Abstract
Chronic pain is a major public health problem in the United States costing $635 billion annually. Hospitalizations for chronic pain in childhood have increased almost tenfold in the past decade, without breakthroughs in novel treatment strategies. Findings from brain imaging studies using structural and resting-state fMRI could potentially help personalize treatment to address this costly and prevalent health problem by identifying the underlying brain pathways that contribute, facilitate, and maintain chronic pain. The aim of this review is to synthesize structural and resting-state network pathology identified by recent brain imaging studies in pediatric chronic pain populations and discuss the potential impact of chronic pain on cortical development. Sex differences as well as treatment effects on these cortical alterations associated with symptom changes are also summarized. This area of research is still in its infancy with currently limited evidence available from a small number of studies, some of which suffer from limitations such as small sample size and suboptimal methodology. The identification of brain signatures of chronic pain in children may help to develop new pathways for future research as well as treatment strategies.
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Introduction
Chronic adolescent pain is estimated to cost society $19.5 billion,1 and insufficient funding for prevention, care, education, and research is likely to escalate this cost even more.2 Prevalence rates of chronic pain in children differ across numerous epidemiological studies relative to diagnosis, duration of pain, early adversity, and age.3 Coffelt et al.4 reported that between 2004 and 2010 the number of children admitted to a hospital for chronic pain increased 831%, with a significant portion presenting with comorbid conditions, such as depression, anxiety, and/or a change in bowel habits. Many of these chronic pain conditions involve multiple systems and show comorbidity with each other,5,6 with girls exhibiting a greater prevalence of chronic pain conditions, and even more pain with increased age.3,7 If left untreated, the development of chronic pain and psychiatric comorbidities can persist,8,9,10,11 while early targeted interventions have the potential to prevent the pain from continuing into adulthood.
Chronic pain can be characterized as somatic (musculoskeletal and cutaneous) and visceral (hollow or solid organs and smooth muscle). These two classes of pain have similarities and differences in underlying anatomical composition, organization, and cellular processes12,13,14 that can be represented as different neurological signatures (e.g., brainstem connectivity patterns).13 Pediatric pain brain imaging studies have provided insight into supraspinal pathologies, their relationship to observed behaviors, and treatments that can change chronic pain-induced alterations. This review will synthesize structural and resting-state network pathology from brain imaging studies in pediatric chronic pain populations. We discuss the potential interaction of chronic pain with cortical development, the possible role of microglia activation in this process, and suggest how treatments targeted at these cortical pathways show promise in treating this debilitating condition. The PubMed database was searched in November 2018 using the keywords “children,” “pain,” and “brain.” Only studies investigating structural and resting-state functional connectivity (RS-FC) between children with chronic pain and healthy controls (HCs) were used owing to the lack of studies using diffusion tensor imaging (DTI). The age limit for the children was set at 18 years. A total of 11 neuroimaging studies were found that met review criteria. Limitations and advantages of each of the studies are discussed, highlighting areas for future research.
Investigating cortical mechanisms in pediatric chronic pain using brain imaging
The limited brain imaging studies in children compared to adults makes it difficult to provide conclusive statements about interacting structural, connectivity, and neurochemical abnormalities. However, recent studies in children with complex regional pain syndrome (CRPS), migraine, sickle cell disease (SCD), and functional abdominal pain (FAP)/irritable bowel syndrome (IBS) have produced findings analogous to that in adults. Multimodal imaging refers to the use of different brain imaging techniques to detect and quantify different aspects of brain structure, function, and molecular signaling. Two of the most common methods are (1) structural magnetic resonance imaging (MRI)—determining properties of gray matter (GM)—and (2) functional MRI—assessing cortical activation through changes in local concentration of paramagnetic deoxyhemoglobin (blood-oxygen-dependent imaging). DTI, an imaging modality measuring white matter (WM) microstructure, has been investigated in adults with chronic pain but not in children.
GM is mainly measured using two approaches, voxel-based morphometry (VBM) and surface-based analyses (SBA). VBM quantifies the amount of GM in each voxel and allows for comparisons across subjects and groups. In SBA, various morphometric measures are derived from geometric models of the cortical surface. Cortical thickness is defined as the distance between the WM surface and the pial surface. Volume is a quadratic function of distances in the surface and a linear function of thickness. Surface area and the mean curvature, which is a measure of folding patterns (how sharply the cortex is folded), are also metrics derived from SBA.15,16 During resting-state, “functional networks” are groups of brain regions connected by their spatiotemporal configuration and function.17 The most common network alterations reported in chronic pain include the default mode network (DMN), sensorimotor network (SMN), salience network (SN), emotional regulation network (ERN), central executive network (CEN), and central autonomic network (CAN) (Table 1, Fig. 1). The DMN consists of the medial prefrontal cortex (mPFC), posterior cingulate cortex (PCC), inferior parietal cortex, lateral temporal cortex, and hippocampal formation. It is responsible for emotional processing, self-referential mental activity, and recollection of prior experiences.18,19,20 The SMN consists of the basal ganglia, thalamus, posterior insula, and the primary/secondary motor and somatosensory cortices. It receives input from the periphery and is important for the awareness of bodily sensations and the generation of appropriate motor responses.21 The SN consists of the mPFC, orbitofrontal cortex (OFC), anterior insula (aINS), and anterior mid-cingulate cortex (aMCC). It responds to a wide range of sensory stimuli or expectations of such stimuli, computes the subjective salience of such stimuli, and accordingly, coordinates appropriate behavioral, affective, and bodily responses aimed to assure homeostasis of the organism.21,22,23 The SN plays the major role in switching from the DMN to the engagement of the CEN, the ERN, and the CAN whenever the homeostasis of the organism is perturbed or the brain is expecting such a perturbation in the future. The CEN encompasses the dorsolateral PFC (dlPFC) and posterior parietal regions and is related to working memory, attentional processes, planning, and response selection.21 The ERN is comprised of the amygdala, the locus coeruleus, hippocampus, amygdala, subgenual anterior cingulate cortex (sgACC), pregenual ACC (pgACC), mPFC, and ventrolateral PFC. The ERN is an important link between stimulus appraisal and autonomic output.21 Finally, the CAN includes the brainstem, amygdala, hypothalamus, sgACC, aINS, aMCC, mPFC, and OFC and is responsible for central control and modulation of the autonomic nervous system.21,24
Sensorimotor network: M1 primary motor cortex, S1 primary somatosensory cortex, BG basal ganglia, THAL thalamus, posINS posterior insula. Salience network: mPFC medial prefrontal cortex, aMCC anterior mid-cingulate cortex, OFC orbitofrontal cortex, aINS anterior insula, Amyg amygdala. Central executive network: dlPFC dorsolateral prefrontal cortex, AnG angular gyrus, PrCu precuneus. Central autonomic network: mPFC medial prefrontal cortex, OFC orbitofrontal cortex, ACC anterior cingulate cortex, aINS anterior insula, Amyg amygdala, Brainstem brain stem. Emotion regulation network: mPFC medial prefrontal cortex, vlPFC ventrolateral prefrontal cortex, ACC anterior cingulate cortex, Hipp hippocampus, Amyg amygdala. Default mode network: mPFC medial prefrontal cortex, PCC posterior cingulate cortex, IPL inferior parietal lobule, MTG middle temporal gyrus.
Below is a summary of disease-related structural and resting-state brain-imaging findings across networks and chronic pain conditions in children (see Table 2). Sex differences within each pain condition are discussed.
Complex regional pain syndrome
CRPS is characterized by chronic pain, typically affecting an extremity but not exclusively, and associated with allodynia, hyperpathia, changes in skin color, temperature, and/or swelling in the affected areas.25 It may or may not be associated with an injury.
Children with CRPS compared to normal controls
Children with CRPS type I (absence of identified peripheral neuropathy) have less GM and higher RS-FC within the SN than HCs.26,27 They also have less GM and higher RS-FC in the cortical areas of the SMN, lower RS-FC in the basal ganglia of the SMN,26,27 less GM and higher RS-FC in the ERN,26,28 less GM and higher RS-FC in the CEN,26,27 less GM in the CAN,26 and less GM and higher RS-FC in the DMN than their HC counterparts.26 These findings suggest that much of the brain involved in regulating chronic pain may be hyperactive in children with CRPS and are responsible for consistent chronic pain with no obvious peripheral abnormalities and mediated by the central nervous system.
Headaches: migraines
Migraines are defined as an intense pulsing or throbbing pain most often in the head, although other sensory and motor systems can be involved, with some clinicians labeling recurrent bouts of severe abdominal pain as “abdominal migraines.”29,30 However, physiological evidence supporting the diagnosis of “abdominal migraine” is minimal.31,32 Additional symptoms can include nausea and vomiting, as well as sensitivities to light and sound. For some individuals, the onset of migraines can be predicted with the occurrence of an aura, described as visual disturbances of flashing lights and/or temporary loss of vision or some other premonitory symptom.
Findings of children with migraines associated with headaches compared to HCs indicate that children with migraines have less GM in the SN,33 mixed results regarding GM in the SMN,33,34 less GM in the ERN,33,34 and less GM in the DMN.33,34 This suggests that children with migraines have excess GM loss, synaptic pruning, and cortical reorganization throughout the brain, which could potentially contribute to hyperconnectivity and chronic pain. From a developmental perspective, this indicates that children with migraines may be undergoing cortical processes that represent sped up cortical development/aging and/or atrophy compared to healthy children. We later discuss plausible cellular mechanisms that may underlie these processes. No RS-FC studies have been conducted in this population.
Disease–sex interaction in children with migraines associated with severe headache
Sex differences have also been observed in GM trajectories throughout development. Specifically, GM volume reaches the highest levels in females 1–3 months earlier than in males throughout all structures. As there are sex GM trajectory differences,35 it is important to look at sex differences in the brain for children in chronic pain to understand potential sex-related developmental pathologies. Such differences have only been investigated in children with migraines.
Boys with migraines have lower GM in the regions of ERN compared to girls with migraines and lower RS-FC compared to girls and HCs.33,34 Boys with migraine have shown lower GM in the regions of ERN compared to male HCs; girls with migraines have greater GM in the regions of SMN compared to boys with migraines and HCs of both sexes; girls with migraines have greater GM and greater RS-FC in the regions of DMN compared to boys with migraines and HCs of both sexes.34 This suggests that the underlying circuits in networks affecting sensory processing may be different in boys (ERN) versus girls (DMN) with migraine. Further research in other chronic pain conditions can determine sex-dependent changes and differences that can direct targeted treatments. No RS-FC studies have been conducted in this population.
Puberty-stage effects in children with migraines
GM changes during puberty, a period of significant brain development, has only been studied in children with migraines.36 In children with migraines, during early puberty boys show more GM in the SMN compared to girls, yet at mid-puberty, girls show more GM in the SMN compared to boys. At early puberty, boys exhibit more GM in the ERN compared to girls, but at mid-puberty, the opposite sex finding occurs (girls show more GM in the ERN compared to boys).34 Thus girls may be more vulnerable to GM atrophy during early puberty, while boys may be more vulnerable in mid-puberty. As girls start puberty at an earlier age compared to boys, the development of these networks may be associated with cortical development due to age (i.e., lower overall GM in boys compared to girls), as well as due to the effect of migraine. Future multisite studies are needed to determine the degree to which puberty and biologic sex impact the effects of migraine on brain development.
Irritable bowel syndrome/functional abdominal pain
IBS is the most common disorder of brain–gut interaction (traditionally referred to as a functional gastrointestinal (GI) disorder), defined by recurrent abdominal pain associated with altered bowel habits. Patients often suffer from other GI symptoms, such as nausea, diarrhea, constipation, and bloating. IBS remains defined by symptom criteria and by the absence of identified GI structural, inflammatory, immunologic, or biochemical pathology.21
Children with IBS/FAP compared to HCs have less GM in the regions of the SN,37,38,39 less GM in the SMN (with decreases over time), as well as greater RS-FC within the SMN,37,38 they have less GM, as well as lower RS-FC between areas of the CEN,37,39 and mixed results regarding GM and RS-FC within the DMN.37,39 Similar conclusions can be made for children with CRPS, as less GM is associated with accelerated development and altered RS-FC, including greater SMN processing associated with hyperactive cortical circuits contributing to central pain. However, only one longitudinal study has been conducted to date and more studies are needed to prove this hypothesis. It has been shown that, in adults, GM loss is the consequence of chronic pain,40 suggesting that cortical hyperactivity, or other cortical cellular processes—which may be causing or be a consequence of chronic pain—may be a contributor to this phenomenon, but future studies are needed to address this hypothesis, especially in children.
Sickle cell disease
Vaso-occlusive pain crises are considered the hallmark symptom in SCD, a condition caused by a genetic defect in the β-globin chain and polymerization of hemoglobin S, and children with SCD may have repeated pain crises often requiring hospitalization.41 Over time, many children with SCD develop chronic pain.42 The impact of SCD on cognitive function may have salience in terms of cognitive-focused interventions and thus is mentioned here.
Children and adolescents with SCD are susceptible to mini-silent strokes that can impact brain structure and function and may contribute to chronic pain and cognitive dysfunction.43,44,45,46,47 Children with SCD compared to HCs have been found to have less GM in the DMN,48 ERN, and SMN,49 as well as greater RS-FC in the DMN, a finding associated with lower cognitive performance.50 These results run parallel to the GM loss and greater RS-FC observed in other chronic pain conditions in children. Lower GM and greater RS-FC in the DMN suggest that this key network involved in regulating chronic pain is hyperactive and contributing to symptoms. This may also be associated with accelerated development/aging of the brain and heightened neural connectivity associated with chronic pain and other neurological deficits.
Efficacy of treatments and associated brain changes
Treatment effects concerning neuroimaging findings in CRPS
Longitudinal studies have shown that with appropriate therapy, chronic pain can be reduced, and these clinical improvements are associated with supraspinal changes. Following an intensive 3-week, 8 h/day, 5 days/week psycho/social/physical treatment regimen,51 decreased RS-FC in the SMN was associated with decreased pain.27 GM volume in the SMN increased following the intervention.26 This growth in GM was also associated with lower pain scores.26,27 Previously lower GM in the ERN increased and higher RS-FC in the ERN decreased.27,28 GM in the CAN increased.26 RS-FC within the DMN decreased and was associated with decreased pain.26 In addition, increases in RS-FC between the dlPFC and periaqueductal gray were observed following treatment,26 reflecting an enhanced ability to engage in top–down inhibitory mechanisms.52,53 However, all of these studies were conducted in one institution and one condition (CRPS), and more research is needed as validation.
Discussion
Children across all chronic pain conditions studied were found to have lower GM and greater RS-FC within the major pain-associated networks. Some of these differences between children with and without pain were associated with altered pain perception. Reduced chronic pain was associated with normalized pathologic brain connectome differences associated with non-pharmacological, pain-focused interventions.
Data from neuroimaging studies in children with chronic pain (Table 2) indicate generally lower GM throughout the brain across diagnoses compared to HCs, with one longitudinal study showing decreased GM in the SMN in children with IBS from ages 7 to 9 years compared to that in controls.37 Most studies have found that children with chronic pain exhibit higher RS-FC compared to HCs. However, longitudinal studies will be needed to replicate these findings in larger samples across chronic pain conditions, age, puberty, and between sexes.
The developing brain—a primer
The structure of the developing brain is a product of variable regressive (e.g., synaptic pruning) and progressive (e.g., increased myelination) cellular processes occurring simultaneously, which correspond to brain shrinkage and growth.54 Between the ages of 7 and 30 years, as the brain grows in an evolutionarily relevant sequence, there is a reduction in the density of GM but an increase in WM.54,55 Moreover, it has been established that trajectories that take both brain size and age into consideration are more likely to predict functional characteristics (e.g., intellectual ability56 or neurodevelopmental disorders, such as autism, attention-deficit/hyperactivity disorder, and schizophrenia36,56,57,58) compared to absolute GM density.56,59,60
The developing functional brain exhibits pronounced “small-world” characteristics.61 This means the brain is organized into local networks that are not as communicative as more densely connected networks found in adults. Early in development, functional hubs are largely confined to sensory and motor regions and, with age, shift to the PCC and insula. Developmentally, the most important networks are regarded to be the CEN, SN, and DMN. These networks are identifiable at an early age and undergo significant change until the age of about 20 years. Deficits in these networks are often seen in neurodevelopmental disorders and chronic pain.26,27,28,33,34,37,38,39,50,61 Thus, even as most imaging studies to date in pediatric pain populations have been cross-sectional, we will discuss these findings in the context of the developing brain.
The developing brain during childhood and adolescence and its role in pain
Neuroplasticity in infancy and childhood underlies the tremendous nociceptive brain development before adulthood.62 Neuroplasticity plays an essential role in the development of neonatal brain circuits and GM and WM development throughout adolescence. The human brain undergoes extensive changes in GM and RS-FC throughout development into adolescence and young adulthood.55,59,63,64,65,66,67,68 The effect of nociceptive stimuli on the developing, infant human brain has been studied using electroencephalography and event-related potentials (ERPs). Larger nociceptive ERPs but not tactile ERPs have been found in preterm infants who were exposed to many invasive, skin-breaking, painful procedures and morphine,69 suggesting that pain experienced in the neonatal intensive care unit (NICU) affects brain networks involved in pain processing but not in perception of non-painful tactile stimuli. Up to 68.4% of children who spend time in the NICU can develop chronic pain by age 10 years, and greater pain-related stressors, painful procedures, and morphine in the NICU are associated with lower global brain volumes and lower GM throughout the brain during childhood.70,71 Abnormalities in WM microstructure are associated with greater numbers of invasive procedures by age 7 years and lower cognitive function.72 Cortical abnormalities associated with chronic pain can continue into adulthood and are manifest by both physical and psychological symptoms.10,37,73 These results suggest that the developing brain is plastic and vulnerable and that changes in pain-processing circuits in response to nociceptive stimuli can result in long-lasting anatomical and functional changes contributing to lifelong chronic pain.
As children age, their GM decreases and their RS-FC increases.61 Pain during childhood may magnify and hasten these neurodevelopmental changes. Along these lines, the rapid neurological changes as a consequence of GM loss during synaptic pruning and associated myelination could lead to increased RS-FC connectivity. We hypothesize that this neural developmental “speed-up process” involving microstructural processes such as the production of more myelin, selective synaptic pruning, and the development of subcortical–cortical connectivity61,67,74,75 could be a cortical facilitator of chronic pain symptoms in children, facilitating exacerbated communication between brain regions. In adults, a reduction of cortical GM, specifically in the cingulate, OFC, insula, dlPFC, thalamus, and somatosensory cortex, has been associated with chronic pain and linked to premature aging.40,76,77,78,79,80 Longitudinal studies in adults with chronic pain, compared to controls, have shown decreases in GM in the somatosensory cortex, motor cortex, throughout the striatum, and in the insula,81,82 a finding that is a consequence and not the cause of chronic pain.40 Just as overall greater RS-FC was found in most cortical networks in children with chronic pain, increased RS-FC has been observed in adults with chronic pain longitudinally. Specifically, decreased GM and increased sensorimotor–mPFC functional connectivity found in both cross-sectional and longitudinal studies predict pain chronification,82,83 and hyperconnectivity has been associated with the intensity of chronic pain.84 High mPFC–nucleus accumbens (subcortical–cortical) connectivity in adults with chronic pain plays a significant role in reorganizing and decreasing the GM in the cortex and increasing the emerging WM tracts in pain-modulatory regions.85 As the mPFC is involved in the SN, ERN, and CAN, increased activity in mPFC in children with chronic pain can be heavily impacted by increasing activity throughout multiple cortical networks involved in pain, thus increasing pain focus and amplifying pain signaling.83,86,87
Formation of pain-associated pathologic neural networks is also influenced by genetic and epigenetic factors.88,89,90 Atypical pain sensitivity and sensory integration issues are common in children with developmental disorders (e.g., autism).91,92 These developmental brain alterations could leave children with chronic pain vulnerable to the development or exacerbation of chronic pain and psychiatric pathologies at later times during childhood and adolescence8,93,94 and may even “set the stage” for pain problems throughout the lifespan.
The possible role of microglial activation in chronic pediatric pain
In the past decade, many mechanistic studies have focused on the role of microglia and neuro-glial interactions in the spinal cord and brain in chronic, persistent pain. Using positron emission tomography imaging, greater brain glial activation has been observed in the brains of adults with chronic low back pain and fibromyalgia, specifically within the SMN and executive control network.95,96 These findings suggest a plausible mechanism underlying hyperconnectivity of the SMN in low back pain patients97 and other patients with chronic pain, including children.27,82,98,99,100,101,102,103 Microglia continuously monitor the interstitial fluid for extracellular signals and consequently respond to maintain homeostasis via a multitude of highly diverse processes. These activities affect both GM and WM, including neuronal plasticity, synaptic pruning, programmed cell death, and phagocytosis.104 In addition, phenotypic characteristics of aging and activated microglia have been associated with an elevation in pro-inflammatory cytokines and proliferative capacity, while showing a decrease in phagocytosis and motility, a phenomenon that is known as “microglia priming.”105 The effects of microglia priming (e.g., exaggerated neuroinflammatory response) are known to have a vital role in excitation of lamina I neurons in the central nervous system, which are crucially involved in chronic neuropathic pain. In addition, excess glial activation and synaptic pruning can be observed as GM loss, as glial cells are known to remove synapses in an activity-dependent manner via inflammatory-mediated neurodegeneration and reactive microgliosis.106,107,108 Future research focusing on imaging microglia, central nervous system function, and intrinsic brain connectivity may help provide a mechanistic explanation underlying the observed cortical changes (i.e., decreased GM and greater RS-FC) and hypothesized accelerated aging80,109,110,111 in children with chronic pain.
Treatments and cortical mechanisms
Non-pharmacological treatments for chronic pain, such as cognitive-behavioral therapy (CBT), have proved efficacious112,113,114,115 and provided insight into cortical mechanisms that could be targeted to improve symptoms. For example, an intensive day-hospital treatment program, consisting of physical, occupational, and CBT therapies,51 decreased previously higher amygdala connectivity in the SMN, SN, and CEN in adolescents with chronic pain compared to controls at a matched time interval before and after the patients were discharged. This decrease in connectivity was associated with a decrease in self-reported pain.28 CBT on its own has also proved efficacious for children with chronic pain in reducing activity limitations and pain intensity.116 Changes in neural connectivity associated with CBT effectiveness in children with chronic pain are yet to be explored but have been shown to change RS-FC in adults with chronic pain and are associated with symptom improvement.104
Results from other therapies in adult chronic pain patients have shown the effectiveness of such interventions and should be evaluated in children. Non-invasive treatments such as transcranial magnetic stimulation and brain–computer interfaces117 have shown promising results in adults with chronic pain. Pharmacological treatments such as selective serotonin reuptake inhibitors, serotonin and norepinephrine reuptake inhibitors, and pregabalin are effective in reducing abnormally higher RS-FC, which was associated with clinical improvement, across multiple networks in adults with chronic pain.118,119,120 Such pharmacological management of chronic pain and associated brain changes in children has yet to be investigated. Greater neuroplasticity in children compared to adults suggests that brain-targeted interventions may be more potent with effects longer lasting when taking place during childhood before irreversible brain changes have occurred. This hypothesis is consistent with the clinical efficacy of neuromodulatory treatments such as hypnosis in children with chronic pain.121
Limitations and advantages
Neuroimaging studies have been known to have flexibility regarding analysis pipelines and statistical methodology. Many small changes can have a large effect on the results produced so that analysis parameters are crucial to the final results.122,123 We compiled study scanner parameters and methodology to examine how differences in study design and analysis parameters may influence final results (Supplementary Tables). Small sample size may lead to false positives and need to be replicated in larger samples, such as 20 subjects are for MRI data replicability.124 False positives can result from liberal statistical thresholding (deviating from the norm of p < 0.001) or using uncorrected results.125,126 Use of different analytic programs can also create risk for false positives.126 Future studies require adequate sample size, standardized pipelines for processing data, appropriate statistical thresholding, and consideration of confounding variables, such as age, sex, motion, and other cortical confounds. Surface-based approaches have also been shown to have greater sensitivity and accuracy of cortical landmarks compared to volume-based approaches.127,128,129,130 Longitudinal versus cross-sectional studies with baseline randomization is preferred for causality inferences. Data-driven methodologies can analyze data more flexibly, have the ability to detect components that may not have been regarded as important a priori, and can generate a context for new models.131,132
Future directions
The current review of pediatric pain neuroimaging studies found changes in GM and RS-FC networks, with findings needing replication given the paucity of studies and differing pathophysiology between chronic pain conditions. Neuroimaging has shown that a network-based approach to identifying brain alterations in chronic pain conditions can contribute to a better understanding of pathophysiology and targets for interventions aimed at affective and sensory components of pain perception.133,134 Yet, abnormalities in these networks and reversal with effective treatment have been documented. Longitudinal research will help identify the subgroups of children who respond to different pain treatments consistent with a phenotypic, “precision medicine” approach. Future research on mechanisms associated with the development of pediatric chronic pain and progression into adulthood will require the integration of genetic, neonatal, familial, and historical data as well as other physiological and psychological parameters with data obtained from brain imaging. For such multimodal, integrated studies, large data sets will be needed to provide developmental pathways that explain trajectories of chronic pain in childhood and risk for progression of pain into adulthood.
References
Groenewald, C., Essner, B., Wright, D., Fesinmeyer, M. & Palmero, T. The economic costs of chronic pain among a cohort of treatment seeking adolescents in the United States. J. Pain 15, 925–933 (2014).
Committee on Advancing Pain Research Care and Education Board on Health Sciences Policy. Relieving Pain in America: A Blueprint for Transforming Prevention, Care, Education and Research (The National Academies Press, Washington, DC, 2011).
King, S. et al. The epidemiology of chronic pain in children and adolescents revisited: a systematic review. Pain 152, 2729–2738 (2011).
Coffelt, T. A., Bauer, B. D. & Carroll, A. E. Inpatient characteristics of the child admitted with chronic pain. Pediatrics 132, 1–8 (2013).
Zernikow, B. et al. Characteristics of highly impaired children with severe chronic pain: a 5-year retrospective study on 2249 pediatric pain patients. BMC Pediatr. 12, 54 (2012).
Egger, H., Jane Costello, E., Erkanli, A. & Angold, A. Somatic complaints and psychopathology in children and adolescents: stomach aches, musculoskeletal pains, and headaches prevalence of specific somatic complaints. J. Am. Acad. Child Adolesc. Psychiatry 38, 852–860 (1999).
Korterink, J. J., Diederen, K., Benninga, M. A. & Tabbers, M. M. Epidemiology of pediatric functional abdominal pain disorders: a meta-analysis. PLoS ONE 10, e0126982 (2015).
Hassett, A. L. et al. Reports of chronic pain in childhood and adolescence among patients at a tertiary care pain clinic. J. Pain 14, 1390–1397 (2013).
Dunn, K. M., Jordan, K. P., Mancl, L., Drangsholt, M. T. & Le Resche, L. Trajectories of pain in adolescents: a prospective cohort study. Pain 152, 66–73 (2011).
Hotopf, M., Carr, S., Mayou, R., Wadsworth, M. & Wessely, S. Why do children have chronic abdominal pain, and what happens to them when they grow up? Population based cohort study. BMJ 316, 1196–1200 (1998).
Jones, G. T., Silman, A. J., Power, C. & Macfarlane, G. J. Are common symptoms in childhood associated with chronic widespread pain in adulthood? Results from the 1958 British Birth Cohort Study. Arthritis Rheum. 56, 1669–1675 (2007).
Cervero, F. Visceral versus somatic pain: similarities and differences. Dig. Dis. 27, 3–10 (2009).
Dunckley, P. et al. A comparison of visceral and somatic pain processing in the human brainstem using functional magnetic resonance imaging. J. Neurosci. 25, 7333–7341 (2005).
Sikandar, S. & Dickenson, A. H. Visceral pain – the ins and outs, the ups and downs. Curr. Opin. Support. Palliat. Care 6, 17–26 (2012).
Greve, D. N. An absolute beginner’s guide to surface- and voxel-based morphometric analysis. Proc. Int. Soc. Magn. Reson. Med. 19 (2011).
Winkler, A. M. et al. Cortical thickness or grey matter volume? The importance of selecting the phenotype for imaging genetics studies. Neuroimage 53, 1135–1146 (2010).
Lee, H. & Frangou, S. Linking functional connectivity and dynamic properties of resting-state networks. Sci. Rep. 7, 16610 (2017).
Raichle, M. E. The brain’s default mode network. Annu. Rev. Neurosci. 38, 433–447 (2015).
Greicius, M. D., Krasnow, B., Reiss, A. L. & Menon, V. Functional connectivity in the resting brain: a network analysis of the default mode hypothesis. Proc. Natl Acad. Sci. USA 100, 253–258 (2003).
Buckner, R. L., Andrews-Hanna, J. R. & Schacter, D. L. The brain’s default network: anatomy, function, and relevance to disease. Ann. NY Acad. Sci. 1124, 1–38 (2008).
Mayer, E. A., Labus, J. S., Tillisch, K., Cole, S. W. & Baldi, P. Towards a systems view of IBS. Nat. Rev. Gastroenterol. Hepatol. 12, 592–605 (2015).
Seeley, W. W. et al. Dissociable intrinsic connectivity networks for salience processing and executive control. J. Neurosci. 27, 2349–2356 (2007).
Grupe, D. W. & Nitschke, J. B. Uncertainty and anticipation in anxiety: an integrated neurobiological and psychological perspective. Nat. Rev. Neurosci. 14, 488–501 (2013).
Critchley, H. D., Nagai, Y., Gray, M. A. & Mathias, C. J. Dissecting axes of autonomic control in humans: insights from neuroimaging. Auton. Neurosci. Basic Clin. 161, 34–42 (2011).
National Institute of Neurological Disorders and Stroke. Complex Regional Pain Syndrome (NINDS, Bethesda, MD, 2017)
Erpelding, N. et al. Rapid treatment-induced brain changes in pediatric CRPS. Brain Struct. Funct. 221, 1095–1111 (2016).
Becerra, L. et al. Intrinsic brain networks normalize with treatment in pediatric complex regional pain syndrome. Neuroimage Clin. 6, 347–369 (2014).
Simons, L. E. et al. The responsive amygdala: treatment-induced alterations in functional connectivity in pediatric complex regional pain syndrome. Pain. 155, 1727–1742 (2014).
Leppan-Angus, H., Saatci, D., Sutcliffe, A. & Guiloff, R. J. Abdominal migraine. BMJ 360, k179 (2018)
Popovich, D. M., Schentrup, D. M. & McAlhany, A. L. Recognizing and diagnosing abdominal migraines. J. Pediatr. Health Care 24, 372–377 (2010).
Mortimer, M. J. & Good, P. A. The VER as a diagnostic marker for childhood abdominal migraine. Headache 30, 642–645 (1990).
Good, P. A. Neurologic investigations of childhood abdominal migraine: a combined electrophysiologic approach to diagnosis. J. Pediatr. Gastroenterol. Nutr. 21, S44–S48 (1995).
Rocca, M. A. et al. Structural brain MRI abnormalities in pediatric patients with migraine. J. Neurol. 261, 350–357 (2014).
Faria, V. et al. The migraine brain in transition: girls versus boys. Pain 156, 2212–2221 (2015).
Giedd, J. N. et al. Brain development during childhood and adolescence: a longitudinal MRI study. Nat. Neurosci. 2, 861–863 (1999).
Giedd, J. N. & Rapoport, J. L. Structural MRI of pediatric brain development: what have we learned and where are we going? Neuron 67, 728–734 (2010).
Gupta, A. et al. Longitudinal changes in brain morphometry associated with abdominal pain and anxiety in pre-adolescent children. Gastroenterology 148, S-629 (2015).
Bhatt, R. R. et al. Altered brain structure and functional connectivity and its relation to pain perception in girls with irritable bowel syndrome. Psychosom. Med. 81, 146–154 (2019).
Hubbard, C. S. et al. Abdominal pain, the adolescent and altered brain structure and function. PLoS ONE 11, 1–30 (2016).
Rodriguez-Raecke, R., Niemeier, A., Ihle, K., Ruether, W. & May, A. Brain gray matter decrease in chronic pain is the consequence and not the cause of pain. J. Neurosci. 29, 13746–13750 (2009).
Connes, P. & Coates, T. D. Autonomic nervous system dysfunction: implication in sickle cell disease. C. R. Biol. 336, 142–147 (2013).
Gil, K. M. et al. Sickle cell disease pain in children and adolescents: change in pain frequency and coping strategies over time. J. Pediatr. Psychol. 18, 621–637 (1993).
Thust, S. C., Burke, C., Siddiqui, A. & Thust, S. C. Neuroimaging findings in sickle cell disease. Br. J. Radiol. 87, 20130699 (2014).
Daniel Armstrong, F. et al. Cognitive functioning and brain magnetic resonance imaging in children with sickle cell disease. Pediatrics 97, 864–870 (1996).
Jordan, L. C. et al. Incidental findings on brain magnetic resonance imaging of children with sickle cell disease. Pediatrics 126, 53–61 (2010).
Steen, R. G. et al. Brain imaging findings in pediatric patients with sickle cell disease. Radiology 228, 216–225 (2003).
Debaun, M. R. et al. Silent cerebral infarcts: a review on a prevalent and progressive cause of neurologic injury in sickle cell anemia. Blood 119, 4587–4596 (2012).
Kirk, G. R. et al. Regionally specific cortical thinning in children with sickle cell disease. Cereb. Cortex 19, 1549–1556 (2009).
Kawadler, J. M. et al. Subcortical and cerebellar volumetric deficits in paediatric sickle cell anaemia. Br. J. Haematol. 163, 373–376 (2013).
Colombatti, R. et al. Cognition and the default mode network in children with sickle cell disease: a resting state functional MRI study. PLoS ONE 11, e0157090 (2016).
Logan, D. E. et al. A day-hospital approach to treatment of pediatric complex regional pain syndrome: initial functional outcomes. Clin. J. Pain 28, 766–774 (2012).
Suzuki, R., Rygh, L. J. & Dickenson, A. H. Bad news from the brain: descending 5-HT pathways that control spinal pain processing. Trends Pharm. Sci. 25, 613–617 (2004).
Gebhart, G. F. Descending modulation of pain. Neurosci. Biobehav. Rev. 27, 729–737 (2004).
Sowell, E. R., Thompson, P. M., Tessner, K. D. & Toga, A. W. Mapping continued brain growth and gray matter density reduction in dorsal frontal cortex: inverse relationships during postadolescent brain maturation. J. Neurosci. 21, 8819–8829 (2001).
Sowell, E. R. et al. Mapping cortical change across the human life span. Nat. Neurosci. 6, 309–315 (2003).
Shaw, P. et al. Intellectual ability and cortical development in children and adolescents. Nature 440, 676–679 (2006).
Shaw, P. et al. Longitudinal mapping of cortical thickness and clinical outcome in children and adolescents with attention-deficit/hyperactivity disorder. Arch. Gen. Psychiatry 63, 540–549 (2006).
Courchesne, E. et al. Mapping early brain development in autism. Neuron 56, 399–413 (2007).
Lenroot, R. K. et al. Sexual dimorphism of brain developmental trajectories during childhood and adolescence. Neuroimage 36, 1065–1073 (2007).
Giedd, J. N. et al. Trajectories of anatomic brain development as a phenotype. Novartis Found. Symp. 289, 101–112 (2008).
Menon, V. Developmental pathways to functional brain networks: emerging principles. Trends Cogn. Sci. 17, 627–640 (2013).
Verriotis, M., Chang, P., Fitzgerald, M. & Fabrizi, L. Development of the nociceptive brain. Neuroscience 338, 207–219 (2016).
Lebel, C., Walker, L., Leemans, A., Phillips, L. & Beaulieu, C. Microstructural maturation of the human brain from childhood to adulthood. Neuroimage 40, 1044–1055 (2008).
Gogtay, N. et al. Dynamic mapping of human cortical development during childhood through early adulthood. PNAS 101, 8174–8179 (2004).
Van Den Heuvel, M. P. et al. Abnormal rich club organization and functional brain dynamics in schizophrenia. JAMA Psychiatry 70, 783–792 (2013).
Uddin, L. Q., Supekar, K. S., Ryali, S. & Menon, V. Dynamic reconfiguration of structural and functional connectivity across core neurocognitive brain networks with development. J. Neurosci. 31, 18578–18589 (2011).
Supekar, K., Musen, M. & Menon, V. Development of large-scale functional brain networks in children. PLoS Biol. 7, e1000157 (2009).
Bartzokis, G. et al. Age-related changes in frontal and temporal lobe volumes in men: a magnetic resonance imaging study. Arch. Gen. Psychiatry 58, 461–465 (2001).
Slater, R. et al. Premature infants display increased noxious-evoked neuronal activity in the brain compared to healthy age-matched term-born infants. Neuroimage 52, 583–589 (2010).
Van Den Bosch, G. E. et al. Prematurity, opioid exposure and neonatal pain: do they affect the developing brain? Neonatology 108, 8–15 (2015).
Ranger, M. et al. Neonatal pain-related stress predicts cortical thickness at age 7 years in children born very preterm. PLoS ONE 8, e76702 (2013).
Vinall, J. et al. Invasive procedures in preterm children: brain and cognitive development at school age. Pediatrics 133, 412–421 (2014).
Fearon, P. & Hotopf, M. Relation between headache in childhood and physical and psychiatric symptoms in adulthood: national birth cohort study. BMJ 322, 1145 (2001).
Casey, B. J., Heller, A. S., Gee, D. G. & Cohen, A. O. Development of the emotional brain. Neurosci. Lett. 693, 29–34 (2019).
Fair, D. A. et al. Functional brain networks develop from a “‘local to distributed’” organization. PLoS Comput. Biol. 5, e1000381 (2009).
Apkarian, A. V. et al. Chronic back pain is associated with decreased prefrontal and thalamic gray matter density. J. Neurosci. 24, 10410–10415 (2004).
Schmidt-Wilcke, T. et al. Subtle grey matter changes between migraine patients and healthy controls. Cephalalgia 28, 1–4 (2008).
Schmidt-Wilcke, T. et al. Striatal grey matter increase in patients suffering from fibromyalgia – a voxel-based morphometry study. Pain 132, S109–S116 (2007).
Draganski, B. et al. Decrease of thalamic gray matter following limb amputation. Neuroimage 31, 951–957 (2006).
Kuchinad, A. et al. Accelerated brain gray matter loss in fibromyalgia patients: premature aging of the brain? J. Neurosci. 27, 4004–4007 (2007).
Baliki, M. N., Schnitzer, T. J., Bauer, W. R., Apkarian, A. V. & Luque, R. M. Brain morphological signatures for chronic pain. PLoS ONE 6, e26010 (2011).
Baliki, M. N. et al. Corticostriatal functional connectivity predicts transition to chronic back pain. Nat. Neurosci. 15, 1117–1119 (2012).
Hashmi, J. A. et al. Shape shifting pain: chronification of back pain shifts brain representation from nociceptive to emotional circuits. Brain 136, 2751–2768 (2013).
Lee, U. et al. Functional brain network mechanism of hypersensitivity in chronic pain. Sci. Rep. 8, 243 (2018).
Mansour, A. et al. Brain white matter structural properties predict transition to chronic pain. Pain 154, 2160–2168 (2013).
Elman, I. & Borsook, D. Common brain mechanisms of chronic pain and addiction. Neuron 89, 11–36 (2016).
Kucyi, A. et al. Enhanced medial prefrontal-default mode network functional connectivity in chronic pain and its association with pain rumination. J. Neurosci. 34, 3969–3975 (2014).
Alvarado, S. et al. An epigenetic hypothesis for the genomic memory of pain. Front. Cell. Neurosci. 9, 88 (2015).
Buchheit, T., Van De Ven, T. & Shaw, A. Epigenetics and the transition from acute to chronic pain. Pain Med. 13, 1474–1490 (2012).
Descalzi, G. et al. Epigenetic mechanisms of chronic pain. Trends Neurosci. 38, 237–246 (2015).
Robertson, A. E. & Simmons, D. R. The relationship between sensory sensitivity and autistic traits in the general population. J. Autism Dev. Disord. 43, 775–784 (2013).
Riquelme, I., Hatem, S. M. & Montoya, P. Reduction of pain sensitivity after somatosensory therapy in children with autism spectrum disorders. J. Abnorm. Child Psychol. 46, 1731–1740 (2018).
Brattberg, G. Do pain problems in young school children persist into early adulthood? A 13-year follow-up. Eur. J. Pain 8, 187–199 (2004).
Simons, L. E., Elman, I. & Borsook, D. Psychological processing in chronic pain: a neural systems approach. Neurosci. Biobehav. Rev. 39, 61–78 (2014).
Loggia, M. L. et al. Evidence for brain glial activation in chronic pain patients. Brain 138, 604–615 (2015).
Albrecht, D. S. et al. Brain glial activation in fibromyalgia - a multi-site positron emission tomography investigation. Brain Behav. Immun. 75, 72–83 (2019).
Yu, R. et al. Disrupted functional connectivity of the periaqueductal gray in chronic low back pain. NeuroImage Clin. 6, 100–108 (2014).
Napadow, V. et al. Intrinsic brain connectivity in fibromyalgia is associated with chronic pain intensity. Arthritis Rheum. 62, 2545–2555 (2010).
Liu, X. et al. Excessive coupling of the salience network with intrinsic neurocognitive brain networks during rectal distension in adolescents with irritable bowel syndrome: a preliminary report. Neurogastroenterol. Motil. 28, 43–53 (2016).
Loggia, M. L. et al. Default mode network connectivity encodes clinical pain: an arterial spin labeling study. Pain 154, 24–33 (2013).
Carvalho, S. et al. Intrinsic brain connectivity in chronic pain: a resting-state fMRI study in patients with rheumatoid arthritis. Front. Hum. Neurosci. 10, 107 (2016).
Davis, K. D. & Moayedi, M. Central mechanisms of pain revealed through functional and structural MRI. J. Neuroimmune Pharm. 8, 518–534 (2013).
Yoshino, A. et al. Changes in resting-state brain networks after cognitive–behavioral therapy for chronic pain. Psychol. Med. 48, 1148–1156 (2018).
Salter M. W. & Stevens B. Microglia emerge as central players in brain disease. Nat. Med. 23, 1018–1027 (2017).
Rawji, K. S. et al. Immunosenescence of microglia and macrophages: impact on the ageing central nervous system. Brain 139, 653–661 (2016).
Schafer, D. P. et al. Microglia sculpt postnatal neural circuits in an activity and complement-dependent manner. Neuron 74, 691–705 (2012).
Paolicelli, R. C. et al. Synaptic pruning by microglia is necessary for normal brain development. Science 333, 1456–1458. (2011).
Lull, M. E. & Block, M. L. Microglial activation and chronic neurodegeneration. Neurotherapeutics 7, 354–365 (2018).
Sibille, K. T. et al. Accelerated aging in adults with knee osteoarthritis pain: consideration for frequency, intensity, time, and total pain sites. Pain Rep. 2, e591 (2017).
Sibille, K. T. et al. Chronic pain, perceived stress, and cellular aging: an exploratory study. Mol. Pain 8, 12 (2012).
Moayedi, M. et al. Abnormal gray matter aging in chronic pain patients. Brain Res. 1456, 82–93 (2012).
Shpaner, M. et al. Unlearning chronic pain: a randomized controlled trial to investigate changes in intrinsic brain connectivity following cognitive behavioral therapy. Neuroimage Clin. 5, 365–376 (2014).
Palermo, T. M., Eccleston, C., Lewandowski, A. S., Williams, A. C. & Morley, S. Randomized controlled trials of psychological therapies for management of chronic pain in children and adolescents: an updated meta-analytic review. Pain 148, 387–397 (2010).
Simons, L. E. & Basch, M. C. State of the art in biobehavioral approaches to the management of chronic pain in childhood. Pain Manag. 6, 49–61 (2016).
Palermo, T. M., Wilson, A. C., Peters, M., Lewandowski, A. & Somhegyi, H. Randomized controlled trial of an Internet delivered family cognitive behavioral therapy intervention for children and adolescents with chronic pain. Pain 146, 205–213 (2009).
Palermo, T. M., Wilson, A. C., Peters, M., Lewandowski, A. & Somhegyi, H. Randomized controlled trial of an Internet-delivered family cognitive-behavioral therapy intervention for children and adolescents with chronic pain. Pain 146, 205–213 (2009).
Walter. A. et al. A brain-computer interface for chronic pain patients using epidural ECoG and visual feedback. In Proc. 2012 IEEE 12th International Conference on Bioinformatics & Bioengineering (IEEE, 2012).
Tsui, J. I., Herman, D. S., Kettavong, M., Anderson, B. J. & Stein, M. D. Escitalopram is associated with reductions in pain severity and pain interference in opioid dependent patients with depressive symptoms. Pain 152, 2640–2644 (2011).
Schmidt-Wilcke, T. et al. Resting state connectivity correlates with drug and placebo response in fibromyalgia patients. Neuroimage Clin. 6, 252–261 (2014).
Harris, R. E. et al. Pregabalin rectifies aberrant brain chemistry, connectivity, and functional response in chronic pain patients. Anesthesiology 119, 1453–1464 (2013).
Tomé-Pires, C. & Miró, J. Hypnosis for the management of chronic and cancer procedure- related pain in children. Int. J. Clin. Exp. Hypn. 60, 432–457 (2012).
Lyon, L. Dead salmon and voodoo correlations: should we be sceptical about functional MRI? Brain 140, 1–5 (2017).
Carp, J. On the plurality of (methodological) worlds: estimating the analytic flexibility of fmri experiments. Front. Neurosci. 6, 149 (2012).
Thirion, B. et al. Analysis of a large fMRI cohort: statistical and methodological issues for group analyses. Neuroimage 35, 105–120 (2007).
Woo, C.-W., Krishnan, A. & Wager, T. D. Cluster-extent based thresholding in fMRI analyses: pitfalls and recommendations. Neuroimage 91, 412–419 (2014).
Eklund, A., Nichols, T. E. & Knutsson, H. Cluster failure: why fMRI inferences for spatial extent have inflated false-positive rates. PNAS 113, 7900–7905 (2016).
Coalson, T. S., Van Essen, D. C. & Glasser, M. F. The impact of traditional neuroimaging methods on the spatial localization of cortical areas. Proc. Natl Acad. Sci. USA 115, E6356–E6365 (2018).
Ghosh, S. S. et al. Evaluating the validity of volume-based and surface-based brain image registration for developmental cognitive neuroscience studies in children 4-to-11 years of age. Neuroimage 53, 85–93 (2010).
Oosterhof, N. N., Wiestler, T., Downing, P. E. & Diedrichsen, J. A comparison of volume-based and surface-based multi-voxel pattern analysis. Neuroimage 56, 593–600 (2011).
Tucholka, A., Fritsch, V., Poline, J. B. & Thirion, B. An empirical comparison of surface-based and volume-based group studies in neuroimaging. Neuroimage 63, 1443–1453 (2012).
Ford, I. Commentary and opinion: III. Some nonontological and functionally unconnected views on current issues in the analysis of PET datasets. J. Cereb. Blood Flow Metab. 15, 371–377 (1995).
Iraji, A. et al. The connectivity domain: analyzing resting state fMRI data using feature-based data-driven and model-based methods. Neuroimage 134, 494–507 (2016).
Coghill, R. C., Sang, C. N., Maisog, J. M. & Iadarola, M. J. Pain intensity processing within the human brain: a bilateral, distributed mechanism. J. Neurophysiol. 82, 1934–1943 (1999).
Koyama, T., Mchaffie, J. G., Laurienti, P. J. & Coghill, R. C. The subjective experience of pain: where expectations become reality. PNAS 102, 12950–12955 (2005).
Acknowledgements
E.A.M. has been supported by grants from the National Institute of Diabetes and Digestive and Kidney Diseases (DK048351, DK064539 and DK096606). L.K.Z. has been supported by grants from the National Heart, Lung, and Blood Institute (NIH 1U01HL117718), the National Institute of Child Health and Human Development (1R43HD09077), the National Cancer Institute (1R43CA206666), and the National Institute of Diabetes and Digestive and Kidney Diseases (R43DK105623). A.G. has been supported by the National Institute of Diabetes and Digestive and Kidney Diseases (K23 DK106528).
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Bhatt, R.R., Gupta, A., Mayer, E.A. et al. Chronic pain in children: structural and resting-state functional brain imaging within a developmental perspective. Pediatr Res 88, 840–849 (2020). https://doi.org/10.1038/s41390-019-0689-9
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DOI: https://doi.org/10.1038/s41390-019-0689-9
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