]. The rationale for not including persons with treated T2D is that the hypothesized main mechanism of metformin is the lowering of insulin levels, and persons with diabetes are treated with medications that can both increase insulin levels (exogenous insulin, sulfonylureas) and medications that can decrease insulin levels (metformin, thiazolidinediones)[33]. We screened for T2D by medical history but also by hemoglobin A1c (HbA1c) in blood. Our exclusion criterion related to T2D changed in the following way during the course of the study. In September of 2008, when one participant had been enrolled, we changed the inclusion criteria from excluding all persons with a history of T2D to accepting persons with T2D with an HbA1c of 6.5% or less who were not on any medication. The justification for this change was that we discovered in our recruitment efforts that there were many persons with a history of T2D that were not treated, leading to a high proportion of exclusion due to untreated T2D. We chose the cutoff of 6.5% in HbA1c because persons with this level of HbA1c seemed unlikely to receive pharmacologic treatment for T2D, including metformin, during the 12 months of the study. In January of 2010, the American Diabetes Association (ADA) adopted diabetes diagnosis guidelines using HbA1c (6.5% or more) for the first time [34]. Thus, we modified our inclusion criteria in March of 2010, when 60 participants had been enrolled. If persons without a history of diabetes were found to have an HbA1c of 6.5% , they were informed that they met criteria for T2D. We allowed participation of subjects who met HbA1c criteria for diabetes, who were not on diabetes treatment, and with a HbA1c of 6.9% or less (the ADA recommends maintaining a HbA1c of less than 7% [34]), and who upon consultation with their physicians were deemed not to need pharmacologic treatment for T2D.

The rationale for the BMI cutoff is that there is no standard for the diagnosis of hyperinsulinemia in research or clinical practice [17]. Thus, we limited inclusion to persons with aMCI who were overweight or obese (BMI≥25 m/k²), definitions of elevated adiposity in research and clinical practice [35], and a surrogate marker of hyperinsulinemia [36], because they were the most likely to benefit from the insulin lowering action of metformin.

Screening was conducted following a 2-step process. First, participants who were interested in participating were screened by telephone for demographic and medical inclusion and exclusion criteria. The Telephone Interview for Cognitive Status (TICS)[37] was administered if the potential participant agreed to screen out persons who were unlikely to have any memory impairment. A TICS score > 34 out of 41 was considered normal cognition. Persons with this score were not invited to participate. Persons who passed the telephone screen were invited for an in-person screening that included a physical exam, blood tests, and a neuropsychological battery.

Intervention

Participants were randomized to identical-appearing pills of metformin or matching placebo provided by Merck-Lipha of France. The maximum dose of metformin was 1000 mg twice a day, as is commonly used in clinical practice. Metformin was administered as 500 mg tablets. Metformin was titrated weekly from 500 mg once a day to 1000 mg twice a day over 4 weeks. Subjects were maintained on the highest tolerated dose. Participants who did not tolerate the study drug were invited to continue in the study and were included in the intent-to-treat analyses. Metformin and placebo were supplied every 3 months, when participants were asked for side effects and contraindications to metformin in addition to undergoing safety laboratory tests. The most common side effect of metformin is gastrointestinal intolerance, which can range from bloating to frank diarrhea [38]. In clinical practice, patients taking metformin can often break through these symptoms after a few weeks and tolerate the drug well. However, we were conservative and maintained participants on the dose of metformin at which they had no symptoms.

Outcomes

Primary clinical outcomes

The primary outcomes of the study were changes from baseline to month 12 in total recall of the Bushcke Selective Reminding Test (SRT) [39] and the Alzheimer’s Disease Assessment Scale-cognitive subscale (ADAS-cog) [40]. The rationale for using the SRT is that it has been extensively used to assess aMCI [14, 41] and AD [42] in the community of Northern Manhattan surrounding Columbia University Medical Center, where the study was based. The rationale for using the ADAS-Cog is that it is commonly used for clinical trials of aMCI [32] and AD. Other clinical measures in the study included the ADCS Clinical Global Impression of Change for Mild Cognitive Impairment (CGIC-MCI) [43], the logical memory II delayed paragraph recall sub-test of the Wechsler Memory Scale Revised [44], the Mini-Mental Status Exam (MMSE) [45], the Neuropsychiatric Inventory Questionnaire [46], and the digit span backwards [47].

Imaging outcomes

The primary imaging outcome was changes from baseline to month 12 in relative glucose uptake (rCMRgl) in the posterior cingulate-precuneus measuredby non-quantitative brain [¹⁸]F-labeled 2-deoxy-2-fluoro-D-glucose (FDG) positron emission tomography (PET) with magnetic resonance imaging (MRI) co-registration. PET imaging was performed with a HR+scanner (Siemens/CTI, Knoxville, TN) at the Columbia Kreitchman PET center. This region of interest was chosen because CMRgl reductions in this region are correlated with dementia severity [48] and progression [49]. FDG PET with MRI coregistration and a region of interest (ROI) approach as conducted in this study have been shown to have good 6-month test-retest reliability for ROIs affected in AD[7]. Cerebellum rCMRgl is not expected to change with AD progression and was chosen as the reference ROI for standardization [50]. The FDG PET results are shown as changes from baseline to 12 months in ratios of rCMRgl of the ROI weighted by the ROI volume and the rCMRgl of the cerebellum. We did not expect to have interference of extreme glucose levels with PET readings because we excluded subjects with treated diabetes from the trial and because metformin does not produce hypoglycemia [38]. However, we conducted a washout period of 2 weeks [51] at the end of the trial before performing FDG PET to ensure that changes in rCMRgl were not due to acute changes in glucose due to metformin. It has been estimated that 26% of the metabolic effects of metformin are acute and disappear upon withdrawal of the medication [51]. Brain MRI was acquired at the Hatch MRI Research Center at Columbia University Medical Center for co-registration of FDG PET images using a 1.5T Philips Intera scanner with an 8 channel receive coil following a protocol similar to the Alzheimer’s Disease Neuroimaging Initiative [52]. The primary ROI was the posterior cingulate-precuneus [53]. This ROI included the precuneus and posterior cingulate gyrus together, because they share the same pathological features in AD. The cingulate sulcus, the callosal sulcus, the inter-hemispheric fissure, and the parieto-occipital fissure were identified in the orthogonal view. The line was then extended between the cingulate and callosal sulci that is the antero-superior limit of the ROI, then posteriorly and inferiorly over the callosal sulcus until reaching the fundus of this sulcus. It was then extended posteriorly and superiorly over the parieto-occipital fissure up to the end. Then, the contour of the precuneus was followed anteriorly and superiorly to the marginal segment of the cingulate sulcus. It was then extended anteriorly over the cingulate sulcus until reaching the other anterior end.

Plasma amyloid-β

Plasma Aβ₄₂ levels were measured in plasma using a combination of monoclonal antibody 6E10 (specific to an epitope present on 1 to 16 amino acid residues of Aβ) and rabbit antibodies specific for Aβ₄₂ (R165) in a double-antibody sandwich ELISA [54]. The detection limit for this assay was 10 pg/mL for Aβ₄₂. The test–retest reliability of the measurement of plasma Aβ₄₂ is excellent (Cronbach’s α coefficient = 0.91).

Other measures

Genotyping of APOE polymorphisms rs7412 and rs429358 was performed at PreventionGenetics (http://www.preventiongenetics.com) with an array tape [5] using allele-specific PCR with universal molecular beacons [56, 57]. DNA sequencing of positive control DNA samples were completed to assure correct assignment of alleles. APOE-ɛ4 genotyping was conducted within one week of acceptance into the trial and was used for randomization purposes. Insulin was measured using a solid-phase chemiluminescent enzyme immunoassay (Immulite, Diagnostic Products Co, Los Angeles, CA). Intra- and inter-assay coefficients of variation are 4.7% and 8.2% , respectively. The normal insulin range for this assay is 6–27μIU/ml. HbA1c and lipids (total cholesterol, high density lipoprotein) were measured at baseline and each follow-up to document the hypothesized metabolic effect which is similar to insulin [58]. High-sensitivity C-Reactive protein (hsCRP) was measured as a marker of systemic inflammation and vascular risk [59, 60] that predicts memory impairment in our population [61] using ELISA (Diagnostic Systems Laboratories, Inc., Webster, TX). Insulin and hsCRP were measured in all samples at the same time at the end of the study. Thyroid stimulating hormone, vitamin B12, and syphilis rapid plasma reagin were assessed at screening.

Statistical analyses

Given that the study was planned as a pilot clinical trial with the goal of collecting preliminary data on safety, feasibility, and efficacy, it was powered to detect a large difference (0.75 standard deviations) in the change in the outcomes at 12 months with a sample size of 30 persons per group (total 60 groups). We obtained supplementary funding and increased the sample size from 60 to 80 participants. Initial analyses were conducted blinded to true treatment allocation. Treatment unblinding was conducted after analyses were checked for quality. The data coordinating center at the Department of Biostatistics at Columbia University Medical Center generated the random allocation sequence. The data coordinating center resided in a building separate from where the study team resided. Only the statistician had access to the randomization sequence. The assistant assigning the participants to interventions and the staff recruiting and evaluating participants did not have access to the randomization sequence. All measurements and laboratory assessments were conducted at the Irving institute for Clinical Translational Research at Columbia University Medical Center. The coordinators conducting outcomes assessments were blinded from these data. No interim analyses were planned or conducted during the conduct of the clinical trial.

For comparison of baseline characteristics between the metformin and placebo group T-tests were used to compare means, and chi-squared to compare proportions. Analysis of covariance (ANCOVA) was used to compare outcomes between the treatment groups following an intent-to-treat (ITT) approach adjusting for variables that were different at baseline if necessary. The primary clinical outcomes were changes from baseline to 12 months in total recall of the SRT and total score of the ADAS-COG. The primary imaging outcome was changes from baseline to 12 months in rCMRgl in the posterior cingulate-precuneus. The exploratory outcome was changes from baseline to 12 months in plasma Aβ₄₂. Imputation with last-observation-carried-forward was used to account for missing follow-up data. We conducted similar analyses for the secondary outcomes and for changes in pertinent metabolic measures related to the effect of metformin such as insulin and hsCRP. Finally we conducted post-hoc analyses relating the dose of metformin (1, 2, 3, or 4 tablets a day) to the outcomes with linear regression using placebo and the persons who did not tolerate metformin as the reference (completers analysis) and stratified analyses by APOE-ɛ4, baseline age, BMI, fasting insulin, and HbA1c categorized by the median. The level of significance was established at a two-sided alpha of 0.05. This study was approved by the Institutional Review Board of Columbia University Medical Center (AAAC7231) and was registered in ClinicalTrials.gov (ID NCT00620191). All study participants provided written informed consent.

RESULTS

Participant characteristics

Figure 1 shows the CONSORT flowchart. Recruitment was completed in 32 months (2.5 subjects a month) [36]; 1426 subjects were screened by telephone and 331 were screened in person; 65 subjects (81%) completed 12 months, 6 subjects (7.5 %) completed 9 months, and 9 subjects (11.2%) had less than 9 months of follow-up. At 12 months, study completion was similar in the 2 arms (33 persons completed the placebo arm and 32 the metformin arm; p = 0.99). The only statistically significant difference between the groups at baseline (Table 2) was the ADAS-Cog score, which was lower (better) in the metformin group. Thus, the comparison of the primary outcomes is adjusted for this variable.

Compliance with metformin and adverse Events

Compliance with metformin was as follows: 7.5% stopped metformin but continued in the study following ITT, 15% remained on 500 mg a day (1 tablet), 35% remained on 1000 mg a day (2 tablets), 32.5% remained on 1500 mg a day (3 tablets), and 10% tolerated the maximum dose of 2,000 mg a day (4 tablets). In terms of safety, there were no serious adverse events related to metformin and the 7.5% of persons who were not able to tolerate metformin reported gastrointestinal symptoms.

Changes of metabolic measures by randomization arms

Fasting insulin increased appreciably more in the placebo group compared with the metformin group as expected, and this difference was close to statistical significance (13.8 versus 4.7 IU/ml; p = 0.09). hsCRP, a measure of inflammation and vascular risk [60], and a correlate of memory impairment in our center [61], decreased in the metformin group and increased in the placebo group (–0.3 versus 1.0 mg/dl; p = 0.07). Weight decreased more in the metformin group (–2.7±6.4 Kg) compared with the placebo group (–1.6±4.5 Kg) but this difference was not statistically significant (p = 0.63). HbA1c decreased modestly more in the metformin group (–0.3±0.7 %) compared with the placebo group (–0.2±0.5), but this difference was not statistically significant (p = 0.64).

Changes in the clinical outcomes

Primary analyses

Table 3 shows the comparison in the primary clinical outcomes of the study, changes from baseline to month 12 in the ADAS-Cog score, and the total recall of the SRT. Both the SRT and ADAS-COG scores improved in the placebo and metformin groups (increases in SRT total recall, decreases in ADAS-COG scores). Crude analyses showed a greater improvement in the SRT in the metformin group, but the difference for the ADAS-Cog favored the placebo group. However, after adjustment for baseline ADAS-Cog the metformin group showed significantly greater improvement in SRT total recall compared to placebo (difference in changes in total recall of the SRT of metformin versus placebo = 4.4±8.5 words) and the difference for the ADAS-Cog was attenuated and not significant. The results were similar for delayed recall of the SRT, in which the gain in words was higher in the metformin group (2.3±2.5) compared to the placebo group (1.3±2.3) and was close to statistical significance (p = 0.06). There were no differences in delayed recall of the ADAS-cog (0.7±1.8 for metformin versus 0.0±2.5 for placebo; p = 0.35).

There were no differences between metformin and placebo in changes in digit span backwards, the neuropsychiatric inventory, the MMSE, paragraph recall, or CGIC-MCI (Supplementary Table 1). One person in the placebo group and none in the metformin group converted to dementia.

Post hoc analyses of primary outcomes

We conducted linear regression models examining the relation of the metformin dose with the primary outcomes, changes in total recall of the SRT and the total score of the ADAS-cog. The highest metformin dose (1000 mg twice a day) was associated with a statistically significant increase of 5.3±10.0 more words in total recall of the SRT (p = 0.03) compared to those in the placebo group and those who could not tolerate metformin. There was no association between the highest metformin dose and changes in the ADAS-Cog (0.7±4.8; p = 0.56).

Table 4 shows the results of stratified analyses by age, APOE-ɛ4 status, BMI category, baseline HbA1c, and fasting insulin levels. Metformin showed better performance compared with placebo in younger persons, those without APOE-ɛ4, those with lower HbA1c, and those with higher insulin levels. There were no differences for the ADAS-Cog in any of the strata.

Changes in biomarker outcomes

Follow-up MRI and PET were completed in 33 out of 40 participants (15 in the metformin group, 18 in the placebo group, 82.5% completion overall). Changes from baseline to 12 months in the posterior cingulate-precuneus rCMRgl, adjusted for cerebellar CMRgl uptake, showed a difference favoring metformin that was not statistically significant (2.0±6.3% versus 0.0±6.0% ; p = 0.36). Secondary ROIs including hippocampus (2.4±4.7% versus 1.0±5.1% ; p = 0.73), para-hippocampus (3.3±5.5% versus 2.0±5.1% ; p = 0.76), and entorhinal cortex (5.3±9.0% versus 1.3±6.0; p = 0.16) favored metformin but were not statistically significant. None of the differences in changes in plasma Aβ₄₂ were statistically significant. Plasma Aβ₄₂ increased in the metformin group (0.69±18.5 pg/ml) and decreased in the placebo group (–4.40±23.51 pg/ml; p = 0.3).

DISCUSSION

We found in a pilot study that conducting a randomized trial of metformin in persons with aMCI was feasible and safe. We also found preliminary evidence of efficacy for one of the primary outcomes, total recall in the SRT, but not the other, the ADAS-Cog, after adjusting for the baseline difference in the ADAS-Cog. Post hoc analyses suggest that the benefit on the SRT total recall is higher with the highest metformin dose, among younger subjects, among those without APOE-ɛ4, among those with the lower HbA1c, and those with the highest baseline fasting insulin. Differences between metformin and placebo in changes in the primary and exploratory biomarker outcomes were not significantly different but the direction of the difference modestly favored metformin and supported the finding for the SRT. However, given the pilot nature of our study with a relatively small sample size and the potential for chance findings, our preliminary evidence of efficacy should be taken with caution.

The finding that diabetes and insulin resistance are related to an increased risk of AD has prompted the exploration of related strategies for treatment and prevention of AD [11]. This is supported by basic and experimental data showing that diabetes and insulin resistance may affect amyloid clearance in the brain [22]. Pursuing these strategies is feasible because of the existence of known effective pharmacologic and non-pharmacologic strategies for the prevention of diabetes and the improvement of insulin resistance. The best and safest strategy for preventing diabetes and decreasing insulin resistance is lifestyle interventions. Lifestyle interventions (exercise and diet) are the best insulin sensitizers, but require substantial support and resources in clinical trials that are difficult to sustain in the long term and replicate in “real world” settings [62]. Among the pharmacologic strategies, the thiazolidenidiones, also known as PPAR-gamma agonists, are powerful insulin sensitizers effective in lowering insulin resistance [63] and preventing T2D [64], with efficacy similar to lifestyle strategies and greater than metformin [65]. However, they have concerning side effects including edema, congestive heart failure, and in the case of rosiglitazone, myocardial infarction [66], which led to a black box warning from the Food and Drug Administration [67]. The thiazolidinedione rosiglitazone was tested for secondary prevention of cognitive decline in mild AD among persons without T2D and was found to be non-efficacious in a trial of 511 persons[68] after promising results in a smaller study [69]. However, it seems reasonable to speculate that the negative vascular effects of rosiglitazone [67], including cerebrovascular effects, may have eclipsed the beneficial effects on AD [11].

Metformin is a medication belonging to the biguanide class [38, 70]. It treats and prevents diabetes by suppression of hepatic glucose output, increasing insulin mediated glucose disposal, by increased intestinal glucose use, and by decreasing fatty acid oxidation [71]; this is accompanied by reduced pancreatic insulin secretion and lower insulin levels in blood in response to glucose loads. While the mechanisms for the action of metformin are not completely understood [24], it clearly reduces insulin levels [23], inflammation and thrombosis [72], and the risk of the metabolic syndrome [73] and T2D [74] in persons at risk. Metformin is usually the first step in pharmacological treatment of T2D [75], but it is increasingly used for T2D prevention based on the findings of the landmark Diabetes Prevention Program (DPP) [74], the largest trial of metformin among persons without T2D. In the DPP, metformin was more effective than lifestyle intervention in preventing T2D after 10 years [62]. The only common side effect of metformin in clinical trials has been gastrointestinal intolerance, occurring in a minority of subjects. In the DPP, the rate of serious adverse events for metformin was the same as for placebo. The side effects and safety for metformin in our trial were similar to published research and clinical experience. Metformin is not directly active in the brain [38], and we postulate that it acts on the AD process through reduction of peripheral insulin levels that affect brain clearance of Aβ [76 –78]. In addition, metformin also decreases advanced glycation end products [79, 80], inflammation [72], coagulation [72], and prevents the metabolic syndrome (diabetes, hypertension, obesity, dyslipidemia) [73], factors that may also influence AD risk through cerebrovascular or neurodegenerative mechanisms [11]. However, metformin has been reported to increase production of Aβ in a cell culture model [81], and two retrospective studies reported that among persons with T2D, a diagnosis of dementia was associated with metformin use [82, 83]. These reports conflict with animal studies showing that metformin decreases AD neuropathology [84, 85] and an epidemiologic study that showed that metformin is related to lower AD risk among persons with T2D [86].

Several of our observations merit further discussion. First, our study showed improvements in both clinical outcomes, contrary to the idea that cognition declines with time. However, we interpret this finding as evidence of practice effects, which are increasingly recognized in aMCI [87], are inversely related with conversion to AD, and can be examined as an outcome in clinical trials [88]. Second, we found a result benefiting metformin for the SRT but not for the ADAS-Cog. Moreover, the difference for the ADAS-cog seemed to benefit placebo in unadjusted analyses. The difference for the ADAS-cog favoring placebo disappeared after adjusting for the significant differences in baseline ADAS-cog, while the differences in the SRT persisted. The opposite directions of effect for the ADAS-cog and the SRT seem to have been explained by a baseline difference in the ADAS-cog. While the ADAS-Cog has been the standard for measurement of cognitive change in clinical trials, it is increasingly recognized that it may not be sensitive enough to detect change in aMCI, and more sensitive instruments such as measures of recall are increasingly being considered in clinical trials individually or to strengthen the ADAS-Cog [89]. In post hoc analyses, we found that younger persons, those without the APOE-ɛ4 allele, those with lower HbA1c, and those with higher insulin, seemed to benefit from metformin in terms of SRT performance. Although these results could be due to chance, we can speculate about their plausibility. In terms of age group, the benefits of metformin on diabetes prevention have been shown to be stronger in younger persons [62], consistent with our findings. In terms of the APOE-ɛ4 allele, a previous study of the insulin sensitizer rosiglitazone had similar findings [68]. This makes sense if one considers that persons with both insulin resistance and an APOE-ɛ4 allele have a higher risk of AD than with either one or none of these risk factors [25]. In terms of HbA1c, those with higher levels may have more advanced hyperglycemia that may be less amenable to prevention-hyperglycemia ensues when pancreatic insulin production can no longer overcome insulin resistance, reflecting a more advanced stage in the natural history leading to T2D. In terms of insulin levels, it seems reasonable that those with the higher insulin have more opportunity for a decrease in insulin with medications and a better opportunity for benefit. Our main imaging outcome did not show statistically significant differences. It has been estimated that sample sizes of several hundred persons with prodromal AD are needed to detect appreciable differences in rCMRgl at longer follow-up periods than our trial [90]. Thus, we were not powered to detect significant differences, but our results were not inconsistent with those showing benefit for the SRT. The decrease in plasma Aβ₄₂ observed in the placebo group was similar to that in a pilot study of rosiglitazone in mild AD [69] and decreases in plasma Aβ₄₂ predict future AD [91]. Although the results for plasma Aβ₄₂ were not significant and this biomarker was exploratory, the findings show a direction of benefit as with the SRT.

It seems safe and feasible to conduct a randomized trial of metformin among persons with MCI although we encountered important challenges. These challenges included a long recruitment period due in part to a large number of subjects needing to be screened, the inability to achieve the maximum metformin dose in the majority of participants, and the inability of some participants to tolerate metformin at all. Potential ways to overcome recruitment challenges include conducting a clinical trial at multiple sites and extending the inclusion criteria to include earlier forms of prodromal AD, such as early MCI and subjective memory impairment [92] instead of restricting the sample to the original MCI criteria. A potential way to improve tolerance and achievement of the maximum dose is to use long-acting forms of metformin [93] instead of the short acting form that we used. Despite these challenges, we cautiously believe that there are preliminary findings justify the conduct of larger clinical trial. We acknowledge that our results must be interpreted with caution because of the inconsistency of the results for the SRT and ADAS-cog, and because the results of post-hoc analyses are subject to chance. This study needs to be followed by a larger efficacy trial with sufficient sample size to examine results in subgroups of age, APOE-ɛ4, and levels of glycemia and insulin. The difference of approximately 4 words in total SRT recall (out of a possible 72) observed between metformin and placebo represents a small but potentially clinically significant difference of approximately 0.5 standard deviations [94]. Our biomarker analyses did not provide insight into the potential impact of metformin on neurodegeneration. Future studies should ideally include AD biomarkers in CSF or imaging markers such as PET with an amyloid ligand. Future studies should also include systematic measures of cerebrovascular disease, which were not part of our protocol. Among the strategies related to insulin resistance that could potentially be used for AD prevention, metformin seems to be the safest, cheapest, and most sustainable. In addition, since metformin is so widely used, it is important to establish its cognitive safety in light of conflicting evidence about its effect on AD.

Footnotes

ACKNOWLEDGMENTS

This project was funded by the National Institute on Aging (R01 AG026413), the Alzheimer’s Disease Drug Discovery Foundation (Grant # 270901), and a Florence and Herbert Irving Scholar Award from the Irving Institute for Clinical Translational Research at Columbia University Medical Center. Metformin and matching placebo were provided free of cost by Merck Santé s.a.s. (Lyon, France). Support for laboratory assays and outpatient evaluations was provided by the Irving Institute for Clinical Translational research, funded by a Clinical Translational Science Award (UL1 RR024156 and UL1 TR000040). We would like to thank all the persons who approached us to enroll in the study, and in particular, the 80 persons who generously participated in the trial.

Authors’ disclosures available online ().

Appendix

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