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. Author manuscript; available in PMC: 2016 Aug 1.
Published in final edited form as: Pain. 2015 Aug;156(8):1545–1554. doi: 10.1097/j.pain.0000000000000196

Multivariate morphological brain signatures predict chronic abdominal pain patients from healthy control subjects

Jennifer S Labus 1,2,3,4,7, John D Van Horn 8, Arpana Gupta 1,2, Mher Alaverdyan 1, Carinna Torgerson 8, Cody Ashe-McNalley 1, Andrei Irimia 8, Jui-Yang Hong 1,5, Bruce Naliboff 1,2,3,4,7, Kirsten Tillisch 1,2,3,4,6,7, Emeran A Mayer 1,2,3,4,7
PMCID: PMC4504800  NIHMSID: NIHMS680657  PMID: 25906347

Abstract

Irritable bowel syndrome (IBS) is the most common chronic visceral pain disorder. The pathophysiology of IBS is incompletely understood, however evidence strongly suggests dysregulation of the brain-gut axis. The aim of this study was to apply multivariate pattern analysis to identify an IBS-related morphometric brain signature which could serve as a central biological marker and provide new mechanistic insights into the pathophysiology of IBS. Parcellation of 165 cortical and subcortical regions was performed using Freesurfer and the Destrieux and Harvard-Oxford atlases. Volume, mean curvature, surface area and cortical thickness were calculated for each region. Sparse partial least squares-discriminant analysis was applied to develop a diagnostic model using a training set of 160 females (80 healthy controls, 80 IBS). Predictive accuracy was assessed in an age matched holdout test set of 52 females (26 health controls, 26 IBS). A two-component classification algorithm comprised of the morphometry of 1) primary somato-sensory and motor regions, and 2) multimodal network regions, explained 36% of the variance. Overall predictive accuracy of the classification algorithm was 70%. Small effect size associations were observed between the somatosensory and motor signature and non-gastrointestinal somatic symptoms. The findings demonstrate the predictive accuracy of a classification algorithm based solely on regional brain morphometry is not sufficient but they do provide support for the utility of multivariate pattern analysis for identifying meaningful neurobiological markers in IBS.

Perspective

This article presents the development, optimization, and testing of a classification algorithm for discriminating female IBS patients from healthy controls using only brain morphometry data. The results provide support for utility of multivariate pattern analysis for identifying meaningful neurobiological markers in IBS.

Keywords: Structural magnetic resonance imaging, brain, females, abdominal pain, classification

Introduction

Multivariate pattern analyses (MVPA) employ supervised and unsupervised machine learning algorithms and projection techniques to identify, model and/or predict spatial and temporal patterns in neuroimaging data that discriminate between cognitive tasks or groups [6]. MVPA has been applied to describe and predict acute pain state and perception based on functional brain data [57]. In addition, MVPA based on functional and structural neuroimaging data has been applied to discriminate healthy controls (HCs) from persons with chronic pain including chronic low back pain [62], functional dyspepsia [47; 55], and interstitial cystitis/bladder pain syndrome[4]. These analyses have provided important information regarding the possible brain mechanisms underlying chronic pain states. Eventually, the results from these analyses may translate into identification of novel therapeutic targets and development of individualized pain therapies based on brain signatures[57].

The utility of classification algorithms are limited by the method used for assessing accuracy of prediction [34; 59]. Due to the scarcity of large neuroimaging datasets and the desire to train a classification model on the largest number of subjects available, most neuroimaging researchers have opted for employing internal cross-validation procedures including leave one out and m-fold cross validation to determine predictive accuracy. However, testing the accuracy of an algorithm on a holdout test sample or independent data not used to train the classifier is considered to be the best approach for testing the generalizability and performance of the classifier [6; 34]. This external validation procedure tests the generalizability of the predictive algorithm to the general population of interest that may vary with respect to demographics, affective and clinical characteristics. Given the known heterogeneity among patients with chronic pain diagnoses, external validation is extremely important when making any inferences about the predictive utility of a classification algorithm.

Irritable bowel syndrome (IBS), the most common chronic abdominal pain syndrome, is thought to result from alterations in brain gut interactions, including alterations in central pain modulation, and autonomic nervous system responses [49]. IBS also has a high comorbidity with other chronic pain and affective disorders [64]. Multiple alterations in the central nervous system as measured by structural and functional brain imaging have been demonstrated in IBS compared to HCs and these alterations correlate with self-reported symptom severity measures [18; 23; 25; 29; 37; 60]. Here, we apply MVPA to an objective biological marker, brain morphometry, in order to provide new mechanistic insights into IBS. Our biological systems based approach uses large-scale brain multivariate imaging processing pipelines, integrated visualization and supervised learning/classification algorithms. We aimed to test the hypothesis that IBS is associated with a specific morphometric brain signature which could represent a central biological marker for the disease. Such morphological brain alterations could be a predisposing factor for IBS development, or could reflect the longstanding input of increased visceral afferent signals to the brain. Furthermore we examined whether the brain signatures derived from a training data set could be used to accurately predict IBS in a holdout test sample.

Methods

Participants

The sample was comprised of a total of 216 female subjects, (HC n=108 and IBS n= 108) enrolled in neuroimaging studies at the Center for Neurobiology of Stress between 2007 and 2013. IBS subjects met Rome II or III symptom criteria for IBS [17]. A gastroenterologist or nurse practitioner obtained a medical history and physical exam to confirm the IBS diagnosis. IBS patients with any bowel habit were included. The Mini-International Neuropsychiatric Interview was used to identify past or current psychiatric illness [58]. The average age for IBS and HCs were similar, 30.0 years (SD=±9.2) and 28.1 years (±9.4), respectively. Average symptom duration in IBS subjects was 10.6 (±8.3) years. IBS subjects reported an average of overall symptoms in the past week of 9.9 (±4.5) on a 21 point numeric rating scale (0= no pain, 20= the most intense symptoms imaginable). Usual symptom severity reported by IBS subjects was 3.2 (±.61) as measured on an ordinal scale where 1 = None, 2 = Mild, 3 = Moderate, 4 = Severe, and 5 = Very Severe.

Exclusionary criteria for all subjects included: (1) serious medical conditions or taking medications which could compromise interpretation of the brain imaging; (2) ongoing major psychiatric diagnoses or use of psychotropic medications in the past 6 months (subjects were not excluded for lifetime incidence of psychiatric disorders or for intake of low-dose tricyclic antidepressants for non-psychiatric indications); and (3) excessive physical exercise (e.g., marathon runners). All procedures complied with the principles of the Declaration of Helsinki and were approved by the Institutional Review Board at our institution.

Case-control matching based on age was performed using the fuzzy algorithm in SPSS v.22. This resulted in a balanced matched sample of 108 HCs and 108 IBS patients. To test the generalizability of the predictive model, we used a hold out procedure via a random 80/20 split on HC data (along with their age-matched IBS subjects). This resulted in a training data set (N=160) and a test set (N=56).

Questionnaires

The Hospital Anxiety and Depression Scale [HADs] ([66] and the Patient Health Questionnaire-15 [PHQ] were obtained prior to the MRI [36]. The PHQ was scored without the 3 gastrointestinal symptom items due to their overlap with IBS symptoms. [36] These measures of somatic symptoms and nonclinical levels of anxiety were used to assess their association with the obtained classification results.

Structural MRI

HCs and IBS female subjects were scanned on a 3.0T Siemens Trio MRI after a sagittal scout was used to position the head. Structural scans were obtained from 1 of 6 different acquisition sequences using a high-resolution 3-dimensional T1-weighted, sagittal magnetization-prepared rapid gradient echo protocol as described in supplemental Table 1. Acquisition protocols only were included if they were used with both IBS and HC subjects. A general linear model controlling for age indicated that protocol 1 and 2 were similar to each other but had lower total gray matter volumes than the remaining protocols (see supplemental Figure 1, for graph of parameter estimates and 95% confidence intervals). Based on these results, we classified protocols into protocol A (1, 2) and protocol B (3, 4, 6, 7). Fisher’s two-sided exact test indicated that the distribution of groups across the protocols was not significantly different (Protocol 1, 48 HC, 36 IBS; Protocol 2, 60 HCs, 72 IBS). Furthermore, there was no evidence that the distribution of the protocols in the test and training samples for each group was unbalanced (HC, p=.52; IBS, p=.49).

Neuroimaging, segmentation and parcellation

T1-image segmentation and regional parcellation were conducted using FreeSurfer [11; 21; 22] following the nomenclature described in Destrieux atlas and the Harvard-Oxford subcortical atlas [13; 15]. For each cerebral hemisphere, a set of 74 cortical structures were labeled in addition to 7 subcortical structures and the cerebellum. Segmentation results from a sample subject are shown in Figure 1. One additional midline structure (the brain stem) was also included, for a complete set of 165 parcellations for the entire brain. Table 1 contains a description of the regions and their abbreviations. Four representative but distinct morphological measures were computed for each cortical parcellation: gray matter volume, surface area, mean cortical thickness, and mean curvature.

Figure 1.

Figure 1

Axial (A) and coronal (B) views of regional parcellations based on the Destrieux and Harvard-Oxford subcortical atlas in a representative subject.

Table 1.

List of regions and abbreviations for Destrieux and Harvard-Oxford Atlas Regions

Abbr Full name
L_CeB L cerebellum
L_Tha L Thalamus
L_CaN L Caudate
L_Pu L Putamen
L_Pal L Pallidum
Bstem Brain-Stem
L_Hip L Hippocampus
L_Amg L Amygdala
L_Nacc L Nucleus Accumbens
R_CeB R Cerebellum
R_Tha R Thalamus
R_CaN R Caudate
R_Pu R Putamen
R_Pal R Pallidum
R_Hip R Hippocampus
R_Amg R Amygdala
R_Nacc R Nucleus Accumbens
L_FMarG/S L Fronto-marginal gyrus (of Wernicke) and sulcus
L_InfOcG/S L Inferior occipital gyrus (O3) and sulcus
L_PaCL/S L Paracentral lobule and sulcus
L_SbCG/S L Subcentral gyrus (central operculum) and sulci
L_TrFPoG/S L Transverse frontopolar gyri and sulci
L_ACgG/S L Anterior part of the cingulate gyrus and sulcus (ACC)
L_MACgG/S L Middle-anterior part of the cingulate gyrus and sulcus (aMCC)
L_MPosCgG/S L Middle-posterior part of the cingulate gyrus and sulcus (pMCC)
L_PosDCgG L Posterior-dorsal part of the cingulate gyrus (dPCC)
L_PosVCgG L Posterior-ventral part of the cingulate gyrus (vPCC, isthmus of the cingulate gyrus)
L_cun L Cuneus
L_InfFGOpp L Opercular part of the inferior frontal gyrus
L_InfFGOrp L Orbital part of the inferior frontal gyrus
L_InfFGTrip L Triangular part of the inferior frontal gyrus
L_MFG L Middle frontal gyrus
L_SupFG L Superior frontal gyrus
L_LoInG/CInS L Long insular gyrus and central sulcus of the insula
L_ShoInG L Short insular gyri
L_MOcG L Middle occipital gyrus
L_SupOcG L Superior occipital gyrus
L_FuG L Lateral occipito-temporal gyrus (fusiform gyrus)
L_LinG L Lingual gyrus, ligual part of the medial occipito-temporal gyrus
L_PaHipG L Parahippocampal gyrus, parahippocampal part of the medial occipito-temporal gyrus
L_OrG L Orbital gyri
L_AngG L Angular gyrus
L_SuMarG L Supramarginal gyrus
L_SupPL L Superior parietal lobule
L_PosCG L Postcentral gyrus
L_PRCG L Precentral gyrus
L_PrCun L Precuneus
L_RG L Straight gyrus, Gyrus rectus
L_SbCaG L Subcallosal area, subcallosal gyrus
L_HG L Anterior transverse temporal gyrus (of Heschl)
L_SupTGLp L Lateral aspect of the superior temporal gyrus
L_PoPl L Planum polare of the superior temporal gyrus
L_TPl L Planum temporale or temporal plane of the superior temporal gyrus
L_InfTG L Inferior temporal gyrus
L_MTG L Middle temporal gyrus
L_ALSHorp L Horizontal ramus of the anterior segment of the lateral sulcus (or fissure)
L_ALSVerp L Vertical ramus of the anterior segment of the lateral sulcus (or fissure)
L_PosLS L Posterior ramus (or segment) of the lateral sulcus (or fissure)
L_OcPo L Occipital pole
L_Tpo L Temporal pole
L_CcS L Calcarine sulcus
L_CS L Central sulcus (Rolando’s fissure)
L_CgSMarp L Marginal branch (or part) of the cingulate sulcus
L_ACirIns L Anterior segment of the circular sulcus of the insula
L_InfCirIns L Inferior segment of the circular sulcus of the insula
L_SupCirInS L Superior segment of the circular sulcus of the insula
L_ATrCoS L Anterior transverse collateral sulcus
L_PosTrCoS L Posterior transverse collateral sulcus
L_InfFS L Inferior frontal sulcus
L_MFS L Middle frontal sulcus
L_SupFS L Superior frontal sulcus
L_JS L Sulcus intermedius primus (of Jensen)
L_IntPS/TrPS L Intraparietal sulcus (interparietal sulcus) and transverse parietal sulci
L_MOcS/LuS L Middle occipital sulcus and lunatus sulcus
L_SupOcS/TrOcS L Superior occipital sulcus and transverse occipital sulcus
L_AOcS L Anterior occipital sulcus and preoccipital notch (temporo- occipital incisure)
L_LOcTS L Lateral occipito-temporal sulcus
L_CoS/LinS L Medial occipito-temporal sulcus (collateral sulcus) and lingual sulcus
L_LORs L Lateral orbital sulcus
L_MedOrS L Medial orbital sulcus (olfactory sulcus)
L_OrS L Orbital sulci (H-shaped sulci)
L_POcS L Parieto-occipital sulcus (or fissure)
L_PerCaS L Pericallosal sulcus (S of corpus callosum)
L_PosCS L Postcentral sulcus
L_InfPrCS L Inferior part of the precentral sulcus
L_SupPrCs L Superior part of the precentral sulcus
L_SbOrS L Suborbital sulcus (sulcus rostrales, supraorbital sulcus)
L_SbPS L Subparietal sulcus
L_InfTS L Inferior temporal sulcus
L_SupTS L Superior temporal sulcus (parallel sulcus)
L_TrTs L Transverse temporal sulcus
R_FMarG/S R Fronto-marginal gyrus (of Wernicke) and sulcus
R_InfOcG/S R Inferior occipital gyrus (O3) and sulcus
R_PaCL/S R Paracentral lobule and sulcus
R_SbCG/S R Subcentral gyrus (central operculum) and sulci
R_TrFPoG/S R Transverse frontopolar gyri and sulci
R_ACgG/S R Anterior part of the cingulate gyrus and sulcus (ACC)
R_MACgG/S R Middle-anterior part of the cingulate gyrus and sulcus (aMCC)
R_MPosCgG/S R Middle-posterior part of the cingulate gyrus and sulcus (pMCC)
R_PosDCgG R Posterior-dorsal part of the cingulate gyrus (dPCC)
R_PosVCgG R Posterior-ventral part of the cingulate gyrus (vPCC, isthmus of the cingulate gyrus)
R_cun R Cuneus
R_InfFGOpp R Opercular part of the inferior frontal gyrus
R_InfFGOrp R Orbital part of the inferior frontal gyrus
R_InfFGTrip R Triangular part of the inferior frontal gyrus
R_MFG R Middle frontal gyrus
R_SupFG R Superior frontal gyrus
R_LoInG/CInS R Long insular gyrus and central sulcus of the insula
R_ShoInG R Short insular gyri
R_MOcG R Middle occipital gyrus
R_SupOcG R Superior occipital gyrus
R_FuG R Lateral occipito-temporal gyrus (fusiform gyrus)
R_LinG R Lingual gyrus, ligual part of the medial occipito-temporal gyrus
R_PaHipG R Parahippocampal gyrus, parahippocampal part of the medial occipito-temporal gyrus
R_OrG R Orbital gyri
R_AngG R Angular gyrus
R_SuMarG R Supramarginal gyrus
R_SupPL R Superior parietal lobule
R_PosCG R Postcentral gyrus
R_PRCG R Precentral gyrus
R_PrCun R Precuneus
R_RG R Straight gyrus, Gyrus rectus
R_SbCaG R Subcallosal area, subcallosal gyrus
R_HG R Anterior transverse temporal gyrus (of Heschl)
R_SupTGLp R Lateral aspect of the superior temporal gyrus
R_PoPl R Planum polare of the superior temporal gyrus
R_TPl R Planum temporale or temporal plane of the superior temporal gyrus
R_InfTG R Inferior temporal gyrus
R_MTG R Middle temporal gyrus
R_ALSHorp R Horizontal ramus of the anterior segment of the lateral sulcus (or fissure)
R_ALSVerp R Vertical ramus of the anterior segment of the lateral sulcus (or fissure)
R_PosLS R Posterior ramus (or segment) of the lateral sulcus (or fissure)
R_OcPo R Occipital pole
R_Tpo R Temporal pole
R_CcS R Calcarine sulcus
R_CS R Central sulcus (Rolando’s fissure)
R_CgSMarp R Marginal branch (or part) of the cingulate sulcus
R_ACirInS R Anterior segment of the circular sulcus of the insula
R_InfCirIns R Inferior segment of the circular sulcus of the insula
R_SupCirInS R Superior segment of the circular sulcus of the insula
R_ATrCoS R Anterior transverse collateral sulcus
R_PosTrCoS R Posterior transverse collateral sulcus
R_InfFS R Inferior frontal sulcus
R_MFS R Middle frontal sulcus
R_SupFS R Superior frontal sulcus
R_JS R Sulcus intermedius primus (of Jensen)
R_IntPS/TrPS R Intraparietal sulcus (interparietal sulcus) and transverse parietal sulci
R_MOcS/LuS R Middle occipital sulcus and lunatus sulcus
R_SupOcS/TrOcS R Superior occipital sulcus and transverse occipital sulcus
R_AOcS R Anterior occipital sulcus and preoccipital notch (temporo- occipital incisure)
R_LOcTS R Lateral occipito-temporal sulcus
R_CoS/LinS R Medial occipito-temporal sulcus (collateral sulcus) and lingual sulcus
R_LORs R Lateral orbital sulcus
R_MedOrS R Medial orbital sulcus (olfactory sulcus)
R_OrS R Orbital sulci (H-shaped sulci)
R_POcS R Parieto-occipital sulcus (or fissure)
R_PerCaS R Pericallosal sulcus (S of corpus callosum)
R_PosCS R Postcentral sulcus
R_InfPrCS R Inferior part of the precentral sulcus
R_SupPrCs R Superior part of the precentral sulcus
R_SbOrS R Suborbital sulcus (sulcus rostrales, supraorbital sulcus)
R_SbPS R Subparietal sulcus
R_InfTS R Inferior temporal sulcus
R_SupTS R Superior temporal sulcus (parallel sulcus)
R_TrTs R Transverse temporal sulcus

Abbreviation: CT=cortical thickness, G=gyrus, L =left, MC=Mean curvature, R=right, S=sulci, SA=surface area, V=volume

Sparse Partial Least Squares for Discrimination Analysis (sPLS-DA)

The aim of this analysis was to identify the brain markers that can help predict patient status (IBS, HCs). To this end, sPLS-DA was applied to the training data set to identify potential brain endophenotypes that discriminate IBS from HCs. sPLS-DA is a variant on well know PLS algorithms that has been used to analyse brain networks in IBS [38; 39] and in several other domains [35; 50]. The sPLS-DA algorithm was selected based upon its ability to deal with a large number of predictors, small sample size, and high collinearity among predictors [40]. sPLS-DA has shown good classification performance in comparison with other methods [40]. Recently, sPLS has been successfully applied to link multivariate neuroimaging and genetic data [44].

sPLS-DA maximizes the sample covariance between the brain measures and a group difference contrast using singular value decomposition [41; 43]. This multivariate technique reduces the dimensionality of the data by finding a set of orthogonal components (also referred to as latent variables) comprised of a set of selected features. This is similar to performing a principal components analysis but restricting the solution to explaining the variance in a group difference contrast. Unlike other previous PLS applications in neuroimaging, sPLS also performs automatic feature selection [6] on the variables comprising each component by using lasso penalization [42; 43]. This is important because highly dimensional data contain lots of irrelevant variables that weaken discriminatory power. Ultimately, the algorithm selects only a few of the most important variables that contribute to the final solution (For a more a technical description of the method, readers are encouraged to read [42; 43]).

Each variable selected for a component has an associated loading, which is a measure of the importance of that variable in the component for the discrimination into the two groups [43]. In addition, variable importance in projection (VIP) scores are calculated to provide a more standardized measure that represents the contribution of each feature relative to the variance explained by all components [51]. As a rule of thumb, predictors with VIP coefficients greater than one are considered particularly important for the classification [43].

Development and optimization of the predictive model

First, the volume, cortical thickness, surface area, and mean curvature of the 165 regions were entered as potential predictor variables into the sPLS-DA. The number of components/brain signatures to identify was fixed at 2. The number of components is often dictated by the number of groups, K, and the formula K-1. However, we also tested the utility of including a second component. We specified fifty variables to be selected/retained for each component or brain signature. See [43] for a complete discussion regarding the theory associated with selecting the optimum number of components and number of variables for each component. Instead of performing one sPLS analysis and providing this solution as the final model, we first performed a stability analysis to tune the final number of components and the number and type of variables comprising those components.

Stability analysis provides information on the reliability of the selected variables comprising a component if a training set is altered [40]. Stability analysis is achieved via 10-fold cross-validation repeated 100 times. This cross-validation procedure divides the training data into 10 folds or subsamples of data (n=16 test sets). A single subsample is set aside as test data and the remaining subsamples are used to train the sPLS-DA model. This process is repeated 100 times to determine the stability of variables selected for the first component. The stability of the variables is assessed by calculating the frequency or probability of a specific variable being selected across all cross-validation runs. We applied a threshold of 90% stability for retaining variables for the final sPLS-DA. Once the number of variables showing at least 90% stability is determined for the first component, the process is repeated for the second component. Stability analysis results in a very limited set of variables to be entered as predictor variables in the final sPLS analysis used to develop the classification algorithm. We refer to the components obtained in the final solution as brain signatures that are able to differentiate the particular groups. The brain signatures are summarized using variable loadings on the individual dimensions/components and VIP coefficients. We also use graphical displays to illustrate loadings and discriminative abilities of the algorithms [40].

The predictive ability of the final model was assessed on the test set (N=52). We calculated binary classification measures: sensitivity, specificity, positive predictive value and negative predictive value. Here, the sensitivity indexes the ability of the classification algorithm to correctly identify individuals with IBS. Specificity reflects the ability of the classification algorithm to correctly identify individuals in HC. Positive predictive value reflects the proportion of sample showing the specific IBS brain signature from the classification algorithm and actually having IBS (true positive). On the other hand, negative predictive value is the probability that the test result is negative, i.e., the participant does not have the IBS-specific brain signature and the participant does not have IBS (true negative).

Statistical Analyses

We applied sPLS-DA to analyze volume, cortical thickness, surface area, and mean curvature of the brain regions described above. In addition to the morphological brain data, total gray matter was included as potential predictive variable. sPLS-DA was performed using the R package mixOmics (http://www.R-project.org). We applied Pearson’s R to examine the association between individual IBS patient scores on each brain signature and patient’s self-report of usual symptom severity and overall symptom severity in the past week. We also examined the correlation between the brain signature scores and measures of non-gastrointestinal somatic symptoms and state anxiety in all subjects. We applied false discovery rate (FDR) to correct for multiple correlational analyses for each brain signature [56]. We report p values lower than .05 and their FDR-adjusted q values.

Results

MVPA/Classification analyses

Morphometric based classification

We examined whether the volume, cortical thickness, surface area, and mean curvature of any of the 165 brain regions could be used to discriminate HCs from IBS in the training data. Based upon stability analysis (see supplemental Figure 2), 21 variables were selected for the first component and 7 variables were selected for the second. As can be seen in Figure 2, the final model demonstrates the discriminative ability of the classifier by depicting the individuals from the sample based on their scores on the two brain signatures. Table 2 contains the list of selected morphometric parameters for each brain signature comprising the discriminative algorithm along with variable loadings, VIP coefficients, and the selected morphometric phenotype. Figures 3 and 4 depict the regions of interest comprising the brain signatures depicted on an inflated brain labeled with the Destrieux Atlas.

Figure 2. Individual sample plot.

Figure 2

Irritable bowel syndrome (red) and healthy control (blue) are represented as point placed according to their scores on the two brain signatures derived from a sparse partial least squares-discriminative analysis. This plot suggests group discrimination can be obtained with the morphological classifier.

Table 2.

Multivariate structural brain signatures

Brain Signature 1 Brain Signature 2 Brain Signature 1 Brain Signature 2
Region Metric Loading Loading VIP VIP
L Paracentral lobule and sulcus MC −0.28 1.49 0.99
L Postcentral gyrus CT −0.43 2.30 1.53
L Postcentral gyrus V −0.28 1.47 0.98
L Precentral gyrus V −0.26 1.35 0.90
R Central sulcus (Rolando’s fissure) MC −0.26 1.36 0.91
R Paracentral lobule and sulcus MC −0.22 1.17 0.78
R Precentral gyrus MC −0.33 1.72 1.15
R Superior segment of the circular sulcus of the insula (anterior/ mid insula) MC −0.19 1.01 0.67
L Middle temporal gyrus V −0.21 1.13 0.75
L Precentral gyrus MC −0.19 1.00 0.67
R Superior part of the precentral sulcus MC −0.16 0.84 0.56
R Superior frontal gyrus MC −0.15 0.79 0.53
R Pericallosal sulcus (S of corpus callosum) MC −0.17 0.92 0.62
R Anterior segment of the circular sulcus of the insula MC −0.16 0.85 0.57
L Subcentral gyrus (central operculum) and sulci CT −0.17 0.91 0.61
L Middle-posterior part of the cingulate gyrus and sulcus (pMCC) MC −0.16 0.83 0.55
L Anterior segment of the circular sulcus of the insula MC −0.14 0.72 0.48
L Central sulcus (Rolando’s fissure) V −0.15 0.78 0.52
L Suborbital sulcus (sulcus rostrales, supraorbital sulcus) MC −0.15 0.78 0.52
L Pericallosal sulcus (S of corpus callosum) MC −0.13 0.71 0.47
L Middle frontal gyrus MC −0.12 0.61 0.41
R inferior frontal/ anterior insula sulcus CT −0.27 0.00 1.07
L Superior part of the precentral sulcus CT −0.16 0.00 0.62
L Subcallosal area, subcallosal gyrus MC −0.30 0.00 1.18
R Transverse temporal sulcus (primary auditory area near Heschl’s gyrus) MC −0.64 0.00 2.53
L Lateral occipito-temporal sulcus (fusiform gyrus) SA 0.33 0.00 1.31
L Intraparietal sulcus (interparietal sulcus) and transverse parietal sulci MC −0.53 0.00 2.07
L Posterior ramus (or segment) of the lateral sulcus (or fissure) V −0.12 0.00 0.46

Brain morphometric endophenotypes selected for each brain signature along with variable loadings on that dimension/signature. For brain signature 1, all negative loading reflect IBS >HC. For brain signature 2, negative loading reflect HC > IBS. Variable of importance to the prediction coefficients (VIP) greater than one indicate endophentotypes that are considered particularly important for the classification. Please note these VIP values change for variables comprising the first component when considering the second component due to the additional variance explained.

Morphometric endophenotype indicates whether the measure was mean curvature,(MC), Volume (V), cortical thickness (CT), or surface area (SA). The first brain signature explained 16% of the variability and the second explained an additional 20% variance in classification of IBS based on morphometric phenotype data. Abbreviations L=Left, R=right.

Figure 3. Regions comprising the Brain signature 1.

Figure 3

Figure 3

Using Freesurfer, all regions comprising the signatures are depicted on an inflated brain labeled with the Destrieux Atlas. Table 2 contains the describes the morphological measures (Volume, Cortical thickness, surface area and/or mean curvature) of the regions that contributed to the solutions

  1. Brain Signature 1 regions-Lateral View: 4, Subcentral Gyrus (central operculum) and Sulci; 15, Middle Frontal Gyrus (15); 28, Postcentral Gyrus; 29, Precentral Gyrus; 38, Middle Temporal Gyrus; 45, Central Sulcus (Rolando’s Fissure); 47, Anterior Segment of the Circular Sulcus of the Insula; 49, Superior Segment of the Circular Sulcus of the Insula; 69, Superior Part of the Precentral Sulcus
  2. Brain Signature 1 regions-Medial View : 3, Paracentral Lobule and Sulcus; 8, Middle-Posterior Part of the Cingulate Gyrus and Sulcus (pMCC); 16, Superior Frontal Gyrus 66, Pericallosal Sulcus (Sulcus of Corpus Callosum); 70, Suborbital Sulcus (Sulcus Rostrales, Supraorbital Sulcus)
Figure 4. Regions comprising the Brain signature 2.

Figure 4

Figure 4

Using Freesurfer, all regions comprising the signatures are depicted on an inflated brain labeled with the Destrieux Atlas. Table 2 contains the describes the morphological measures (Volume, Cortical thickness, surface area and/or mean curvature) of the regions that contributed to the solutions

  1. Brain Signature 2 regions-Lateral View:
    41, Posterior Ramus of the Lateral Sulcus; 47, Anterior Segment of the Circular Sulcus of the Insula; 69, Superior Part of the Precentral Sulcus; 56, Intraparietal Sulcus and Transverse Parietal Sulci ; 74, Transverse Temporal Sulcus
  2. Brain Signature 2 regions- Medial View:
    21 Lateral Occipito-Temporal Gyrus (Fusiform Gyrus); 32, Subcallosal Area (Subcallosal Gyrus);

The first brain signature explained 16% of the variability in discriminating HCs and IBS This brain signature was comprised of morphometric alterations of several somato-sensory and motor regions (including pre and post central gyrus), interoceptive integration regions (including anterior and mid insula, the middle-posterior part of the cingulate gyrus and sulcus, and cognitive-modulatory regions (including subregions of the frontal gyrus). Ten of the 21 variables comprising the signature showed VIP coefficients greater than 1, suggesting these variables are the most influential in the predictive model. Cortical thickness of the left post central gyrus and mean curvature of the right precentral gyrus explained most of the variance in the group discrimination. As seen in Table 2, all loadings for variables on the first brain signature were negative, and associated with higher values in IBS.

The second brain signature explained 20% of the variance. This second brain signature was comprised of fronto-insular regions (right horizontal ramus of the anterior segment of the lateral sulcus), an emotion modulation region [left subcallosal area (subgenual cingulate)], a dorsal attentional region (left intraparietal sulcus and transverse parietal sulci), as well as visual (left fusiform gyrus) and auditory (right transverse temporal sulcus near Heschl’s gyrus) gyri. The signature also contained a primary motor area (left superior part of the precentral gyrus) and primary interoceptive cortex (left posterior segment of the lateral sulcus posterior insula/inferior parietal sulci), but the VIP coefficients for these two regions were quite small indicating the least amount of influence on the discrimination of groups. Negative loadings were associated with greater values in HC compared to IBS. All loadings were negative except for the fusiform gyrus which had a greater value in IBS.

Estimating predictive accuracy of brain signatures for discriminating IBS from HCs in a test set

The classification algorithm developed in the training set was used to predict cases from the test set (N=52) and calculate binary classification measures. The algorithm had a sensitivity of 68% and a specificity of 71%. The negative predictive value was 69% and the positive predictive value was 70%. Overall classification accuracy in this independent test set was 70%. We also applied 10-fold cross validation 100 times and leave-one-out cross validation on the original training set. Cross validation estimated that the model performance had a sensitivity of 65%, specificity of 75%, negative predictive value of 68%, and positive predictive value of 72%. This resulted in an overall accuracy of 70%. Leave-one-out cross validation indicated a sensitivity of 65%, specificity of 74%, negative predictive value of 68%, and positive predictive value of 71%. This also resulted in an overall accuracy of 70%.

Correlations between morphometric brain signature scores and clinical variables

Correlations of brain signatures with behavioral and clinical variables in IBS were small and none of them survived correction for multiple comparisons. However, patient reports of usual symptom severity showed a trend for a small positive correlation with their scores on the second multimodal morphological signature, (r (108) =.20, p=.036, q=.072). Across IBS and HC, extra-gastrointestinal somatic symptoms across HC and IBS were associated with the somatosensory and motor brain signature, r (199) =−.19, p=.007, q=.028. No correlations were found between the brain signatures and state anxiety.

Discussion

The aim of this study was to determine whether a central biological signature of IBS could be identified based on a high resolution structural MRI brain image. Using large-scale pre-processing and analytic pipelines, a training data set, and applying sPLS-DA, we developed a predictive algorithm based on multivariate morphometric metrics. We then tested the accuracy of this predictive algorithm in an independent test sample to avoid biased estimation. We demonstrated that two morphological brain signatures discriminated female IBS subjects from HCs with 70% overall predictive accuracy. The predictive accuracy achieved with sPLS-DA was comparable to the predictive accuracy obtained using support vector machines and whole brain voxel-based morphometry data for discriminating HCs from subjects with a condition often comorbid with IBS, interstitial cystitis/bladder pain syndrome [4].

Brain signatures which discriminate IBS from HCs

The first component/brain signature explained 16% variance and was largely a somato-sensory and motor signature given that the most influential regions for the discrimination were pre- and post-central gyrus and the bilateral paracentral lobule. The paracentral lobule has been implicated in the regulation of motor activity related to defecation and micturition, and in motor sensory regulation of the lower extremity. This region has also been found to show altered functional connectivity with the midbrain in bladder pain syndrome/interstitial cystitis, a functional disorder with frequent overlap with IBS [31]. Other sensorimotor regions included the mid-insula, subcentral gyrus (central operculum) and sulci that connect the inferior parts of the pre- and post-central gyri and the middle-posterior part of the cingulate gyrus and sulcus. Although a part of this brain signature, regions associated with the salience network including the anterior insula and the closely connected medial frontal and middle temporal gyri were least influential in the discrimination. The morphometric values of all regions comprising this signature were higher in IBS, e.g. they had higher volume, cortical thickness, greater complexity, and/or larger surface area in IBS. Indirect evidence from retrograde tracing studies suggests that primary and secondary motor cortices provide input to central sympathetic control regions, and may therefore be able to modulate gastrointestinal motility and secretion [45]. Dysregulation of sympathetic nervous system activity has been demonstrated in IBS [48; 61] and in other disorders of chronic pain, such as fibromyalgia and temporomandibular disorder [46]. Recent structural MRI investigations in IBS have demonstrated similar increases in cortical thickness and volume in these sensorimotor areas confirming the relevance of the regions identified [29; 37]. Compared to the previously used parcellation based on the LBP40 atlas, the parcellation based on the Destrieux atlas used here provided greater resolution to identify more specific regions within the sensorimotor, cingulate, insular, and prefrontal cortices. Increased volume and cortical thickness in the somatosensory and motor regions have been reported in other chronic pain conditions including interstitial cystitis/painful bladder syndrome [30], trigeminal neuralgia [14], migraine [12] and temporomandibular disorders [53; 54]. Cortical thickening in primary somato-sensensory regions and posterior midcingulate cortex in healthy subjects has been associated with greater sensitivity to experimental temperature and pain stimuli [20]. Recent investigations of resting state data demonstrate an alteration in the salience and sensorimotor networks of IBS patients [23; 25; 26]. Resting state functional alterations in sensorimotor network regions have also been noted in females with other comorbid diseases including vulvodynia [24], fibromyalgia [33] and interstitial cystitis/bladder pain syndrome [31]. The reported alterations in these networks may mediate differences in perceptual sensitivity to visceral stimuli between HCs and IBS. When viewed together, the current findings support an important role of a gray matter signature involving sensorimotor regions in discriminating IBS from HCs.

A second independent brain signature was primarily characterized by the morphometry of regions involved in sensory (primary auditory cortex, fusiform gyrus,), emotion regulation (subgenual cingulate), dorsal attention (parietal sulci), and salience networks (inferior frontal gyrus/anterior insula). The primary viscerosensory cortex (posterior insula) and the primary motor cortex (left superior precentral gyrus) were also included in the signature but were the least influential in the discrimination of IBS and HCs. The morphometric values of all regions comprising this signature were higher in HCs with the exception of greater surface area of the fusiform gyrus in IBS. Consistent with our findings, the cortical thickness of the subgenual cingulate as well as the anterior insula has been reported as reduced in IBS compared to HCs [29]. Similar reductions have been reported in some forms of depression[16]. The subgenual cingulate is functionally and anatomically connected to a network of regions associated with autonomic nervous system and emotion regulation, including the amygdala and the vagal nucleus tractus solitarius [63]. The anterior insula is one of the core regions of the salience network, and functions as a hub integrating information from and interacting with brain networks including cognitive control/attentional, emotion regulation, and viscero- and somato-sensory networks to determine personal relevance of internal and external stimuli. In addition, anterior insula outputs to subcortical regions play an important role in adjusting descending pain modulation and autonomic nervous system responses in accordance with stimulus salience. [10; 52] [79; 52]. Of interest, smaller anterior insula volumes have been associated with lower rectal sensory perception thresholds in HCs [19]. Support for alterations in the processing of auditory stimuli have been reported in IBS and other functional pain disorders [2; 3]. In fact, a lack of habituation and potentiated prepulse inhibition to auditory stimuli suggest enhancement of pre-attentive processing suggestive of hypervigilance in IBS [5; 32]. Functional alterations in the dorsal attention network in IBS have also been described [27; 38]. In sum, the current data support the role of a multimodal brain signature comprised by salience, sensory, and autonomic regions in discriminating IBS from HCs.

Correlation of brain signatures with behavioral and clinical measures

We found that associations between structural brain signatures and symptom, clinical, and behavioral measures were weak. The only association that survived FDR correction was a small correlation between scores on the somato-sensory and motor signature and non-gastrointestinal somatic symptoms in HCs and IBS. Consistent with previous observations, these findings indicate that symptom based measures are poorly correlated with non-evoked morphological brain signatures. Self-reported symptoms may show stronger relationships with measures of structural or functional connectivity between brain regions as previously shown [26; 65]. One might hypothesize that structural brain signatures which develop over many years, will be more correlated with biological measures, including immune system alterations [28] rather than acute symptom severity.

Strengths and Limitations

The multivariate processing pipeline used in this study made it possible to examine not only volume and mean cortical thickness, but also additional measures including mean curvature and surface area. No one measure emerged as sufficient for discriminating the groups supporting this multivariate approach. Especially important as a morphometric measure for discriminating groups was mean curvature which represents cortical folding and indexes complexity of gyri. This exploratory analysis, combined with replication in an independent sample, compliments previous hypothesis driven approaches and provides new hypotheses regarding alterations in the processing of sensorimotor signals in IBS patients.

Whether the observed brain signatures are specific to IBS or generalizable to other, often overlapping chronic pain conditions or affective disorders remains to be tested. In the future, we hope to achieve the sample sizes necessary to generate a multiclass (multiple chronic pain disorders) discrimination algorithm using the growing Pain and Interoception Imaging Network (PAIN), a multimodal, multisite, brain-imaging repository for chronic somatic and visceral pain disorders (painrepository.org)[1]. Furthermore, this classifier has been developed in female subjects and does not provide evidence for inferences regarding IBS in males. To achieve an appropriately sized test and training set, we combined data obtained using slightly different structural acquisition parameters. Greater standardization of acquisition protocols is certainly desirable for exact parameter estimation and explaining variance in gray matter. However, despite this variability we were still able to discriminate groups, a finding that underscores the power of the technique.

Conclusion and possible pathophysiological implications

Alterations in sensorimotor regions dominated the morphometry-based classifier. Similar findings have been demonstrated in other chronic functional pain disorders suggesting a central role of these changes in the pathophysiology of chronic functional pain. It remains to be determined if these changes reflect chronically altered signaling from the viscera to the brain, if they are a vulnerability factor predating the onset of IBS symptoms, or if they play a primary role in symptom generation. Big data approaches such as MVPA provide an opportunity for new insights into pathophysiological mechanisms in IBS. This line of research, while still in its infancy, may provide information important in the future identification of therapeutic targets and in the development of tailored patient treatments. The predictive accuracy of this morphometric classifier is certainly not sufficient but provides support for the feasibility of this approach in examining central mechanisms in IBS. Future studies will examine the utility of resting state and anatomical (white matter) connectivity and network metrics in discriminating IBS from HCs.

Supplementary Material

Supplemental Figure 1. Supplemental Figure 1. Total gray matter volume by structural MRI acquisition protocol.

Estimates of total gray matter volume with 95% confidence intervals for each structural MRI acquisition protocol after controlling for age in healthy controls (A) and subjects with irritable bowel syndrome (B).

Supplemental Figure 2. Supplemental Figure 2. Stability of the 50 most select variables for Component 1 (A) and Component 2(B) across the cross-validation runs.

Depicts the 50 most frequently selected variables across all cross-validation runs for each component. Variable are color coded. For abbreviations see Table 1. Abbreviations: CT=cortical thickness, L =left, MC=mean curvature, R=right, SA=surface area, V=Volume.

Supplemental Table 1

Acknowledgments

This research was supported in part by grants from the National Institutes of Health: R01 DK048351 (EAM), P50DK64539 (EAM), R01 AT007137 (KT), K23 DK073451 (KT), K08 DK071626 (JSL), R03 DK084169 (JSL). Pilot scans were provided by the Ahmanson-Lovelace Brain Mapping Center, UCLA. The authors would like to especially thank Kim-Ahn Lê Cao and the mixOmics team for their technical assistance.

Footnotes

Disclosures: The authors declare no competing financial interests

The authors report no conflict of interest.

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Associated Data

This section collects any data citations, data availability statements, or supplementary materials included in this article.

Supplementary Materials

Supplemental Figure 1. Supplemental Figure 1. Total gray matter volume by structural MRI acquisition protocol.

Estimates of total gray matter volume with 95% confidence intervals for each structural MRI acquisition protocol after controlling for age in healthy controls (A) and subjects with irritable bowel syndrome (B).

Supplemental Figure 2. Supplemental Figure 2. Stability of the 50 most select variables for Component 1 (A) and Component 2(B) across the cross-validation runs.

Depicts the 50 most frequently selected variables across all cross-validation runs for each component. Variable are color coded. For abbreviations see Table 1. Abbreviations: CT=cortical thickness, L =left, MC=mean curvature, R=right, SA=surface area, V=Volume.

Supplemental Table 1

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