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Introduction
Spinal cord tumors are rare in adults and occur at a considerably lower frequency in children. The proportion between spinal cord and intracranial tumors described in the pediatric population varies from 1:4.8 to 1:20, depending on the series reviewed1. Incidence of spinal cord tumors in high-income countries such as the United States is 1 case/100,000 children2, mainly affecting scholars and adolescents3,4. These tumors can arise from the spinal cord or from the adjacent structures, and according to their location, they can be classified as intra- or extradural. Moreover, intradural tumors are divided into intramedullary and extramedullary5.
The current literature describes that two-thirds of the total spinal cord neoplasia occurring in children are extradural. These include bone tumors, tumors of the epidural space, and extraspinal tumors that invade such space. On the other hand, 35% of the spinal cord tumors in pediatric patients are intramedullary, representing 4-6% of the total central nervous system neoplasia6. Astrocytoma, ganglioma, and ependymoma are the histological subtypes most frequently observed in the intramedullary location2. Such tumors often localize at cervical and thoracic levels of the spinal cord in almost 50% of the cases, being less frequently observed at lumbar segments7,8. Finally, intradural extramedullary neoplasia is rare and most of them are leptomeningeal metastasis from brain tumors9.
Most of what it is currently known about epidemiology and clinical characteristics of spinal cord tumors in children comes from series in Caucasians. However, few studies have described the clinical behavior of these tumors in other populations. In developing countries like Mexico, there are only few reports of spinal cord tumor in children10-12, some of which were published before the advent and availability of novel brain imaging tools currently used for the diagnostic and surgical approach of these neoplasia10,11. Therefore, it is of major relevance to have updated information about the frequency, clinical behavior, diagnostic tools, surgical strategies, and post-operative clinical outcomes of spinal cord tumors in our children population. Here, we report our experience in the management of spinal cord tumors by reviewing the clinical registries of children that attended and were regularly followed at the Department of Neurosurgery of the Pediatric Hospital of Mexico, a third-level National Reference Center in Mexico City. We believe that our clinical description contributes to the knowledge of spinal cord tumors in Hispanic children and provides valuable data for future studies aimed to compare the clinical behavior of spinal cord tumors among pediatrics with different ethnic backgrounds.
Methods
We conducted a retrospective review of the clinical and radiological database of the Pediatric Hospital of Mexico "Federico Gomez," looking for clinical cases of children with spinal cord tumors that attended and were regularly followed at our center during the period from 1985 to 2015. Demographic, clinical, and imaging data from participants were retrieved from the database of our hospital. The collected information included relevant neurological manifestations, anatomical location and histological subtype of the tumors, category of imaging tools used for the diagnosis, surgical approaches employed for tumor resection, and post-operative clinical outcomes. Descriptive statistics were used to clinically characterize the study population. Frequencies and proportions were calculated for categorical data. Means, medians, and standard deviations were used for continuous data. Calculations for descriptive statistics were performed using GraphPad Prism v5 (La Jolla, CA, USA). The study was approved by the Ethics Committee of our institution and was conducted with strict adherence to the Official Mexican Law NOM-012-SSA3-2012 that establishes the criteria for the execution of health research projects in humans.
Results
Participants' characteristics
A total of 45 children with spinal cord tumors were included in the study. Their mean age at diagnosis was 8.75 years (range 5 months-17 years). The most ancient case occurred 31 years before the conduction of the current study. From these, 28 patients were male (62.22%) and 17 female (37.77%), with a male/female ratio of 1.64:1. The age group with the highest incidence of spinal cord tumors was composed of school-age children with 19 cases (42.22%), followed by adolescents (13 cases, 28.88%), pre-scholars (9 cases, 20%), and infants (4 cases, 8.88%). All the patients were born in Mexico and their parents referred themselves as belonging to the Mexican Mestizo race. The clinical and demographic characteristics of participants are summarized in Table 1.
Table 1 Clinical characteristics of Hispanic children with spinal cord tumors
| Variable | n = 45 |
|---|---|
| Age at onset, mean (range) | 8.75 (0.5-17) |
| Gender | |
| Male, n (%) | 28 (62.22) |
| Female, n (%) | 17 (37.77) |
| Male/female ratio | 1.64:1 |
| Age group | |
| Infants, n (%) | 4 (8.88) |
| Pre-scholars, n (%) | 9 (20) |
| School-age children, n (%) | 19 (42.22) |
| Adolescents, n (%) | 13 (28.88) |
| Clinical findings before surgical management | |
| Motor deficit, n (%) | 44 (97.77) |
| Pain, n (%) | 39 (86.66) |
| Pain referred to the corresponding dermatomes, n (%) | 36 (80) |
| Radicular pain, n (%) | 3 (6.66) |
| Hypoesthesia, n (%) | 38 (84.44) |
| Dysesthesia, n (%) | 25 (55.55) |
| Paresthesia, n (%) | 13 (28.88) |
| Urinary incontinency, n (%) | 29 (64.44) |
| Abnormal gait, n (%) | 16 (35.55) |
| Fecal incontinence, n (%) | 10 (22.22) |
| Scoliosis, n (%) | 18 (40) |
| Kyphoscoliosis, n (%) | 6 (13.33) |
| Falls, n (%) | 6 (13.33) |
| Cervical stiffness, n (%) | 6 (13.33) |
| Muscle contractures, n (%) | 6 (13.33) |
| Hyperreflexia, n (%) | 6 (13.33) |
| Clonus, n (%) | 6 (13.33) |
| Atrophy of muscles of the hands, n (%) | 6 (13.33) |
| Hydrocephalus, n (%) | 4 (8.88) |
| Headache, n (%) | 4 (8.88) |
| Seizures, n (%) | 4 (8.88) |
Tumors location and histological subtype
Intramedullary tumors were the most frequent lesions affecting our population, representing the 44.44% of the cases (20 patients) followed by extradural and intradural extramedullary tumors with 18 (40%) and 7 (15.55%) cases, respectively. In addition, six cases of intramedullary lesions were holocordal neoplasia (13.33%). All cases received histopathological diagnosis. Independently of the tumors' location, astrocytoma was the most frequent histological subtype, followed by primitive neuroectodermal tumors (PNETs), ependymoma, meningioma, and metastases. The frequency and anatomical localization of the different histological subtypes of spinal cord tumors observed in our series are shown in Table 2.
Table 2 Frequency and distribution of spinal cord tumors according to their anatomical location and histological subtype
| Localization/histological subtype | Frequency | % of tumors at specific localization | % from total |
|---|---|---|---|
| Intramedullary | 20 | -- | 44.44 |
| Astrocytoma | 14 | 70 | 31.11 |
| Ependymomas | 5 | 25 | 11.11 |
| Ganglioma | 1 | 5 | 2.22 |
| Extradural | 18 | -- | 40 |
| PNETs | 6 | 33.33 | 13.33 |
| Metastases | 4 | 22.22 | 8.88 |
| Sarcomas | 3 | 16.66 | 6.66 |
| Neuroblastoma | 1 | 5.55 | 2.22 |
| Lymphomas | 1 | 5.55 | 2.22 |
| Other not specified | 3 | 16.66 | 6.66 |
| Intradural extramedullary | 7 | -- | 15.55 |
| Meningiomas | 4 | 57.14 | 8.88 |
| Ependymomas | 1 | 14.28 | 2.22 |
| Schwannomas | 1 | 14.28 | 2.22 |
| Dermoid cysts | 1 | 14.28 | 2.22 |
PNETs: primary neuroectodermal tumors.
Neurological findings
The most common clinical findings observed in order of frequency were motor deficit (97.77%), pain (86.66%), urinary incontinence (64.44%), abnormal gait (35.55%), and fecal incontinence (22.22%) (Table 1). Furthermore, 53.33% of patients had alterations of the statics of the spine; 18 cases presented scoliosis (40%) and 6 had kyphoscoliosis (13.33%).
Although motor deficit was the main neurological finding, this sign occurred as the first clinical manifestation only in 22 cases (48.88%). The mean time since the presentation of the motor deficit and surgery was 4.5 months. This deficit was observed in all cases of astrocytoma and intramedullary ependymoma. Other neurological findings observed in our series, especially among patients with cervical-thoracic holocordal tumors included falls, tabetic gait, cervical stiffness, deltoid, supraspinatus, biceps and triceps muscle contractures, as well as hyperreflexia, clonus, and atrophy of intrinsic muscles of the hands.
Regarding pain, this was referred along the dermatomes corresponding to the anatomical location of the tumors in 80% of patients. This symptom was most common in patients with extradural tumors. Three patients had radicular pain (6.66%). Among children affected by cervical tumors, we observed neck pain that was exacerbated with inclination of the head to the contralateral side of the lesion. Sensory deficits manifested as hypoesthesia in 38 cases, dysesthesia in 25 patients, and paresthesia in 13 cases. These sensory alterations always occurred in the dermatomes corresponding to the location of the tumors. Urinary and fecal incontinency occurred in patients with neoplasia of the lumbosacral region or holocordal tumors. Hydrocephalus was detected in 4 cases (8.88%) and was accompanied by headache and seizures secondary to intracranial hypertension. Neurological features observed in our population are summarized in Table 1.
Diagnostic approach
From the 45 patients included in the current study, only 13 presented images of brain computerized axial tomography (computed tomography [CT]) scan and magnetic resonance imaging (MRI) at their first medical appointment. Overall, 36 patients underwent to CT scan (80%), 38 to MRI (84.44%), 27 to electromyography (60%), and 31 to evoked potentials (68.88%). In 29 cases, urodynamic studies were performed (64.44%) including 18 cases with intramedullary tumors. Furthermore, anorectal manometry was performed in 19 patients (42.22%), 11 of them with intramedullary lesions.
Surgical management
Overall, 10 patients were subjected to surgery as their only management strategy, whereas the rest received multidisciplinary oncological management, which included surgery, radiotherapy, and chemotherapy (Fig. 1A). A total of 50 surgical procedures were performed in the 45 cases included in the study (Table 3 and Fig. 1B). Laminotomy was the most frequent operative procedure used for the treatment of 28 cases (56%, n = 50) (Fig. 1C). From these, 17 were laminotomies followed by laminoplasty as previously described13,14. Furthermore, 17 laminectomies (34%) and 5 hemi-laminectomies (10%) were performed (Fig. 1D and E). In all cases, a posterior spinal approach was used. For the resection of intramedullary tumors, a classic myelotomy through microsurgical dissection was performed. Ultrasonic cavitation was used only for three cases. The interval from symptoms onset to surgery was lower than 1 month in 3 cases (6.66%), 1-6 months in 36 cases (80%), 7-12 months in 2 cases (4.44%), and higher than 12 months in 4 patients (8.88%), with an overall mean of 9.5 ± 8.5 months (Table 3).
Figure 1 Treatment approaches for pediatric patients with spinal cord tumors. A: Treatment modalities for children with spinal cord tumors. B: Surgical procedures performed for the resection of spinal cord tumors. C: Representative figure of the operative field provided by posterior laminotomy. D: Laminectomy. E: Hemi-laminectomy.
Table 3 Surgical management and post-operative outcomes in children with spinal cord tumors
| Management modality | n = 45 |
|---|---|
| Radiotherapy + chemotherapy + surgery, n (%) | 35 (77.77) |
| Only surgical resection, n (%) | 10 (22.22) |
| Interval from onset to surgery, mean (SD) | 9.5 (8.5) |
| < 1 month, n (%) | 3 (6.66) |
| 1-6 months, n (%) | 36 (80) |
| 7-12 months, n (%) | 2 (4.44) |
| > 12 months, n (%) | 4 (8.88) |
| Surgical procedure | n = 50 |
| Laminotomy, n (%) | 28 (56) |
| Laminotomy + laminoplasty, n (%) | 17 (34) |
| Laminectomy, n (%) | 17 (34) |
| Hemilaminectomy, n (%) | 5 (10) |
| Surgical outcome | n = 45 |
| Complete tumor resection, n (%) | 9 (20) |
| Subtotal tumor resection, n (%) | 36 (80) |
| Post-operative complications | |
| CSF fistula, n (%) | 9 (20) |
| Post-surgical motor deficit, n (%) | 6 (13.33) |
| New-onset urinary incontinency, n (%) | 3 (6.66) |
| Scoliosis, n (%) | 1 (2.22) |
| Hemorrhage, n (%) | 1 (2.22) |
CSF: cerebrospinal fluid; SD: standard deviation.
Post-operative clinical outcomes
A complete tumor resection, defined by negative margins after histopathological analysis, was achieved in 9 cases (20%; Table 3). From these, five cases were cervical-thoracic astrocytoma, one cervical ependymoma, one cervical PNET, and two thoracic meningioma. All these cases remained without neurological deficits and their mean survival time from onset to the last known follow-up was 10 ± 4.5 years. Thirty-six cases had a subtotal tumor resection, from which 19 (52.77%) had a favorable outcome with no aggravation of the neurological deficit nor recurrence of the tumor after a mean follow up time of 4.5 ± 2.02 years. The recurrence status was confirmed on the basis of clinical and imaging findings during the outpatient follow-up period.
The most frequent complications observed after surgery were cerebrospinal fluid fistulas in 9 cases (20%), post-surgical motor deficit in 6 cases (13.33%), new-onset urinary incontinence in 3 cases (6.66%), hemorrhage in 1 case (2.22%), and scoliosis in 1 case (2.22%). Finally, 3 dysfunctions (8.88%) occurred during the period evaluated in the current study and were caused by two anaplastic astrocytoma and one rhabdomyosarcoma.
Discussion
In the current study, we provide the first clinical description of the full spectrum of tumors affecting the spine and spinal cord in Mexican children11,12. Hence, our data may constitute relevant evidence useful for the diagnostic approach and management of spinal cord tumors in non-Caucasian Hispanic pediatric patients from Latin American populations. Based on epidemiological studies conducted at developed countries2, the incidence of pediatric spinal cord tumors in Mexico is expected to be high, considering that children have constituted a major proportion of the general population in our country during the period of time comprehended in this study. Nonetheless, only 226 cases occurring in our country, including the 45 children described here, have been formally reported in literature during the past 3 decades11,12. This suggests a high degree of underdiagnosis and subreport. Despite this, our work and previous local studies show certain similitudes and discrepancies in the clinical phenotype of Mexican Hispanic children with spinal cord tumors with respect to what is described in Caucasian series (Table 4). First, we observed a higher incidence of these tumors in male, and a predominant affection to scholars and adolescents, which have been also reported by other researchers2,10-12,15,16. Second, considering the experience of our department in the management of brain neoplasms in children (810 cases in 36 years)17, the ratio between spinal cord tumors and intracranial neoplasia derived from the present work (45 cases in 31 years) is 1:15.5 and 1:17.6 if we compare our series with the 511 brain tumors observed during 20 years in the Spanish Hospital of Mexico18. These data coincide with the ratio observed in other studies in Caucasians1; however, this information may not be accurate due to the possible local degree of underdiagnosis mentioned above.
Table 4 Clinical characteristics of spinal cord tumors in children from different regions
| Race/origin | Age at onset (years), mean | Predominant gender | Mortality (%) | Tumor localization | Histological subtype | Reference |
|---|---|---|---|---|---|---|
| Hispanic | 8.75 | Male | 8.88 | Intramedullary | Astrocytoma | Current study |
| Hispanic | -- | Male | -- | Intradural extramedullary | Dermoid cyst | 11 |
| Hispanic | 5.2 | Male | 21.7 | -- | Primary neuroectodermal tumors | 12 |
| Caucasian | 6.6 | Male | -- | Intramedullary | Dermoid tumors, epidermoid tumors, and teratomas | 15 |
| Caucasian | 8.5 | Male | 11.9 | Intramedullary | Low-grade glioma | 16 |
On the other hand, we observed a higher incidence of intramedullary lesions followed by those of extradural location in our population. In this regard, there is no consensus about the anatomical area most predominantly affected by these tumors since some studies show a higher frequency of extradural lesions16,19,20, while others describe a higher incidence of intramedullary tumors15,21-26. It is probable that factors specific to each population explain these discrepancies. Our data also confirm the previous descriptions about the most common histological type of spinal cord tumors observed in children2,9, as astrocytoma was the most incident tumor in our series regardless of their location. Furthermore, a remarkable finding derived from this work is the high frequency of extradural PNET type neoplasms occurring in our patients, which has been also reported in other Mexican series12. These tumors are conformed by undifferentiated cells, with varying degrees of pleomorphism and a slight tendency to acquire neuroectodermal characteristics27. Their incidence is extremely low, and some studies show that they represent less than 1% of all neoplasms that affect the spinal cord28. The average age at which they have been previously diagnosed is 24 years and their exact epidemiology in children remains unknown29. Thus, our data suggest that the incidence of spinal cord PNET in the pediatric population may be higher than previously thought.
The identification of spinal cord tumors in children is a major diagnostic challenge due to their rarity and unspecific clinical features. In this regard, our data, as well as previous reports30, show that a high proportion of pediatric patients with spinal cord tumors present motor deficits as their initial manifestation. Furthermore, our findings suggest that the presence of pain distributed along with a dermatome, radicular pain, hypoesthesia, paresthesia, dysesthesia, urinary and fecal incontinence, as well as gait disorders in a child otherwise healthy, should suggest the presence of a spinal cord tumor. Regarding surgical management of these lesions, we found that laminotomy by posterior approach is a safe and not deforming procedure, as previously reported13,14. Interestingly, we also observed that laminectomy caused kyphosis in only 1 of 17 patients subjected to such procedure at least until the last known follow-up, which represents a lower frequency than reported by other researchers who described that two-thirds of the subjects undergoing laminectomy developed deformity of the spine31, especially when laxity of supporting tissues was induced by the adjuvant oncological treatment32. Moreover, the occurrence of post-surgical complications in our study was low regardless of the operative approach, and fatal cases were not directly associated with the surgical resection of the tumors. Thus, our data show that pediatric patients with spinal cord tumors can receive surgical management with an acceptable low surgical morbidity.
Our study possesses all the limitations of a retrospective design in relation to the access and collection of the clinical information. In fact, we could not address the prognostic value of clinical variables and treatment approaches as most of the patients were not further followed after they reach the adulthood. Thus, our survival estimations only represent those patients that remain alive at the last known follow-up. In addition, we did not find objective quantitative evaluations of the post-operative neurological status of the patients within their clinical registries. Such information would have informed us about the effect of the surgical treatment on the neurological functionality. Finally, the fact that the current study was conducted at a single third-level medical center made us unable to perform a population-based comparison, which limited our ability to estimate the local incidence of spinal cord tumors in children and may restrict the representativeness of our data.
Conclusions
Pediatric patients with spinal cord tumors can receive surgical management with an acceptable low surgical morbidity. The clinical phenotype observed in our population has certain similitudes concerning what it is described in caucasians. This study provides a valuable clinical description of spinal cord tumors that can help in future research in non-caucasian Hispanic children.
