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Keywords:

  • sinusitis;
  • abnormal brain MRI;
  • developmental delay

Abstract

  1. Top of page
  2. Abstract
  3. Introduction
  4. Methods
  5. Results
  6. Conclusions
  7. Acknowledgements
  8. References

Objective

To collect normative MRI data for effective clinical and research applications. Such data may also offer insights into common neurological insults.

Methods

We identified a representative, community-based sample of children aged 9–14 years. Children were screened for neurodevelopmental problems. Demographic data, medical history and environmental exposures were ascertained. Eligible children underwent the Neurologic Examination for Subtle Signs (NESS) and a brain MRI. Descriptive findings and analyses to identify risk factors for MRI abnormalities are detailed.

Results

One hundred and two of 170 households screened had age-appropriate children. Two of 102 children had neurological problems – one each with cerebral palsy and epilepsy. Ninety-six of 100 eligible children were enrolled. Mean age was 11.9 years (SD 1.5), and 43 (45%) were boys. No acute MRI abnormalities were seen. NESS abnormalities were identified in 6 of 96 children (6%). Radiographic evidence of sinusitis in 29 children (30%) was the most common MRI finding. Brain abnormalities were found in 16 (23%): mild diffuse atrophy in 4 (4%), periventricular white matter changes/gliosis in 6 (6%), multifocal punctuate subcortical white matter changes in 2 (2%), vermian atrophy in 1 (1%), empty sella in 3 (3%) and multifocal granulomas with surrounding gliosis in 1 (1%). Having an abnormal MRI was not associated with age, sex, antenatal problems, early malnutrition, febrile seizures, an abnormal neurological examination or housing quality (all P values >0.05). No predictors of radiographic sinusitis were identified.

Conclusion

Incidental brain MRI abnormalities are common in normal Malawian children. The incidental atrophy and white matter abnormalities seen in this African population have not been reported among incidental findings from US populations, suggesting Malawi-specific exposures may be the cause.

Objectif

Recueillir des données IRM normatives pour des applications cliniques et de recherche efficaces. De telles données peuvent également offrir un aperçu sur les affections neurologiques courantes.

Méthodes

Nous avons identifié un échantillon représentatif, basé sur la communauté d'enfants âgés de 9 à 14 ans. Les enfants ont été examinés pour des problèmes de développement neurologique. Les données démographiques, les antécédents médicaux et les expositions environnementales ont été constatés. Les enfants éligibles ont subi l'examen neurologique pour les signes subtils (ENSS) et une IRM du cerveau. Les résultats descriptifs et analyses pour l'identification des facteurs de risque d'anomalies IRM sont détaillés.

Résultats

102/170 ménages échantillonnés avaient des enfants d’âge approprié. 2/102 enfants avaient des problèmes neurologiques, un avec une paralysie cérébrale et un avec l’épilepsie. 96/100 enfants éligibles ont été inscrits à l’étude. L’âge moyen était de 11.9 ans (DS: 1.5), 43 (45%) étaient de sexe masculin. Aucune anomalie IRM aiguë n'a été observée. Des anomalies ENSS ont été identifiées chez 6/96 (6%) enfants. Des signes radiologiques de sinusite 29 (30%) représentaient le résultat IRM le plus courant. Des anomalies cérébrales ont été trouvées chez 16 (23%) enfants: atrophie diffuse bénigne chez 4 (4%), changements de la matière blanche péri ventriculaire/gliose chez 6 (6%), changements multifocaux ponctués de la substance blanche sous-corticale chez 2 (2%), atrophie du vermis chez 1 (1%), selle turcique vide chez 3 (3%) et des granulomes multifocaux avec gliose environnante chez 1 (1%). Avoir une IRM anormale n’était pas associé à l’âge, au sexe, à des problèmes prénataux, à la malnutrition précoce, à des convulsions fébriles, à un examen neurologique anormal ni à la qualité des logements (tous les > 0.05). Aucun prédicteurs de la sinusite radiographique n'a été identifié.

Conclusion

Les anomalies IRM cérébrales fortuites sont communes chez les enfants du Malawi. L'atrophie fortuite et des anomalies de la substance blanche observées dans cette population africaine n'ont pas été rapportées parmi les découvertes fortuites dans les populations américaines, ce qui suggère que des expositions spécifiques au Malawi pourraient en être la cause.

Objetivo

Recoger datos de imágenes por resonancia magnética (IRM) normales para aplicaciones clínicas efectivas e investigación. Estos datos podrían también ofrecer una visión de lesiones neurológicas comunes.

Métodos

Hemos identificado una muestra representativa, basada en la comunidad, de niños con edades entre los 9–14 años. Los niños se evaluaron en busca de problemas de desarrollo neurológico. Se determinaron los datos demográficos, la historia médica y la exposición ambiental. A los niños elegibles se les realizó en Examen Neurológico para Signos Sutiles (NESS) y una IRM del cerebro. Se detallan los hallazgos descriptivos y el análisis para identificar los factores de riesgo de anormalidades en las IRM.

Resultados

102/170 hogares evaluados tenían niños en edad apropiada. 2/102 niños tenían problemas neurológicos — uno con parálisis cerebral y otro con epilepsia. Se incluyeron 96/100 niños elegibles. La edad media era de 11.9 años (SD 1.5), 43 (45%) eran hombre. No se observaron anormalidades agudas en las IRM. Se identificaron anormalidades en NESS en 6/96 (6%). La evidencia radiográfica de sinusitis 29 (30%) era el hallazgo por IRM más común. Se encontraron anormalidades en el cerebro en 16 (23%): atrofia difusa leve en 4 (4%), cambios periventriculares en la sustancia blanca /gliosis en 6 (6%), cambios multifocales en la sustancia blanca subcortical en 2 (2%), atrofia vermiana en 1 (1%), silla turca vacía en 3 (3%), y granulomas multifocales con gliosis circundante en 1 (1%). El tener una IRM anormal no estaba asociada con la edad, el sexo, los problemas prenatales, una desnutrición temprana, convulsiones febriles, un examen neurológico anormal o la calidad del hogar (todos los P's > 0.05). No se identificaron vaticinadores de sinusitis radiográfica.

Conclusión

Las anomalías incidentales en IMR del cerebro son comunes en niños normales de Malawi. La atrofia incidental y anormalidades de la materia blanca observadas en esta población Africana no se han reportado entre los hallazgos incidentales de poblaciones de Estado Unidos, sugiriendo que las exposiciones específicas para Malawi podrían ser la causa.


Introduction

  1. Top of page
  2. Abstract
  3. Introduction
  4. Methods
  5. Results
  6. Conclusions
  7. Acknowledgements
  8. References

Neurological disorders contribute substantially to the global burden of disease, but we know little about the pathophysiology of many common tropical conditions. Our insights into tropical diseases have often been elucidated through autopsy studies, but such insights are only available for fatal conditions and fatal cases offering limited insights into brain injury among survivors (Taylor 2004). Advanced neuroimaging technology can elucidate mechanisms of brain injury in vivo, but such technologies are generally not available in low-income settings. For example, in Africa, only 1 of every 5 countries has even a single MRI scanner, and in 2004, 40% of African countries surveyed had no functioning CT scanner (WHO/IBE/ILAE, 2005; WHO/WFN 2004).

When the Malawi MRI Facility opened in July 2008, the absence of normative data complicated the interpretation of brain MRI studies substantially. Difficulties were that (i) images obtained for evaluation of acute illnesses frequently revealed abnormalities associated with a chronic condition or pre-existing injury, (ii) structural abnormalities, such as unusual cortical nodules and severe vermian atrophy, were seen in paediatric populations. These are not well described in the radiologic literature, and the significance of such findings was unclear, and (iii) other findings of unclear significance, such as subclinical hydrocephalus, were frequently evident.

In low-income, tropical settings, individuals may experience CNS insults associated with trauma and infections more frequently than in developed regions. Exposures not generally encountered in developed populations, such as CNS parasitic infections and malnutrition, also occur. As a result of these exposures, people from low-income, tropical settings who undergo neuroimaging may have unexpected findings, which are unrelated to their acute presentation. Without normative data, there is substantial risk of falsely attributing coincidental findings to acute clinical conditions. In the absence of normative data, MRI technology could contribute more confusion than clarification in the tropics. Therefore, we undertook a study of brain MRIs in a community-based, representative sample of normal children in Malawi.

Methods

  1. Top of page
  2. Abstract
  3. Introduction
  4. Methods
  5. Results
  6. Conclusions
  7. Acknowledgements
  8. References

Study population

From July 2010 to December 2011, a representative, community-based sample of youths 9–14 years old was identified in the Blantyre catchment area using a pseudo-snowball referral technique (Van Meter, 1990), the Ten Questions. Using the homes of children enrolled in a previous longitudinal cohort study as a reference point (Birbeck, 2010), the research nurse used random directional sampling methods to identify an adjacent household to seek potential participants. Random directional sampling tables were developed for use during community recruitment visits. After identifying the reference household, the research nurse consulted the directional sampling table to determine which adjacent household to select. In the selected household, she then approached the head of household in residence to determine whether there are any children in the appropriate age range residing in the home. If more than one potential participant was identified, a modified Kish grid (1, 2) was used to select a specific youth. If the selected child or their parent declined participation or if no eligible child resided in the home, the declining household was used as the next point of reference, and using the same technique as described above, another adjacent household was identified and similarly approached. Once identified, potential normative study subjects were then screened using the Ten Questions (Durkin, 1992) and assessed for information regarding their demographic details, socio-economic status and exposures they have previously had that might result in CNS injuries. Inclusion criteria included being a resident of the sampled household, being 9–14 years old, no neurological problems identified on the Ten Questions, parental consent and youth assent. Menstruating girls also underwent a urine pregnancy test prior to MRI. This study was approved by the Malawi College of Medicine Research Ethics Committee and Michigan State University's Biomedical Institutional Review Board.

Participant assessments

Structured interviews were conducted in the local language to ascertain demographic details, socio-economic characteristics and environmental assessments and to obtain key aspects of the medical history. Study participants, all of whom had normal neurodevelopment based upon the Ten Questions, underwent the Neurological Examination for Subtle Signs (NESS) by a paediatric neurologist (Denckla 1985). They then underwent a brain MRI (0.35T GE Signa Ovation, Sag T1, Ax T2, Ax DWI). See Appendix 1 for the full scanning protocol. Two interpreting radiologists used NeuroInterp, a web-based multivariable tool of potentially relevant data points, which was developed and used for this and other ongoing studies using the Malawi MRI (Potchen 2012). NeuroInterp is a computer-based MRI reading program that requires the interpreting radiologists to evaluate and quantify MRI findings based upon the presence of normal structures and/or the scaled rating of any abnormality. The radiologists used NeuroInterp to provide independent reviews of the images; any discrepancies between the two radiologists were identified and adjudicated. A panel of physicians, including the QECH neurologists and the physician investigators from the team, reviewed each case when a clinical or structural abnormality was noted and categorised each identified structural abnormality as (i) clinically relevant but asymptomatic, (ii) clinically relevant and symptomatic, (iii) clinical significance unknown, and (iv) not clinically relevant. Where clinical assessments reveal an examination abnormality without an associated structural abnormality, the team reviewed the images as a group for confirmation.

Data management and analysis

A full code book was developed, and data (except for NeuroInterp) were initially entered onto paper forms before entry for importation into Epi Info for analysis. Descriptive data were presented for the prevalence and characteristics of NESS and MRI findings. Due to the range and prevalence of abnormalities identified, we conducted an analysis to identify risk factors for any brain MRI abnormality (all abnormalities combined excluding sinusitis and normal variants) as well as for risk factors for sinusitis. For age, the only continuous variable, Student's t-test was used. Otherwise, the Pearson's chi-squared test was used unless sample size required Fisher's exact test. P-values of <0.05 were considered statistically significant. The sample size of 100 was chosen because it was feasible both logistically and financially. The power yielded by a chi-squared test with 1 degree of freedom, α = 0.05 and n = 100 is 0.61, 0.89 and 0.97 for χ2 of 5, 10 and 20, respectively.

Results

  1. Top of page
  2. Abstract
  3. Introduction
  4. Methods
  5. Results
  6. Conclusions
  7. Acknowledgements
  8. References

Of 170 households screened, 102 had an eligible child. Nine of 102 screened positive on the Ten Questions for possible developmental problems. Seven had simple febrile seizures and were eligible. One child had cerebral palsy and one had epilepsy, and these were excluded. Thus, 96 eligible children were enroled. Mean age was 11.9 years, SD = 1.5 years; 42 of 96 (44%) were boys. All were in school except one child whose parents reported being unable to pay school fees.

Study subject characteristics included 4 of 96 problem pregnancies (4.2%), 6 of 96 problem births (6%), 5 of 96 with a history of coma in the context of an acute illness (5%), 2 of 96 with a history of underweight status or growth problems (2%), 30 of 96 with history of prior hospitalisation (31%) and 8 of 96 with a history of prior provoked seizures (8%).

On the NESS, 6 of 96 (6%) children had clinical examination abnormalities (Table 1). These individual findings included poor fine motor control especially on the left, intellectual disability, poor fine motor and balance, saccadic smooth pursuit and vestibulo-ocular reflex (VOR), isolated saccadic smooth pursuits and poor coordination of left hand.

Table 1. Abnormalities identified by the neurologic examination for subtle signs (n = 96)
Subject IDFinding
BR009Poor fine motor control especially on the left
BR044Intellectual disability
BR063Poor fine motor and balance
BR064Saccadic smooth pursuit and saccadic vestibulo-ocular reflex
BR070Saccadic smooth pursuits
BR073Poor coordination of left hand

No acute MRI changes were seen. A normal variant MRI was seen in 5 of 96 (5%) (Table 2). Radiographic evidence of sinusitis was the most common finding – occurring in 28 (29.2%) children. Abnormal brain structures were found in 16 of 96 (17%) children and comprised the following: mild diffuse atrophy, mild periventricular white matter changes/gliosis, multifocal punctuate subcortical white matter changes, vermian atrophy and empty sella, and multifocal granulomas with surrounding gliosis (Table 3). Having an abnormal MRI was not associated with age, sex, history of problem pregnancy, history of problem birth, history of illness with coma, history of growth/weight problems, history of prior hospitalisation, history of seizures, abnormal physical exam or housing quality (Table 4).

Table 2. Normal variant brain MRI findings (n = 96)
Subject IDMRI Finding
BR041Peritrigonal cyst
BR0153 mm left peritrigonal cyst
BR079Posterior fossa (3.5 cm) arachnoid cyst
BR068Left temporal (3 cm) arachnoid cyst
BR032Bilateral hippocampal cystic changes (right > left)
BR063Cavum septum pellucidum
BR095Cavum septum pellucidum
Table 3. Brain MRI abnormalities identified (n = 96)
Subject IDMRI finding
BR001Vermian atrophy and empty sella
BR004Mild diffuse atrophy
BR005Periventricular white matter changes (mild – moderate) and mild diffuse atrophy
BR007Empty sella
BR012Periventricular white matter changes (mild)
BR022Mild diffuse atrophy
BR027Periventricular white matter changes (mild) and multifocal punctate subcortical white matter changes
BR032Mild diffuse atrophy
BR034Periventricular white matter changes (mild)
BR036Empty sella
BR039Right hippocampal cystic changes with surrounding gliosis
BR048Periventricular white matter changes (mild – moderate)
BR051Empty sella
BR073Very small right frontal white matter cystic focus with high T2 signal
BR084Periventricular white matter changes (mild – moderate) and multifocal punctate subcortical white matter changes
BR095Cystic lesion and solid areas of localised oedema consistent with a granulomatous process
Table 4. Risk factor analysis for brain MRI abnormalities
CharacteristicsAbnormal MRI (n = 15)Normal MRI (n = 81)P-value
Age12.1 (mean years)11.9 (mean years)0.71
Sex (male)8 (53%)34 (42%)0.42
History of problem pregnancy04 (5%)0.76
History of problem birth2 (13%)4 (5%)0.23
History of illness with coma1 (14%)4 (5%)0.32
History of growth/weight problems02 (3%)0.71
History of Hospitalisation5 (33%)25 (31%)0.53
History of seizure2 (13%)6 (7%)0.36
Abnormal NESS1 (7%)6 (7%)0.70
Housing quality7.56.30.23

Factors evaluated for an association with the radiographic evidence of sinusitis were age, sex, history of growth/weight problems, housing quality and fuel for cooking (electricity, charcoal or wood) (Table 5). None showed significance, but trends were seen in fuel for cooking with the use of charcoal or wood being associated with higher rates of sinusitis.

Table 5. Risk factor analysis for radiographic sinusitis
CharacteristicsSinusitisNo sinusitisP-value
Age (mean)11.9 (SD 1.5)12.6 (SD 1.5)0.26
Sex (male)3 (43%)39 (44%)0.28
History of growth/weight problems02 (2%)0.86
Housing quality (mean score)6.5 (SD 3.7)4.6 (SD 3.4)0.28
Fuel for cooking (n = 95)0.62
Electricity1 (3.6%)3 (4.5%) 
Charcoal19 (67.9%)51 (76.1%)
Wood8 (28.6%)13 (19.4%)

Conclusions

  1. Top of page
  2. Abstract
  3. Introduction
  4. Methods
  5. Results
  6. Conclusions
  7. Acknowledgements
  8. References

Many of the impressive advances in the clinical and basic neurosciences over the past two decades were made possible through ever-evolving imaging technologies. Critical advances in treatments for common conditions (e.g. disease-modifying agents for multiple sclerosis, ‘clot busters’ for acute stroke and more refined surgical resections for epilepsy) are predicated on access to imaging. As imaging becomes more available, at least at a small minority of research facilities in low-income tropical settings, MRI technology may offer critical insights into the nature, progression and clinicopathologic natural history of CNS infections and infestations common in tropical and developing country settings. Neuroimaging also has the potential to allow researchers to better understand clinical differences in disease aetiology for neurological problems that are globally ubiquitous but which exhibit unique epidemiologic parameters in different geographical settings.

A substantial proportion of healthy Malawian children have evidence of structural brain abnormalities in the absence of clinical symptoms. These included atrophy and empty sella. Radiographic ‘sinusitis’ with no clinical correlate is also common. To our knowledge, these are the first normative brain MRI data from Africa and the first report of incidental findings from an African population. Incidental findings in healthy individuals have been reported from Western populations. A study of 2536 young men in the German military found low rates of abnormalities such as arachnoid cysts in 1.7% and vascular abnormalities and intracranial tumours in 0.5% (Weber, 2006). A review of 1000 MRIs obtained from healthy volunteers participating in research at the US National Institute of Health in Bethesda, MD included mostly adults. Incidental findings were dominated by age-related changes but did include sinusitis in 13.2%. (Katzman et al. 1999). Among paediatric populations, a study of 225 children in California also identified sinusitis as being a common finding – seen in 9.3% of children (Kim, 2002). None of the children in this California-based sample exhibited atrophy and white matter abnormalities seen in our Malawian cohort, suggesting that a factor or factors innate to Malawi may be the underlying cause.

This study is primarily limited by the small sample size and the field strength of the MRI. Due to the limited number of individuals with any specific MRI abnormality, we had limited power to identify risk factors for specific abnormalities. Furthermore, the MRI field strength may have led to an underestimation of structural abnormalities further limiting our analytic capacity. Patients were selected using a snowball sampling mechanism based upon the households of children from a prior (cerebral malaria) study who were admitted to the hospital with cerebral malaria. The 80/20 urban/rural distribution of the sample population in the Brain imaging in normal kids (BRINK) study reflects the QECH Blantyre referral population, but this was not a systematic, population-based sample. The sampling frame may have favoured children from areas with more expeditious hospital referral routes or it may have preferentially selected for children residing in more malarial regions. Nonetheless, this report provides important normative data for clinicians and researchers using neuroimaging in Malawi and similar regions.

Incidental brain MRI abnormalities are common in normal Malawian children. The incidental atrophy and white matter abnormalities seen in this African population have not been reported among incidental findings from US populations, suggesting Malawi-specific exposures may be the cause.

Acknowledgements

  1. Top of page
  2. Abstract
  3. Introduction
  4. Methods
  5. Results
  6. Conclusions
  7. Acknowledgements
  8. References

We thank Monica Sapuwa and Clara Antonio whose contributions made this work possible. We are grateful to the children and their parents who took part in the study. The Malawi MRI unit and staff provided essential support for this study, and General Electric Healthcare donated the Signa Ovation MRI used in this study. The project was supported by an award from the National Institute of Neurological Disorders and Stroke (R21NS069228). The content is solely the responsibility of the authors and does not necessarily represent the official views of the National Institute of Neurological Disorders and Stroke or the National Institutes of Health.

References

  1. Top of page
  2. Abstract
  3. Introduction
  4. Methods
  5. Results
  6. Conclusions
  7. Acknowledgements
  8. References
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