From histology to macroscale function in the human amygdala

Hans Auer; Donna Gift Cabalo; Raul Rodriguez-Cruces; Oualid Benkarim; Casey Paquola; Jordan DeKraker; Yezhou Wang; Sofie Valk; Boris C Bernhardt; Jessica Royer

doi:10.7554/eLife.101950.1

eLife Assessment

This valuable contribution combines high-resolution histology with magnetic resonance imaging in a novel way to study the organisation of the human amygdala. The main findings convincingly show the axes of microstructural organisation within the amygdala and how they map onto the functional organisation. Overall, the approach taken in this paper showcases the utility of combining multiple modalities at different spatial scales to help understand brain organisation.

https://doi.org/10.7554/eLife.101950.1.sa2

Significance of findings

valuable: Findings that have theoretical or practical implications for a subfield

landmark
fundamental
important
valuable
useful

Strength of evidence

convincing: Appropriate and validated methodology in line with current state-of-the-art

exceptional
compelling
convincing
solid
incomplete
inadequate

During the peer-review process the editor and reviewers write an eLife assessment that summarises the significance of the findings reported in the article (on a scale ranging from landmark to useful) and the strength of the evidence (on a scale ranging from exceptional to inadequate). Learn more about eLife assessments

Abstract

The amygdala is a subcortical region in the mesiotemporal lobe that plays a key role in emotional and sensory functions. Conventional neuroimaging experiments treat this structure as a single, uniform entity, but there is ample histological evidence for subregional heterogeneity in microstructure and function. The current study characterized subregional structure-function coupling in the human amygdala, integrating post mortem histology and in vivo MRI at ultrahigh fields. Core to our work was a novel neuroinformatics approach that leveraged multiscale texture analysis as well as non-linear dimensionality reduction techniques to identify salient dimensions of microstructural variation in a 3D post mortem histological reconstruction of the human amygdala. We observed two axes of subregional variation in the human amygdala, describing inferior-superior as well as medio-lateral trends in microstructural differentiation that in part recapitulated established atlases of amygdala subnuclei. We then translated our approach to in vivo MRI data acquired at 7 Tesla, and could demonstrate generalizability of these spatial trends across 10 healthy adults. We then cross-referenced microstructural axes with functional blood-oxygen-level dependent (BOLD) signal analysis obtained during task-free conditions, and demonstrated a close association of structural axes with macroscale functional network embedding, notably the temporo-limbic, default mode, and sensory-motor networks. Our novel multiscale approach consolidates descriptions of amygdala anatomy and function obtained from histological and in vivo imaging techniques.

Introduction

The amygdala is a central hub for socio-affective and cognitive functioning (1–3). Over the past decades, lesion studies in animals and humans have been crucial in our understanding of this structure’s functional role. Studies performed in animal models have reported significant deficits in a vast array of social and affective functions following amygdala lesions, including affective blunting, perturbed social interest and affiliation behaviors, increased aggression, altered sexual and maternal behaviors as well as fear response to environmental stimuli (4–6). In addition to altering social behavior, lesions of this structure in humans have been associated with impaired decision making (7) and deficits in attention and arousal mechanisms (8), emphasizing the importance of the amygdala in a broad array of functional domains.

Although earlier work on amygdala function in humans has considered this region as a single, unitary structure, the distinct roles of its individual subdivisions are now increasingly highlighted (9–11). Indeed, qualitative examinations of post mortem specimens have identified several subdivisions within the amygdala, each with distinct cytoarchitectural characteristics and distinguishable connectivity profiles (12). These individual subnuclei have often been grouped into larger subdivisions, specifically centromedian, laterobasal and superficial regions (13). Distinguishable connectivity profiles in these subdivisions have been previously observed through the analysis of resting-state functional magnetic resonance imaging (rsfMRI) (10,14). This non-invasive technique has been instrumental to interrogate grey matter (GM) connectivity and map functional networks in the brain by detecting coordinated hemodynamic signal fluctuations across regions (15–20). For instance, previous work has shown synchronized functional signals between the centromedial (CM) subdivision of the amygdala and middle and anterior cingulate cortices, frontal cortex, striatum, insula, cerebellum and precuneus, supporting processes such as attention control and visceral responses (21–23). Conversely, the laterobasal (LB) region shows unique connectivity with the inferior and middle temporal gyri and middle occipital gyrus which have been associated with associative processing of environmental information and the integration with self-relevant cognition for decision making (21,24–26). The superficial (SF) subdivision of the amygdala has rather been associated with social information processing and social interaction via its unique connectivity to the paracentral lobule, posterior cingulate cortex, and orbitofrontal cortex (14,27–30). Given these differences across amygdala subregions, combining structural and functional analyses can shed light on the multi-faceted contribution of the amygdala to affective and cognitive functioning by potentially revealing variable participation of its subdivisions in different functional networks.

Our current understanding of the amygdala highlights its multidimensional roles, supported by its complex anatomy and participation in multiple brain networks. However, microstructural atlases of this area developed using quantitative techniques are still lacking but are essential for large-scale investigations of structure-function coupling within this region. Emerging strategies for quantitative segmentations of amygdala subdivisions have shown promising results. For example, a dual-branch convolutional network model trained with features extracted from T1-weighted images could find strong overlap between automatically segmented labels and a manual segmentation of lateral, basal, cortico-superficial and centromedial subregions (31). Similarly, a machine learning-based correction model could achieve comparable accuracy using a multi-atlas segmentation model (32). Despite the promise of these methods, they remain to be validated in histology (33), which remains a key technique to validate MRI-based features with access to ground-truth measures of cytoarchitecture (34–36). Indeed, regions with different cytoarchitecture often show distinct myelination patterns, which can be observed through various MRI contrasts. Such myelin-sensitive imaging contrasts can differentiate regions with distinct intracortical myeloarchitectonic profiles, demonstrating ties between variations in cellular architecture and myelin distribution (37,38).

Our study seeks to elucidate the intricate structure-function relationships within the amygdala by leveraging advanced data-driven quantitative methods and high-resolution histology. Our approach first leveraged computer vision techniques to map major subdivisions of the amygdala in BigBrain (39), a post mortem, high-resolution 3D histological dataset providing direct measurements of brain cytoarchitecture. We translated this approach to in vivo MRI data acquired at ultra-high fields enabling individual-specific assessments of microstructure-function coupling in the amygdala. Harnessing myelin-sensitive contrasts and multi-echo rsfMRI, our study identifies a principal axis of microstructural and functional network dissociation within the human amygdala from a data-driven analysis of its cyto- and myeloarchitecture.

Results

Data-driven histological analysis of the human amygdala

Using a radiomics approach (40,41), we computed the four central moments (mean, variance, skewness, and kurtosis) from cell body staining intensities in the amygdala provided by the BigBrain dataset (39,42,43), Figure 1A). These voxel-wise metrics were computed across different kernel sizes, with local 3-dimensional neighborhoods ranging from a radius of 2 to 10 voxels. As expected, increasing kernel values produced smoother images for all central moments. Thus fine-grain features were emphasized at small kernel values and coarser features with larger kernel values.

Data-driven histological mapping of the human amygdala.
**(A)** The amygdala was segmented from the 100-micron resolution BigBrain dataset using an existing subcortical parcellation (42). Leveraging the pyRadiomics package v3.0.1 (44), we built a multiscale histological feature bank of the amygdala capturing fine-to-coarse intensity variations within this structure. Feature values were all normalized to better visualize relative intensity differences. **(B)** Matrix representation of the normalized feature bank shown in A. We applied UMAP to this feature bank to derive a low dimensional embedding of amygdala cytoarchitecture, defining a 2-dimensional coordinate space (scatter plot, middle). Colors of the scatter plot represent proximity to axis limits. Reordering the feature bank according to each eigenvector (U1 and U2) highlighted the underlying variance in each feature captured by UMAP. **(C, Left)** Coloring each amygdala voxel according to its corresponding location in the UMAP embedding space partially recovered its anatomical organization. **(C, right)** U1 and U2 were correlated to the three spatial axes and a variogram matching test was done for each axis to assess the statistical significance of each correlation. **(D)** Coloring the embedding space with openly available probabilistic map labels of the three main amygdala subregions could recover the fully data-driven structure uncovered by UMAP. Ridge plots of the probability values per subregions also illustrate a characterization of the subregions in U1.

The resulting feature bank showed heterogeneous feature profiles across selected moments and kernel sizes (Figure 1A). Mean intensities smoothly increased in the ventral to dorsal direction, culminating in highest intensity values in the dorsal subnucleus regions, andà mainly coinciding with the CM subdivision of the amygdala. Variance, however, was highest along the amygdala’s borders with the entorhinal cortex and in the amygdala-striatum transition zone. Skewness and kurtosis maps generally co-varied spatially and both highlight high skewness and kurtosis within the lateral nucleus. Together, these findings indicate that the selected features captured both unique and shared characteristics of histological signal variations within the amygdala.

We then applied UMAP (45) to the resulting 20-feature matrix to derive a 2-dimensional embedding of amygdala cytoarchitecture (Figure 1B). This approach allowed us to bring the high dimensional histological feature space to a 2D embedding space composed of every amygdala voxel. As such, amygdala voxels were ordered along two dimensions, U1 and U2, capturing two axes of variance in amygdala cytoarchitecture. To better visualize which features may be driving each UMAP dimension, we sorted all input features along U1 and U2 (Figure 2B). Ordering the mean along U1 highlighted increasing intensity values at all different kernel sizes, where highest intensity voxels co-localized with low values in U1. While the variance, skewness and kurtosis showed less systematic changes at lower kernel values, patterns became more evident at higher kernels. Indeed, variance and kurtosis seemed to show an opposite trend to the mean along U1, where higher skewness and kurtosis co-localized more strongly with positive values of U1 (Supplementary Table S1.1). In contrast, sorting the feature matrix by U2 showed very similar trends between all features, independent of its moment and kernel value. More specifically, the highest intensity voxels were mostly found to show higher values along U2 (Supplementary Table S1.2). Overall, these UMAP-driven visualizations of the histological feature space suggest our dimensionality reduction approach could recover moment-specific (U1) as well as global intensity covariations across moments (U2).

Translating amygdala histological space to *in vivo*, ultra high-resolution, myelin-sensitive MRI.
**(A)** We segmented the left and right amygdalae of individual subjects from quantitative T1 (qT1) scans, and applied the same framework as developed in *post mortem* imaging to derive subject-specific, *in vivo* representations of amygdala microstructure. **(B)** Correlation values between the UMAP components (U1 and U2) and the three coordinate axes of the 10 MRI subjects were computed in MNI152 space and then contrasted with the correlatio values found in the histological data (BigBrain transformed to MNI152 space).

To contextualize variations in U1 and U2 values across the amygdala, we computed voxel-wise correlations between each UMAP component and the amygdala coordinate space. U1 primarily varied along the inferior-superior axis (U1: r = 0.8340; U2: r = −0.0137), followed by posterior-anterior (U1: r = −0.5282; U2: r = 0.2793) and medial-lateral directions (U1: r = 0.1399; U2: r = - 0.2657) (Figure 1C). Statistical significance of correlations was assessed using a variogram matching approach (46) implemented in the BrainSpace toolbox (47) (Figure 1C). Both UMAP components were found to significantly co-vary along the posterior-anterior axis (U1: p_null< 0.001; U2: p_null = 0.002), while only U1 was significantly correlated with the inferior-superior axis (U1: p_null < 0.001; U2: p_null = 0.909). Neither U1 or U2 were significantly correlated with the medial-lateral coordinate (U1: p_null= 0.441; U2: p_null = 0.068).

Validation of histological space using independent post mortem dataset

We contextualize our data-driven approach using established probability maps of amygdala microstructure. These openly available probability maps generated from visual inspection of 10 post mortem brains divide the amygdala into CM, SF, and LB subregions (36). Maps were thresholded to retain only voxels with highest 5% probability values and binarized. Plotting the probability values of retained voxels for each subregion showed that UMAP could dissociate these established cytoarchitectural subdivisions of the amygdala (Figure 1D). The three subregions could be particularly segregated along the U1 component. Indeed, we found significant differences in U1 values across the three amygdala subdivisions (F = 1630.8; p_null< 0.001), while no significant difference was found across U2 (F = 30.3; p_null < 0.581). Together, these findings show our theoretically grounded framework can successfully distinguish different subregions in the amygdala in a purely data-driven way. Additionally, results could be replicated when analyzing signals from the right amygdala, supporting the potential generalizability of our framework (Supplementary Figure S1)

In vivo generalizability of histological space

We also assess the generalizability of these results to in vivo myelin-sensitive MRI data. We leverage quantitative T1 imaging collected at a field strength of 7 Tesla (7T) in 10 unrelated, healthy participants (Figure 2A). These images offered a resolution of 500um and were run through a similar analytical framework as the BigBrain dataset. We used individual-specific segmentations of the amygdala obtained with VolBrain (48). Once again, a feature bank was rendered from the same central moments, specifically mean, variance, skewness, and kurtosis. Kernel sizes varied from size 1-5, resulting in 20 distinct feature maps (Figure 2A). The new feature bank was again submitted to UMAP for dimensionality reduction (Figure 2A), and values of each component were plotted back to their respective coordinates in the amygdala.

We then compared spatial variations of the two UMAP components uncovered in each participant with the UMAP space derived from the BigBrain dataset. When examining the spatial layout of the UMAP components of each subject, we find similar neuroanatomical trends in all subjects to those found in histological space (Figure 2B). Notably, the U1 vector of all subjects are found to be significantly correlated to the inferior-superior axis from a variogram matching test (Supplementary Table S2.1), similarly to BigBrain, suggesting the potential for this framework to capture important structural features in histology as well as in vivo MRI. We also find that the medial-lateral axis correlations to U1 across all subjects are consistent from the variogram test (Supplementary Table S2.1). The spatial layout of U2, on the other hand, showed lower consistency across participants, as none of the coordinate axes were significantly correlated with U2 in more than 7/10 subjects (Supplementary Table S2.2). In sum, we identify a single axis (U1) able to pick up on important amygdala microstructural features in both post mortem histology and in vivo markers of GM microstructure.

Association with macroscale function

We next sought to investigate associations between amygdala microstructural organization and this region’s macroscale functional organization across subjects. Given U1’s strong spatial consistency across participants and microstructural modalities, we generated subject-specific masks segregating this component’s highest and lowest 25% of values within the amygdala for each participant. This resulted in two distinct regions of interest, reflecting the anchors of maximal microstructural dissociation within the amygdala for each participant, from which we could extract corresponding functional activity recorded at rest (Figure 3A).

Functional network mapping of amygdala microstructural subregions.
**(A)** We isolated the rsfMRI timeseries of two amygdala subregions, defined from subject-specific U1 topography, as well as the whole amygdala. **(B)** We computed the functional connectivity of both amygdala subregions, and project resultin correlations to the cortex. We further demonstrate the differences in connectivity patterns between both subregions (t-value) and highlight the regions with significant differences (*pFWE*<0.05). **(C)** The activation patterns illustrate in (B, top) were averaged within intrinsic functional communities defined by Yeo, Krienan, et al. (2011) t highlight differences in connectivity of each amygdala subregion in each network. (C, right) Meta-analytic decoding of functional connectivity patterns of both amygdala subregions and the whole amygdala dissociated cognitive an affective functional affiliations of this region.

Voxel-wise rsfMRI timeseries were averaged within each microstructural subregion, and correlated to vertex-wise cortical timeseries. A linear mixed effect model comparing amygdalo-cortical connectivity profiles between both subregions showed that functional network affiliations significantly differed across U1 subregions, with stronger connectivity observed between the superior portions of the amygdala (top 25% U1 values) and the prefrontal lobe (Figure 3B). Stratifying functional connectivity patterns of each amygdala subregion to the cortex according to established intrinsic functional network communities further highlighted the relatively stronger connectivity of the superior subregions to all cortical networks, particularly the limbic, frontoparietal, and default mode networks (Figure 3C). Meta-analytical decoding of subregional connectivity profiles using NeuroSynth (49) emphasized the functional dissociation between both microstructurally-defined areas. This analysis showed that the functional connectivity pattern of the region with highest 25% U1 values were most strongly associated with terms relating to autobiographical memory (‘autobiographical’ and ‘autobiographical memory’), while the other seed region’s connectivity profile overlapped with activation patterns related to emotional input (‘happy faces’, ‘neutral faces’ and ‘fearful faces’) (Figure 3C). Furthermore, decoding our statistical effects map (Region 1 connectivity > Region 2 connectivity) highlighted associations with terms relating to the self, introspection, and reward (‘self referential’, ‘referential’, ‘moral’, ‘autobiographical’, ‘smoking’, ‘craving’). This shows our theoretically-grounded approach, developed in histology and generalizable to microstructurally-sensitive in vivo MRI data, can delineate distinct functional network embeddings in the human amygdala. The present work thus offers insights into an integrated account of this region’s microstructural composition and functional organization.

Discussion

The amygdala is a crucial structure for several aspects of cognitive and socio-affective functioning (3). These functions are supported by complex connectivity patterns to other brain regions, stemming from distinct subnuclei with unique microstructural properties (12). However, current investigations of structure-function coupling in the amygdala are limited by a lack of datasets and tools for individualized and observer-independent delineation of its subregions. Indeed, the strong inter-individual variability of its structural and functional organization (13,50) motivates more personalized approaches to reliably study the microstructural determinants of amygdala function and connectivity. In the current paper, we present a data-driven exploration of subcortical cytoarchitecture applied to the human amygdala. We could translate this approach to microstructurally-sensitive in vivo MRI data as a bridge, to ultimately examine associations between microstructural subregions and functional networks. As such, the present work defines a quantitative and integrated account of the amygdala’s microstructural composition and functional organization. In doing so, our approach sets the stage for novel investigations spanning other subcortico-cortical systems, and shows potential to deliver new insights into brain-wide principles of structure-function coupling and how this interplay may be altered in clinical populations.

The proposed framework aimed to delineate amygdala subnuclear organization by leveraging a multiscale texture processing pipeline designed to retain finer and coarser regional cytoarchitectonic properties. For this purpose, we specifically harness radiomics, a field with established diagnostic and prognostic potential in medical imaging(51). Feature selection in our study was motivated by previous work conducted at the level of the neocortex (33,40) and focused on the four central moments, specifically, the mean, variance, skewness, and kurtosis of voxel subsets, to reflect regional texture variability related to amygdala cytoarchitecture. In contrast to qualitative approaches based on single features, such as investigations based on the detection of specific cell types (52), our pipeline captures several aspects of amygdala microstructure informing non-linear dimensionality reduction methods applied to a high-dimensional feature space. The resulting components U1 and U2 reflected complex combinations of central moments, with U1 being mainly scaled to mean intensities and U2 being associated to weighted combinations of the different moments. Crucially, we validated this coordinate space using openly available maps of amygdalar subdivisions from histological examinations performed by expert neuroanatomists (36). This approach complements previous work harnessing subnuclear parcellations of the amygdala derived from visual inspections of post mortem specimens (12) and deep-learning algorithms applied to in vivo MRI data (31,53,54) to contextualize variations in functional connectivity profiles within this region. Indeed, a significant advantage of our framework lies in the ease with which it may be applied to new datasets. For instance, our method overcomes the time-consuming nature and high level of expertise required for precise manual subnuclear segmentations. Furthermore, this approach circumvents the need for large datasets required to validate deep learning-based applications, a particular concern in the case of histological data which are often limited to few or even single specimens. Overall, the proposed framework lays the groundwork for future investigations of subcortical structure-function coupling by anchoring connectivity and task-related activations within measurements of regional microarchitecture.

The present works described a continuous coordinate space of amygdala subregional microstructure. However, this region has been previously described as consisting of three main subdivisions: LB, CM, and SF, each composed of smaller subnuclei with distinct connectivity patterns and functions (9,10,13,55). We selected UMAP for its potential to recover this nuclear architecture via the identification of discrete clusters of microstructural similarity within the amygdala. While these dimensions partially align with traditional concepts of arealization, they also provide a complementary, graded representation of amygdala microarchitecture. Although our framework leverages ultra-high resolution histological and myelin-sensitive MRI, the inherent spatial autocorrelation of feature intensities in these modalities may have emphasized the continuous signal variations we identify within the amygdala and hindered the discovery of discrete boundaries between known subdivisions. We address this limitation by benchmarking U1 and U2 distributions against validated probabilistic maps of major amygdala subdivisions (13,36), enabling us to recover the established biological validity of its nuclear organization. Furthermore, this approach allowed us to derive discrete clusters of maximal microstructural differentiation within the amygdala; these clusters served as seed regions for microstructurally-grounded and individualized investigations of the functional connectome embedding of amygdala subregions. Specifically following an inferior-superior and medial-lateral axis of differentiation in both post mortem histology and myelin-sensitive in vivo MRI, this bipartite division is in line with previous work investigating the structural connectivity of the amygdala using diffusion-weighted imaging and probabilistic tractography (56) as well as functional connectivity from rsfMRI (57). Indeed, both modalities highlight the existence of two distinct clusters segregating amygdala connectivity to temporopolar and orbitofrontal cortices. These findings mirror macroscale associations seen in the neocortex between microstructure and connectivity, which notably emphasize close correspondence between the strength of interareal connectivity and microstructural similarity(58–60). In the case of the amygdala, our framework could thus recover these distinct anatomical pathways from a data-driven, texture-based analysis of microarchitectural information alone, supporting the potential of such contrasts to provide insights into the large-scale network embeddings of subcortical systems.

In line with this suggested association between amygdala microarchitecture and functional connectivity, we conclude our analyses by leveraging subject-specific representations of amygdala microstructure to map large-scale variations in its functional connectivity to the neocortex. By isolating and contrasting the highest and lowest 25% of U1 values for each participant to define an individualized bipartite parcellation of the amygdala, we observe significant dissociation in functional connectivity to prefrontal structures that support self-referential, reward-related, and socio-affective processes. We find that the highest 25% U1 value defined region overlaps with what is commonly defined as the superficial and centromedial subregions, whereas the lowest 25% U1 value region overlaps with what is commonly defined as the laterobasal subregion. Interestingly, CM and SF characterized subregions showed significantly stronger functional connectivity to prefrontal structures. This finding aligns with previous work demonstrating unique affiliations between the CM subregion and anterior cingulate and frontal cortices (22,23), as well as between the SF subregion and the orbitofrontal cortex (14,21,27,61). Functional decoding of the connectivity profiles of each microstructurally-defined subregion could further distinguish the cognitive (i.e., memory) and affective (i.e., emotional face processing) roles of the amygdala, building on previous accounts of amygdala function. Notably, our functional connectivity analysis linked a subregion co-localizing with LB to emotional face processing. This subregion has been previously linked to associative processing related to integrating information from internal and external environments (10,21,24–26), which is consistent with the tuning for visual emotional information identified in the present work. Overall, our findings suggest that this microstructurally-grounded delineation of U1 subregions could capture dissociations in their respective associations with fear-related processes. These results echo previous chemoarchitectural descriptions of the amygdala involving the 5-HT receptor, which has been closely associated with fear responses in mice and humans (28,62). Indeed, this receptor is expressed in lower densities in the CM region, overlapping with our U1 subregions that show lower connectivity to regions involved in fear-related responses. The present work thus offers an important step towards a more integrated account of the amygdala’s microstructural composition and functional organization.

By harnessing an openly available arsenal of tools and methods from histology, radiomics, and neuroinformatic, we define a comprehensive framework enhancing our understanding of individual differences in amygdala organization. Our findings contribute to a growing body of research emphasizing the importance of integrating structural and functional data to elucidate the complex roles of the amygdala in both health and disease. This multimodal, multiscale, and subject-specific approach not only advances our knowledge of the amygdala’s microstructural and functional intricacies but also offers a valuable resource for future studies exploring subcortical structures and their implications in various neurological and psychiatric conditions. This integrated perspective is essential for developing more precise and personalized interventions for disorders associated with amygdala dysfunction.

Methods

Histological data acquisition and pre-processing

Cell-body-staining intensity of the amygdala was obtained from the BigBrain dataset (39). BigBrain is an ultra-high–resolution Merker-stained 3D volumetric histological reconstruction of a post mortem human brain from a 65-year-old male, made available on the open-access BigBrain repository (bigbrain.loris.ca). The post mortem brain was paraffin-embedded, coronally sliced into 7,400 20-μm sections, silver-stained for cell bodies (9), and digitized. As such, image intensity values in this dataset provide direct measurements of brain cytoarchitecture. Following manual inspection for artifacts, automatic repair procedures were applied, involving nonlinear alignment to a post mortem MRI, intensity normalization, and block averaging (63). 3D reconstruction was implemented with a successive coarse-to-fine hierarchical procedure. All main analyses were performed using the 100μm isovoxel resolution dataset.

Amygdala segmentation and subdivision mapping

The left and right amygdalae were isolated from the BigBrain volume using an existing manual segmentation of left and right subcortical structures (42). This segmentation was warped to BigBrain histological space from a standard template space (ICBM2009b symmetric (64)) using openly available co-registration strategies aggregated in the BigBrainWarp toolbox (42,43). Notably, these approaches were optimized to improve the alignment of subcortical structures (42). After registering the subcortical atlas to histological space and resampling the segmentation to an isovoxel resolution of 100μm, we generated unique binary masks isolating the left and right amygdalae and performed manual corrections on each mask (i.e., improving smoothness and continuity of the mask borders), and eroded the mask by five voxels to provide a conservative estimate of regional borders. All main analyses were performed on left hemisphere data only, while the right hemisphere served as a validation dataset (Supplementary Figure S1).

To contextualize our data-driven histological mapping of the amygdala (see below), we leveraged openly available probabilistic maps of amygdala subnuclei derived from visual inspections of post mortem tissue specimens performed by expert neuroanatomists (12,36). The borders of amygdala subdivisions were traced in 10 post mortem brains. Following 3D reconstruction and alignment of each post mortem brain to a common template space, voxel-wise probabilistic maps for each subregion were computed by quantifying the consistency of label assignments across the 10 donor brains. For the present work, all available probabilistic maps of the amygdala, including large subdivision groups encompassing multiple amygdala subnuclei (i.e., CM, LB, and SF subdivisions) were accessed from the EBrains repository (v8.2) (36). Regional probabilistic maps were warped from ICBM2009c asymmetric space to the ICBM2009b symmetric template using the SyN algorithm implemented in the Advanced Normalization Tools software (ANTs) (65). Each subregional probabilistic map was subsequently warped to BigBrain histological space (42,43) and was resampled to an isovoxel resolution of 100μm. We then generated a maximum probability map to parcellate the amygdala into its subdivisions by retaining the voxels with the highest 5% probability values of belonging to each subdivision.

Histological feature extraction

We built a histological feature bank of amygdala cell-body-staining using methods from the field of radiomics (66). Our approach for feature selection was also inspired by quantitative cytoarchitectural analyses developed in foundational neuroanatomical studies (40), involving the parameterization of intensity profiles with four central moments to characterize regional cytoarchitecture across the neocortex. In the present work, we computed these same four central moments (i.e., mean, variance, skewness, and kurtosis) of cell body staining intensities in the amygdala to characterize intensity differences across this region. We used pyRadiomics v3.0.1 (44) to compute voxel-based maps for each of the selected first-order features, varying the size of 3D-feature extraction to a voxel neighbourhood of 500μm to 2100μm (in 400μm increments). Outlier values (> 1 standard deviation from the mean intensity value) were excluded from moment calculations at each kernel size. This resulted in 20 distinct feature maps, capturing variations in intensity distributions within the amygdala at finer and coarser scales. These feature maps were normalized by z-scoring each feature at each kernel size.

Dimensionality reduction of histological features

To capture and visualize the underlying structure of amygdala cytoarchitecture, we applied Uniform Manifold Approximation and Projection (UMAP), a non-linear dimensionality reduction technique, to our normalized histological feature bank (45). This algorithm was selected over other compression approaches for its scalability in the analysis of large datasets, as well as its ability to preserve both local and global data structure (67). Two UMAP hyperparameters controlling the size of the local neighbourhood as well as the local density of data points were kept at their default settings (n_neighbours=15, dist_min=0.1). The resulting low-dimensional embedding of higher-order histological features was contextualized in relation to the amygdala’s x, y, and z voxel coordinate space, and validated against previously described maximum probability map of the amygdala.

In vivo MRI data acquisition

After establishing this framework with post mortem histological data, we assessed its generalizability to in vivo, myelin-sensitive MRI contrasts. We capitalized on quantitative T1 (qT1) relaxometry data collected in 10 participants at a field strength of 7 Tesla. This sequence has been shown to be sensitive to cortical myeloarchitecture (68–70), and could thus offer complementary insights into the microstructural organization of the amygdala. Our cohort of 10 adult participants (5 men, mean ± SD age = 27.3 ± 5.71 years) were all healthy, with no history of neurological or psychiatric conditions (71).

Scans were acquired at the McConnell Brain Imaging Centre (BIC) of the Montreal Neurological Institute and Hospital on a 7T Terra Siemens Magnetom scanner equipped with a 32-receive and 8-transmit channel head coil. Synthetic T1-weighted (UNI) and quantitative T1 relaxometry (qT1) data were acquired using a 3D-MP2RAGE sequence (0.5 mm isovoxels, 320 sagittal slices, TR=5170 ms, TE=2.44 ms, TI1=1000 ms, TI2=3200 ms, flip angle₁=4°, iPAT=3, partial Fourier=6/8 flip angle₂=4°, FOV=260×260 mm²). We combined two inversion images to minimize sensitivity to B1 inhomogeneities and optimize reliability (72,73). rsfMRI scans were acquired using a multi-echo, 2D echo-planar imaging sequence (1.9mm isovoxels, 75 slices oriented to AT-PC-31 degrees, TR=1690 ms, TE1=10.8 ms, TE2=27.3 ms, TE3=43.8 ms, flip angle=67°, multiband factor=3). The rsfMRI scan lasted ∼6 minutes, and participants were instructed to fixate a cross displayed in the center of the screen, to clear their mind, and not fall asleep.

Multimodal MRI processing and analysis

a) Anatomical segmentation and co-registration. Image processing leading to the extraction of cortical and subcortical features and their registration to surface templates was performed via micapipe v0.2.3, an open multimodal MRI processing and data fusion pipeline (github.com/MICA-MNI/micapipe/) (74). The amygdala was automatically segmented on the T1w images with volBrain v3, in every subject. Cortical surface models were generated from MP2RAGE-derived UNI images using FastSurfer 2.0.0 (48). Surface extractions were inspected and corrected for segmentation errors via placement of manual edits. Native-surface space cortical features were registered to the fs-LR template surface using workbench tools (75).
b) qT1 image processing and analysis. Automated, individual-specific segmentations of the amygdala were obtained with VolBrain, and were manually inspected and corrected prior to image processing. In a similar fashion to the histological data, a feature bank was rendered from the same central moments, although kernel sizes varied from size 1-5, rather than 2-10 in order to take into account the difference in image resolution between the two datasets. Thus, voxel neighborhoods ranged from 1500μm to 5500μm (in 1000μm increments). This resulted in 20 distinct feature maps, capturing variations in intensity distributions within the amygdala at finer and coarser scales. The new feature bank was again submitted to UMAP for dimensionality reduction, independently for all 10 participants. This procedure generated a 2-dimensional feature space unique to each participant recapitulating the organization of the amygdala. We then plotted the values generated in our UMAP space onto their original coordinate points inside the amygdala in the original qT1 space of each subject for further visualization and analysis.

To finally compare subject-specific in vivo MRI findings to our previously defined histological components, we first co-registered each subject’s qT1 scan to the ICBM152 template and applied the resulting transform to each participant’s U1 map. We applied existing transformations to bring the histological-space U1 to the same template space (42,43). This allowed us to contrast the UMAP components of all 10 subjects and BigBrain, along x, y, and z coordinate axes.c) rsfMRI image processing and analysis. Processing employed micapipe v.0.2.3 (74), which combines functions from AFNI (76), FastSurfer (77–79), workbench command (80), and FSL (81). Images were reoriented, as well as motion and distortion corrected. Motion correction was performed by registering each timepoint volume to the mean volume across timepoints, while distortion correction utilized main phase and reverse phase encoded field maps. Leveraging our multi-echo acquisition protocol, nuisance variable signals were removed with tedana (82). Volumetric timeseries were averaged for registration to native FastSurfer space using boundary-based registration (83), and mapped to individual surfaces using trilinear interpolation. Cortical timeseries were mapped to the hemisphere-matched fs-LR template using workbench tools then spatially smoothed with a 10mm Gaussian kernel. Surface- and template-mapped cortical timeseries were corrected for motion spikes using linear regression of motion outliers provided by FSL. Functional and anatomical spaces were co-registered using label-based affine registration (84) and the SyN algorithm available in ANTs (85).

Functional network mapping of amygdala microstructural subregions

We averaged the rsfMRI timeseries within amygdala subregions defined by the highest and lowest 25% of values in each participant’s own qT1-derived U1 component. Functional connectivity of each amygdala subregion to the rest of the cortex was determined using Pearson correlation between the timeseries of each amygdala subregion and each cortical vertex. Resulting correlation coefficients underwent Fisher R-to-Z transformation to increase the normality of the distribution of functional connectivity values.

A mixed effects model implemented with the BrainStat toolbox (86) assessed differences between the cortical connectivity profiles of each U1 subregion, while considering age and sex and fixed effects and subject identity as a random effect. We corrected findings for family-wise errors (FWE) using random field theory (p_FWE < 0.05; cluster-defining threshold (CDT) = 0.01). We further contextualized differences in each connectivity map using decoding functions from NeuroSynth (49) that are made available via BrainStat (86), by contrasting the overall connectivity profile of the amygdala to those of each of its microstructurally-defined subregions. First, we divided subregional amygdala-cortical connectivity profiles into seven established functional network communities (16) and contrasted their average connectivity strength across each network. Meta-analytic functional decoding of the connectivity patterns of both amygdala subregions and the whole amygdala also highlighted different cognitive affiliations of each seed. Spatial correlations between the amygdala’s cortical connectivity profile and spatial activation maps associated with each term allowed us to retain ten terms associated with different cognitive domains. We then compared the association between the activation patterns associated with each of the retained terms and the cortical connectivity profiles of each amygdala U1 subregion.

Data and code availability

Analysis notebooks related to this project are available on GitHub (github.com/MICA-MNI/micaopen/AmygdalaUMAP). BigBrain data are available on (osf.io/xkqb3/), 7T data are available on the Open Science Framework (osf.io/mhq3f/).

Acknowledgements

H.A. acknowledges funding from the Fonds de la Recherche du Québec – Nature et Technologie (FRQNT) Master’s Training Scholarship. D.G.C. acknowledges support from FRQ-Sante and Savoy Foundation. J.R. acknowledges support from CIHR. B.C.B. acknowledges support from NSERC, CIHR, SickKids Foundation, BrainCanada, Future Leaders Research Grant, Helmholtz International BigBrain Analytics and Learning Laboratory (HIBALL), FRQS, and the Canada Research Chairs program.

References

1.
1. LeDoux J
2003The emotional brain, fear, and the amygdalaCell Mol Neurobiol 23:727–38
2.
1. Adolphs R
1999The Human Amygdala and EmotionNeuroscientist 5:125–37
3.
1. Pessoa L
2. Adolphs R
2010Emotion processing and the amygdala: from a “low road” to “many roads” of evaluating biological significanceNat Rev Neurosci 11:773–83
4.
1. Gothard KM
2020Multidimensional processing in the amygdalaNat Rev Neurosci 21:565–75
5.
1. Dal Monte O
2. Costa VD
3. Noble PL
4. Murray EA
5. Averbeck BB
2015Amygdala lesions in rhesus macaques decrease attention to threatNat Commun 6
6.
1. Kazama AM
2. Heuer E
3. Davis M
4. Bachevalier J
2012Effects of neonatal amygdala lesions on fear learning, conditioned inhibition, and extinction in adult macaquesBehav Neurosci 126:392–403
7.
1. Hampton AN
2. Adolphs R
3. Tyszka MJ
4. O’Doherty JP
2007Contributions of the amygdala to reward expectancy and choice signals in human prefrontal cortexNeuron 55:545–55
8.
1. Sarter M
2. Bruno JP
2000Cortical cholinergic inputs mediating arousal, attentional processing and dreaming: differential afferent regulation of the basal forebrain by telencephalic and brainstem afferentsNeuroscience 95:933–52
9.
1. Ball T
2. Rahm B
3. Eickhoff SB
4. Schulze-Bonhage A
5. Speck O
6. Mutschler I
2007Response properties of human amygdala subregions: evidence based on functional MRI combined with probabilistic anatomical mapsPLoS One 2
10.
1. Bzdok D
2. Laird AR
3. Zilles K
4. Fox PT
5. Eickhoff SB
2013An investigation of the structural, connectional, and functional subspecialization in the human amygdalaHum Brain Mapp 34:3247–66
11.
1. Gamer M
2. Zurowski B
3. Büchel C
2010Different amygdala subregions mediate valence-related and attentional effects of oxytocin in humansProc Natl Acad Sci U S A 107:9400–5
12.
1. Kedo O
2. Zilles K
3. Palomero-Gallagher N
4. Schleicher A
5. Mohlberg H
6. Bludau S
7. et al.
2018Receptor-driven, multimodal mapping of the human amygdalaBrain Struct Funct 223:1637–66
13.
1. Amunts K
2. Kedo O
3. Kindler M
4. Pieperhoff P
5. Mohlberg H
6. Shah NJ
7. et al.
2005Cytoarchitectonic mapping of the human amygdala, hippocampal region and entorhinal cortex: intersubject variability and probability mapsAnat Embryol 210:343–52
14.
1. Caparelli EC
2. Ross TJ
3. Gu H
4. Liang X
5. Stein EA
6. Yang Y
2017Graph theory reveals amygdala modules consistent with its anatomical subdivisionsSci Rep 7
15.
1. Greicius MD
2. Supekar K
3. Menon V
4. Dougherty RF
2009Resting-state functional connectivity reflects structural connectivity in the default mode networkCereb Cortex 19:72–8
16.
1. Yeo BTT
2. Krienen FM
3. Sepulcre J
4. Sabuncu MR
5. Lashkari D
6. Hollinshead M
7. et al.
2011The organization of the human cerebral cortex estimated by intrinsic functional connectivityJ Neurophysiol 106:1125–65
17.
1. Biswal B
2. Zerrin Yetkin F
3. Haughton VM
4. Hyde JS
1995Functional connectivity in the motor cortex of resting human brain using echo-planar mriMagn Reson Med 34:537–41
18.
1. Smith SM
2. Fox PT
3. Miller KL
4. Glahn DC
5. Fox PM
6. Mackay CE
7. et al.
2009Correspondence of the brain’s functional architecture during activation and restProceedings of the National Academy of Sciences 106:13040–5
19.
1. Biswal BB
2. Mennes M
3. Zuo XN
4. Gohel S
5. Kelly C
6. Smith SM
7. et al.
2010Toward discovery science of human brain functionProc Natl Acad Sci U S A 107:4734–9
20.
1. Raichle ME
2011The restless brainBrain Connect 1:3–12
21.
1. Pessoa L
2010Emotion and cognition and the amygdala: From “what is it?” to “what’s to be done?” Neuropsychologia 48:3416–29
22.
1. Barbour T
2. Murphy E
3. Pruitt P
4. Eickhoff SB
5. Keshavan MS
6. Rajan U
7. et al.
2010Reduced intra-amygdala activity to positively valenced faces in adolescent schizophrenia offspringSchizophr Res 123:126–36
23.
1. Kapp BS
2. Jr Supple WF
3. Whalen PJ
1994Effects of electrical stimulation of the amygdaloid central nucleus on neocortical arousal in the rabbitBehav Neurosci 108:81–93
24.
1. Winstanley CA
2. Theobald DEH
3. Cardinal RN
4. Robbins TW
2004Contrasting roles of basolateral amygdala and orbitofrontal cortex in impulsive choiceJ Neurosci 24:4718–22
25.
1. Ghods-Sharifi S
2. St Onge JR
3. Floresco SB
2009Fundamental contribution by the basolateral amygdala to different forms of decision makingJ Neurosci 29:5251–9
26.
1. Boyer P
2008Evolutionary economics of mental time travel?Trends Cogn Sci 12:219–24
27.
1. Goossens L
2. Kukolja J
3. Onur OA
4. Fink GR
5. Maier W
6. Griez E
7. et al.
2009Selective processing of social stimuli in the superficial amygdalaHum Brain Mapp 30:3332–8
28.
1. Hurlemann R
2. Schlaepfer TE
3. Matusch A
4. Reich H
5. Shah NJ
6. Zilles K
7. et al.
2009Reduced 5-HT2A receptor signaling following selective bilateral amygdala damageSoc Cogn Affect Neurosci 4:79–84
29.
1. Carr L
2. Iacoboni M
3. Dubeau MC
4. Mazziotta JC
5. Lenzi GL
2003Neural mechanisms of empathy in humans: a relay from neural systems for imitation to limbic areasProc Natl Acad Sci U S A 100:5497–502
30.
1. Wicker B
2. Keysers C
3. Plailly J
4. Royet JP
5. Gallese V
6. Rizzolatti G
2003Both of us disgusted in My insula: the common neural basis of seeing and feeling disgustNeuron 40:655–64
31.
1. Liu Y
2. Nacewicz BM
3. Zhao G
4. Adluru N
5. Kirk GR
6. Ferrazzano PA
7. et al.
2020A 3D Fully Convolutional Neural Network With Top-Down Attention-Guided Refinement for Accurate and Robust Automatic Segmentation of Amygdala and Its SubnucleiFront Neurosci 14
32.
1. Hanson JL
2. Suh JW
3. Nacewicz BM
4. Sutterer MJ
5. Cayo AA
6. Stodola DE
7. et al.
2012Robust Automated Amygdala Segmentation via Multi-Atlas Diffeomorphic RegistrationFront Neurosci 6
33.
1. Amunts K
2. Zilles K
2015Architectonic Mapping of the Human Brain beyond BrodmannNeuron 88:1086–107
34.
1. Yang S
2. Yang Z
3. Fischer K
4. Zhong K
5. Stadler J
6. Godenschweger F
7. et al.
2013Integration of ultra-high field MRI and histology for connectome based research of brain disordersFront Neuroanat 7
35.
1. Alkemade A
2. Großmann R
3. Bazin PL
4. Forstmann BU
2023Mixed methodology in human brain research: integrating MRI and histologyBrain Struct Funct 228:1399–410
36.
1. Amunts K
2. Mohlberg H
3. Bludau S
4. Zilles K
2020Julich-Brain: A 3D probabilistic atlas of the human brain’s cytoarchitectureScience 369:988–92
37.
1. Ganzetti M
2. Wenderoth N
3. Mantini D
2014Whole brain myelin mapping using T1- and T2-weighted MR imaging dataFront Hum Neurosci 8
38.
1. Baxi M
2. Cetin-Karayumak S
3. Papadimitriou G
4. Makris N
5. van der Kouwe A
6. Jenkins B
7. et al.
2022Investigating the contribution of cytoarchitecture to diffusion MRI measures in gray matter using histologyFront Neuroimaging 1
39.
1. Amunts K
2. Lepage C
3. Borgeat L
4. Mohlberg H
5. Dickscheid T
6. Rousseau MÉ
7. et al.
2013BigBrain: an ultrahigh-resolution 3D human brain modelScience 340:1472–5
40.
1. Schleicher A
2. Amunts K
3. Geyer S
4. Morosan P
5. Zilles K
1999Observer-independent method for microstructural parcellation of cerebral cortex: A quantitative approach to cytoarchitectonicsNeuroimage 9:165–77
41.
1. Palomero-Gallagher N
2. Zilles K
2018Cyto- and receptor architectonic mapping of the human brainHandb Clin Neurol 150:355–87
42.
1. Xiao Y
2. Lau JC
3. Anderson T
4. DeKraker J
5. Collins DL
6. Peters T
7. et al.
2019An accurate registration of the BigBrain dataset with the MNI PD25 and ICBM152 atlasesSci Data 6
43.
1. Paquola C
2. Royer J
3. Lewis LB
4. Lepage C
5. Glatard T
6. Wagstyl K
7. et al.
2021The BigBrainWarp toolbox for integration of BigBrain 3D histology with multimodal neuroimagingElife 10https://doi.org/10.7554/eLife.70119
44.
1. van Griethuysen JJM
2. Fedorov A
3. Parmar C
4. Hosny A
5. Aucoin N
6. Narayan V
7. et al.
2017Computational Radiomics System to Decode the Radiographic PhenotypeCancer Res 77:e104–7
45.
1. Becht E
2. McInnes L
3. Healy J
4. Dutertre CA
5. Kwok IWH
6. Ng LG
7. et al.
2018Dimensionality reduction for visualizing single-cell data using UMAPNat Biotechnol https://doi.org/10.1038/nbt.4314
46.
1. Burt JB
2. Helmer M
3. Shinn M
4. Anticevic A
5. Murray JD
2020Generative modeling of brain maps with spatial autocorrelationNeuroimage 220
47.
1. Vos de Wael R
2. Benkarim O
3. Paquola C
4. Lariviere S
5. Royer J
6. Tavakol S
7. et al.
2020BrainSpace: a toolbox for the analysis of macroscale gradients in neuroimaging and connectomics datasetsCommun Biol 3
48.
1. Manjón JV
2. Coupé P
2016volBrain: An Online MRI Brain Volumetry SystemFront Neuroinform 10
49.
1. Yarkoni T
2. Poldrack RA
3. Nichols TE
4. Van Essen DC
5. Wager TD
2011Large-scale automated synthesis of human functional neuroimaging dataNat Methods 8:665–70
50.
1. Sylvester CM
2. Yu Q
3. Srivastava AB
4. Marek S
5. Zheng A
6. Alexopoulos D
7. et al.
2020Individual-specific functional connectivity of the amygdala: A substrate for precision psychiatryProc Natl Acad Sci U S A 117:3808–18
51.
1. Limkin EJ
2. Sun R
3. Dercle L
4. Zacharaki EI
5. Robert C
6. Reuzé S
7. et al.
2017Promises and challenges for the implementation of computational medical imaging (radiomics) in oncologyAnn Oncol 28:1191–206
52.
1. Bonin G
1961Pattern of the Cerebral IsocortexKarger Medical and Scientific Publishers 56
53.
1. Liu Y
2. Zhao G
3. Nacewicz BM
4. Adluru N
5. Kirk GR
6. Ferrazzano PA
7. et al.
2019Accurate Automatic Segmentation of Amygdala Subnuclei and Modeling of Uncertainty via Bayesian Fully Convolutional Neural NetworkarXiv
54.
1. Saygin ZM
2. Kliemann D
3. Iglesias JE
4. van der Kouwe AJW
5. Boyd E
6. Reuter M
7. et al.
2017High-resolution magnetic resonance imaging reveals nuclei of the human amygdala: manual segmentation to automatic atlasNeuroimage 155:370–82
55.
1. de Olmos JS
2. Heimer L
1999The concepts of the ventral striatopallidal system and extended amygdalaAnn N Y Acad Sci 877:1–32
56.
1. Bach DR
2. Behrens TE
3. Garrido L
4. Weiskopf N
5. Dolan RJ
2011Deep and superficial amygdala nuclei projections revealed in vivo by probabilistic tractographyJ Neurosci 31:618–23
57.
1. Mishra A
2. Rogers BP
3. Chen LM
4. Gore JC
2014Functional connectivity-based parcellation of amygdala using self-organized mapping: A data driven approachHum Brain Mapp 35:1247–60
58.
1. Barbas H
2015General cortical and special prefrontal connections: principles from structure to functionAnnu Rev Neurosci 38:269–89
59.
1. García-Cabezas MÁ
2. Zikopoulos B
3. Barbas H
2019The Structural Model: a theory linking connections, plasticity, pathology, development and evolution of the cerebral cortexBrain Struct Funct 224:985–1008
60.
1. Barbas H
1986Pattern in the laminar origin of corticocortical connectionsJ Comp Neurol 252:415–22
61.
1. Klein-Flügge MC
2. Jensen DEA
3. Takagi Y
4. Priestley L
5. Verhagen L
6. Smith SM
7. et al.
2022Relationship between nuclei-specific amygdala connectivity and mental health dimensions in humansNat Hum Behav 6:1705–22
62.
1. Ramboz S
2. Oosting R
3. Amara DA
4. Kung HF
5. Blier P
6. Mendelsohn M
7. et al.
1998Serotonin receptor 1A knockout: an animal model of anxiety-related disorderProc Natl Acad Sci U S A 95:14476–81
63.
1. Paquola C
2. De Wael R Vos
3. Wagstyl K
4. Bethlehem RAI
5. Hong SJ
6. Seidlitz J
7. et al.
2019Microstructural and functional gradients are increasingly dissociated in transmodal corticesPLoS Biol 17
64.
1. Fonov V
2. Evans AC
3. Botteron K
4. Almli CR
5. McKinstry RC
6. Collins DL
7. et al.
2011Unbiased average age-appropriate atlases for pediatric studiesNeuroimage 54:313–27
65.
1. Avants BB
2. Epstein CL
3. Grossman M
4. Gee JC
2008Symmetric diffeomorphic image registration with cross-correlation: evaluating automated labeling of elderly and neurodegenerative brainMed Image Anal 12:26–41
66.
1. Zhou M
2. Scott J
3. Chaudhury B
4. Hall L
5. Goldgof D
6. Yeom KW
7. et al.
2018Radiomics in Brain Tumor: Image Assessment, Quantitative Feature Descriptors, and Machine-Learning ApproachesAJNR Am J Neuroradiol 39:208–16
67.
1. Kobak D
2. Linderman GC
2021Initialization is critical for preserving global data structure in both t-SNE and UMAPNat Biotechnol 39:156–7
68.
1. Lutti A
2. Dick F
3. Sereno MI
4. Weiskopf N
2014Using high-resolution quantitative mapping of R1 as an index of cortical myelinationNeuroimage 93:176–88
69.
1. Stüber C
2. Morawski M
3. Schäfer A
4. et al.
2014Myelin and iron concentration in the human brain: A quantitative study of MRI contrastNeuroimage 93:95–106
70.
1. Waehnert MD
2. Dinse J
3. Schäfer A
4. et al.
2016A subject-specific framework for in vivo myeloarchitectonic analysis using high resolution quantitative MRINeuroimage 125:94–107
71.
1. Cabalo DG
2. Rodriguez-Cruces R
3. Bernhardt BC.
2024MICA-PNC: Precision NeuroImaging and Connectomics [Internet]Center For Open Science
72.
1. Haast RAM
2. Ivanov D
3. Formisano E
4. Uluda K
2016Reproducibility and Reliability of Quantitative and Weighted T and T Mapping for Myelin-Based Cortical Parcellation at 7 TeslaFront Neuroanat 10
73.
1. Marques JP
2. Kober T
3. Krueger G
4. van der Zwaag W
5. Van de Moortele PF
6. Gruetter R
2010MP2RAGE, a self bias-field corrected sequence for improved segmentation and T1-mapping at high fieldNeuroimage 49:1271–81
74.
1. Cruces RR
2. Royer J
3. Herholz P
4. Larivière S
5. de Wael R Vos
6. Paquola C
7. et al.
2022Micapipe: A pipeline for multimodal neuroimaging and connectome analysisNeuroimage 263
75.
1. Van Essen DC
2. Glasser MF
3. Dierker DL
4. Harwell J
5. Coalson T
2012Parcellations and hemispheric asymmetries of human cerebral cortex analyzed on surface-based atlasesCereb Cortex 22:2241–62
76.
1. Cox RW
1996AFNI: Software for Analysis and Visualization of Functional Magnetic Resonance NeuroimagesComput Biomed Res 29:162–73
77.
1. Henschel L
2. Conjeti S
3. Estrada S
4. Diers K
5. Fischl B
6. Reuter M
2020FastSurfer - A fast and accurate deep learning based neuroimaging pipelineNeuroimage 219
78.
1. Henschel L
2. Kügler D
3. Reuter M
2022FastSurferVINN: Building resolution-independence into deep learning segmentation methods—A solution for HighRes brain MRINeuroimage 251
79.
1. Faber J
2. Kügler D
3. Bahrami E
4. et, al.
2022CerebNet: A fast and reliable deep-learning pipeline for detailed cerebellum sub-segmentationNeuroimage 264
80.
1. Marcus DS
2. Harwell J
3. Olsen T
4. Hodge M
5. Glasser MF
6. Prior F
7. et al.
2011Informatics and data mining tools and strategies for the human connectome projectFront Neuroinform 5
81.
1. Jenkinson M
2. Beckmann CF
3. Behrens TEJ
4. Woolrich MW
5. Smith SM
2012FSLNeuroimage 62:782–90
82.
1. DuPre E
2. Salo T
3. Ahmed Z
4. Bandettini PA
5. Bottenhorn KL
6. Caballero-Gaudes C
7. et al.
2021TE-dependent analysis of multi-echo fMRI with *tedana*Journal of Open Source Software 6
83.
1. Greve DN
2. Fischl B
2009Accurate and robust brain image alignment using boundary-based registrationNeuroimage 48:63–72
84.
1. Avants BB
2. Yushkevich P
3. Pluta J
4. Minkoff D
5. Korczykowski M
6. Detre J
7. et al.
2010The optimal template effect in hippocampus studies of diseased populationsNeuroimage 49:2457–66
85.
1. Avants BB
2. Tustison NJ
3. Song G
4. Cook PA
5. Klein A
6. Gee JC
2011A reproducible evaluation of ANTs similarity metric performance in brain image registrationNeuroimage 54:2033–44
86.
1. Larivière S
2. Bayrak Ş
3. Vos de Wael R
4. Benkarim O
5. Herholz P
6. Rodriguez-Cruces R
7. et al.
2023BrainStat: A toolbox for brain-wide statistics and multimodal feature associationsNeuroimage 266

Article and author information

Author information

Hans Auer
Montreal Neurological Institute and Hospital, McGill University, Montreal, Canada
ORCID iD: 0000-0003-2127-4636
- For correspondence: hans.auer@mail.mcgill.ca
Donna Gift Cabalo
Montreal Neurological Institute and Hospital, McGill University, Montreal, Canada
ORCID iD: 0000-0001-9568-1723
Raul Rodriguez-Cruces
Montreal Neurological Institute and Hospital, McGill University, Montreal, Canada
ORCID iD: 0000-0002-2917-1212
Oualid Benkarim
Montreal Neurological Institute and Hospital, McGill University, Montreal, Canada
ORCID iD: 0000-0003-3922-7643
Casey Paquola
Institute for Neuroscience and Medicine (INM-7), Forschungszentrum Jülich, Jülich Germany
ORCID iD: 0000-0002-0190-4103
Jordan DeKraker
Montreal Neurological Institute and Hospital, McGill University, Montreal, Canada
ORCID iD: 0000-0002-4093-0582
Yezhou Wang
Montreal Neurological Institute and Hospital, McGill University, Montreal, Canada
ORCID iD: 0000-0003-3650-5476
Sofie Valk
Institute for Neuroscience and Medicine (INM-7), Forschungszentrum Jülich, Jülich Germany, Max Planck Institute for Human Cognitive and Brain Sciences, Leipzig, Germany, Institute of Systems Neuroscience, Heinrich Heine University Düsseldorf, Düsseldorf, Germany
ORCID iD: 0000-0003-2998-6849
Boris C Bernhardt
Montreal Neurological Institute and Hospital, McGill University, Montreal, Canada
ORCID iD: 0000-0001-9256-6041
- Co-senior authors
Jessica Royer
Montreal Neurological Institute and Hospital, McGill University, Montreal, Canada
ORCID iD: 0000-0002-4448-8998
- Co-senior authors

Version history

Preprint posted: July 13, 2024
Sent for peer review: August 27, 2024
Reviewed Preprint version 1: November 11, 2024

Copyright

This article is distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use and redistribution provided that the original author and source are credited.

Metrics

views: 297
downloads: 2
citations: 0

Views, downloads and citations are aggregated across all versions of this paper published by eLife.

Significance of findings

Strength of evidence

Abstract

Introduction

Results

Data-driven histological analysis of the human amygdala

Data-driven histological mapping of the human amygdala.

Translating amygdala histological space to in vivo, ultra high-resolution, myelin-sensitive MRI.

Validation of histological space using independent post mortem dataset

In vivo generalizability of histological space

Association with macroscale function

Functional network mapping of amygdala microstructural subregions.

Discussion

Methods

Histological data acquisition and pre-processing

Amygdala segmentation and subdivision mapping

Histological feature extraction

Dimensionality reduction of histological features

In vivo MRI data acquisition

Multimodal MRI processing and analysis

Functional network mapping of amygdala microstructural subregions

Data and code availability

Acknowledgements

References

Article and author information

Author information

Hans Auer

Donna Gift Cabalo

Raul Rodriguez-Cruces

Oualid Benkarim

Casey Paquola

Jordan DeKraker

Yezhou Wang

Sofie Valk

Boris C Bernhardt*

Jessica Royer*

Version history

Copyright

Metrics

Boris C Bernhardt

Jessica Royer