Thirty healthy older subjects between the age of 50 and 79 years were recruited in this study (14 f; mean/SD age: 62/6 years). They were all right-handed, German native speakers, with no history of neurological diseases. Neuropsychological testing was performed for all participants to assure normal cognitive functioning within age- and education-related norms (CERAD-Plus)¹ (Table 1). The study was approved by the Ethics Committee of the Charité University Medicine and conducted in accordance with the Helsinki Declaration. Written informed consent was obtained from all participants prior to participation.

The task was adapted from previous studies (Breitenstein and Knecht, 2002; Breitenstein et al., 2005; Floel et al., 2008; Antonenko et al., 2016a, 2019), and programmed using the software Presentation (Neurobehavioral Systems)². The paradigm consists of the presentation of 30 picture-pseudoword pairs. For each participant, a set of 30 pseudowords and 30 pictures of daily life were randomly matched to generate 30 “correct” picture-pseudoword combinations (e.g., elephant = “pari”), creating a “vocabulary” list which had to be learned over the course of five blocks and retrieved in a “transfer” block (where pictures were replaced by corresponding German words). “Incorrect” pairs (e.g., elephant = “ralm”) were created by combining a picture with other pseudowords from the set. The task was originally created to resemble natural language learning, so the underlying learning principle involves the detection of higher co-occurrences of “correct” compared to “incorrect” pairs (Breitenstein and Knecht, 2002).

During the learning phase, 600 trials were presented, divided into five blocks (120 trials per block). “Correct” pairings were presented ten times in total (i.e., twice in each block, totaling up to 60 “correct” pairs per block). Each of the 30 pictures was also presented ten times with varying “incorrect” pseudowords (i.e., each picture was paired with two different “incorrect” pseudowords per block, totaling up to 60 “incorrect” pairs per block). Each “incorrect” pairing was presented only once over the course of the whole task. Trial presentation order was randomized. Participants were instructed to answer as quickly as possible by button press if the pairing was “correct” or not, being however not informed about the underlying frequency principle. No feedback was given during the task. As the learning principle of the task is based on the detection of higher co-occurrences of (arbitrarily) “correct” compared to “incorrect” couplings (ratio 10:1) over the course of the five learning blocks, participants had to guess in the beginning of the task. In each trial of the learning phase, the picture was presented 200 ms after the onset of an auditory spoken pseudoword (normalized at the same loudness and length of 600 ms, delivered over headphones) and remained on the screen for 1500 ms. Performance accuracy increased from first to last learning block, indicating that participants were able to learn the pairings (repeated-measures ANOVA showed a significant main effect of learning blocks on performance accuracy [F(2.5, 71.0) = 74.43, p < 0.001, partial eta squared = 0.72), see Supplementary Figure S1 for individual learning curves).

During the retrieval block, corresponding spoken German words were presented instead of pictures together with the pseudowords. Stimulus count, underlying frequency principle (i.e., 60 “correct” and 60 “incorrect” pairings; the latter containing again different pseudowords than in the learning phase) and trial timings were identical to those in a learning block. Total duration of the task was 35 min. The task generated four response categories: hits (i.e., classifying a “correct” pair as “correct”), correct rejections (i.e., classifying an “incorrect” pair as “incorrect”), false alarms (i.e., classifying an “incorrect” pair as “correct”), and misses (i.e., classifying a “correct” pair as “incorrect”) (Lynn and Barrett, 2014). Distribution of performance in response categories was illustrated in Supplementary Figure S2. Percentage of total correct responses and percentage of correct responses in different response categories were examined in the retrieval phase.

MRI was performed using 3T Siemens Trio MR-System using 12-channel head coil at the Berlin Center for Advanced Neuroimaging. First, a 3D structural high-resolution T1-weighted magnetization prepared rapid gradient echo image was acquired with the subsequent characteristics; TR = 1900 ms, TE = 2.52 ms, 192 sagittal slices, voxel size = 1.0 mm³ × 1.0 mm³ × 1.0 mm³, flip angle = 9^o. Second, a diffusion-weighted spin-echo echo-planar imaging image was acquired with the subsequent characteristics; TR = 7500 ms, TE = 86 ms, 61 axial slices, voxel size = 2.3 mm³ × 2.3 mm³ × 2.3 mm³; 64 directions, b-value of 1000 s/mm², 1 b0.

Fornix FA showed a positive correlation with percentage of total correct responses (partial correlation coefficient: r (corrected for age) = 0.39, p = 0.035). In order to examine whether this relationship was specific to a response category, we further examined separate correlations between Fornix FA and percentage of hits and correct rejections: Fornix FA did not correlate with percentage of hits (partial r = −0.001, p = 0.995) but showed a positive correlation with percentage of correct rejections (partial r = 0.403, p = 0.030, Figure 1). FA values extracted from the uncinate fasciculus did not correlate with percentage of correct rejections (partial r = 0.299, p = 0.115, see Supplementary Figure S7).

Left DG volume showed no strong correlation with percentage of total correct responses (partial correlation coefficient: r (corrected for age) = 0.291, p = 0.126). In order to explore this relationship in different response categories, we further examined separate correlations between left DG volume and percentage of hits and correct rejections: left DG volume did not correlate with percentage of hits (partial r = −0.133, p = 0.492) but showed a positive correlation with percentage of correct rejections (partial r = 0.501, p = 0.006, Figure 1). Volume left CA1 did not correlate with percentage of correct rejections (partial r = 0.341, p = 0.071, see Supplementary Figure S7). Correlations with all other hippocampal subfields were statistically non-significant (Supplementary Table S1, all p’s > 0.05).

Our model including fornix FA, memory performance and left DG volume met the criteria for mediation, where path a, b and c showed significant associations (p < 0.05) and path c′ did not show significant associations (Table 2). Single mediation analysis (model A) showed an indirect effect of fornix FA on percentage of correct rejections, mediated by left DG volume, corrected for age (β = 1.50, 95% CI: 0.03, 4.57, Table 2 and Figure 2A). The mediation effect (path ab) constituted 48% of the total effect of fornix FA on percentage of correct rejections (path c). Reverse mediation analysis (model B) was performed to investigate whether fornix FA mediates the effect of left DG volume on percentage of correct rejections, as such, we can induce the specificity of left DG volume in mediating fornix FA effect of percentage of correct rejections. Reverse mediation analysis showed that fornix FA did not mediate the effect of left DG volume on percentage of correct rejections, corrected for age (β = 0.0007, 95% CI: −0.0005, 0.0019, Table 2 and Figure 2B). These findings support the mediation effects of left DG volume on the relationship between fornix FA and percentage of correct rejections. Further mediation analysis showed that neither left CA1 nor left subiculum mediated the effect of fornix FA on the percentage of correct rejections (Supplementary Figure S6).

Our finding of a positive association between fornix FA and memory performance is in line with previous studies in both young and older adults (Rudebeck et al., 2009; Douet and Chang, 2014; Ly et al., 2016). Ly et al. (2016) found that variability in fornix microstructure in middle-to-late aged adults was related to face recognition memory and partly explained preserved functional connectivity within hippocampal networks. A study by Metzler-Baddeley et al. (2011) further suggested that specifically age-related degradation of fornix microstructure as derived from individual fiber tracking was linked to memory recall performance in strategic and visual memory tasks in older adults (Metzler-Baddeley et al., 2011). Our data confirms the role of the fornix in older adults in verbal episodic memory (Metzler-Baddeley et al., 2011, 2012). Moreover, we found a positive link between fornix FA and percentage of correct rejections in older adults, indicating that preservation of forniceal fiber pathway integrity with increasing age may be crucial for the ability to detect false associations. We found no correlation of FA of the uncinate fasciculus with percentage of correct rejections. Bennett et al. (2015) found effects of fornix FA on the prediction of pattern separation performance. They also found no effect of uncinate fasciculus and cingulum bundle FA on the prediction pattern separation performance. Taken together, these findings suggest that pattern separation performance, corresponding to the ability to detect false associations, relies selectively on fornix microstructural integrity.

In line with previous studies, age-related preservation in left DG volumes was also associated with superior memory performance (Small et al., 2002; Toner et al., 2009; Stark and Stark, 2017; Bennett et al., 2018). Our data further suggests that in particular the inhibition of false memories may be sensitive to the effects of age-related atrophy in the left DG. This result complements the findings of Shing et al. (2011) who showed that DG volumes in healthy older adults were negatively correlated to false alarm rates [which are complementary to correct rejection rates (Lynn and Barrett, 2014)] in a word-pair learning task. The authors hypothesized that the role of the DG is to enhance the specificity of encoded memories. In order to store overlapping inputs, DG performs pattern separation that enables the correct retrieval of interfering information (Rolls, 2010). As such, successful rejection of false associations is based on the efficient representation of differences between the correct and the incorrect associations. Interestingly, older adults show a specific decrease in their pattern separation ability, making them more vulnerable to memory distortions (Toner et al., 2009; Stark et al., 2010). It is also possible that this specific association between left DG volume and correct rejections reveals the function of left DG in implementing retrieval strategies to prevent these memory distortions [for review (Kesner et al., 2004)]. Novelty detection is one strategy that has been related to the DG and that allows detection of newly presented information. Our findings lend further support to this concept, assuming that participants may have implemented this strategy to successfully detect new (i.e., incorrect) associations. Additionally, we found no correlation of percentage of correct rejections with left CA1 subfield volume, confirming that this subfield may not be crucial for pattern separation (Bakker et al., 2008). This suggests that our results were specific for the left DG.

In the present study, correct rejections, used as main outcome in the mediation analysis, most likely quantified pattern separation performance that has been associated to both, DG and fornix (Shing et al., 2011; Bennett et al., 2015). Combining both white matter microstructure and gray matter volume within the structural hippocampal memory network, our mediation analysis showed that the prediction of memory performance by fornix microstructure was partially mediated by the volume of left DG in older adults. Previous studies have shown a link between age-related decrease of fornix integrity and hippocampal atrophy (Pelletier et al., 2013; Zhuang et al., 2013; Wisse et al., 2015; Gazes et al., 2018). The directional relationship, however, remains unclear, as it is conceivable that both hippocampal gray matter loss induces fornix white matter fiber degeneration and vice versa (cf. Zhuang et al., 2013). So far, it has been shown that fornix microstructural degradation, and not hippocampal atrophy, served as a biomarker for early amnestic MCI due to AD (Zhuang et al., 2013). Further, using mediation analysis, a recent study provided evidence for a causal effect of age-related fornix white matter damage on hippocampal gray matter volume decline in healthy adults (Metzler-Baddeley et al., 2019). The current study complements previous evidence by demonstrating that fornix microstructure and left DG subfield volume interact to specifically mediate memory for false associations.

It should be noted that cells of the DG do not project outside of the hippocampal formation, so this area can provide only indirect input to the fornix (Insausti and Amaral, 2004). However, Gondard et al. (2015) showed that deep brain stimulation of the fornix activated the DG by modulating the expression of neurotrophic factors and markers of synaptic plasticity known to be crucial for memory processing. This association could be explained by the interconnectivity of subfields in the hippocampus, forming a functional unit within the hippocampal formation (cf. Duvernoy et al., 2005; Wisse et al., 2015). Based on this, one can assume that structural proximity between hippocampal subfields may make it difficult to clearly distinguish individual subfield function. Rather, the specificity of hippocampal subfields function may be demonstrated by its exclusive effect on specific cognitive outcomes. In patients with MCI and AD, in particular atrophy of the subiculum was associated with fornix microstructure (Wisse et al., 2015) which may point toward different patterns of hippocampal disconnection in early AD. Future studies are needed that unveil the interconnectivity between hippocampal subfields and white matter tracts involved in this circuit.

In conclusion, our mediation model offered a neurobehavioral model in which preserved fornix white matter microstructure in older age predicts successful retrieval of learned associations through its protective effect on gray matter volume in the left DG. Thus, demyelination, even in healthy aging, may induce gray matter loss reflecting altered intracellular metabolism or neural death in connected structures, and leading to constrained memory performance (Bartzokis, 2004; Metzler-Baddeley et al., 2019). Due to the cross-sectional design of our study that still limits conclusions about causality; future longitudinal studies are needed to support this hypothesis.

Strengths of the study include the multimodal imaging approach of combined gray matter volumetric analysis and white matter fiber tractography to assess the impact of structural integrity that promotes successful cognitive function in older adults. A robust tractography method was used. CSD overcomes the limitations of other DTI techniques, estimating the orientation of multiple intravoxel fiber populations in regions of white matter structures with crossing fibers like the fornix (Tournier et al., 2008; Jeurissen et al., 2011). The present study presents two methodological limitations; first, partial volume effects (PVE) affect DTI-based indices (Alexander et al., 2001; Szczepankiewicz et al., 2013). An individual voxel in brain imaging may contain different types of tissues; gray matter, white matter and cerebrospinal fluid. PVE refers to the impact that tissues, other than white matter, may have on tractography analysis, leading to underestimated FA values within a voxel [for review (Tohka, 2014)]. In order to attenuate PVE, we set the FA threshold to 0.2, as a mean to eliminate all underestimated FA values. Second, concerns about the hippocampal subfield segmentation tool implemented in FreeSurfer were recently expressed when applied on T1-weighted images with standard spatial resolution (Pluta et al., 2012; Wisse et al., 2014; de Flores et al., 2015; Yushkevich et al., 2015). Using the automated segmentation on images with 1 mm-resolution may result in less accurate delineation of boundaries within subfields. It is thus recommended to acquire T2 images to improve automated subfield segmentation (Iglesias et al., 2015). Therefore, volumetric results from hippocampal subregions must be interpreted with caution. Nevertheless, we are confident that the automated segmentation in FreeSurfer provides highly useful information, allows for reproducible and – compared to manual segmentation – less labor intensive and less biased results (Iglesias et al., 2015; Foo et al., 2017; Li et al., 2018; Zheng et al., 2018); and that individual subfields in our study were produced in the right position.