Treatment Limitations for Pediatric Diffuse Intrinsic Pontine Gliomas in a Middle-Income Country

Pablo E. Baquero-Herrera; Manuel A. Ardila-Martínez; Nadín J. Abdalá-Vargas; Jorge Racedo; Edgar G. Ordóñez-Rubiano

doi:10.1055/s-0042-1745714

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Brief Report

13 (

); 515-520

doi:

10.1055/s-0042-1745714

Treatment Limitations for Pediatric Diffuse Intrinsic Pontine Gliomas in a Middle-Income Country

Pablo E. Baquero-Herrera¹, Manuel A. Ardila-Martínez^1,2, Nadín J. Abdalá-Vargas^1,2, Jorge Racedo³, Edgar G. Ordóñez-Rubiano^2,4,5

1Department of Neurosurgery, Hospital Infantil Universitario de San José, Fundacion Universitaria de Ciencias de la Salud (FUCS), Bogotá, Colombia

2Department of Neurosurgery, Hospital de San José – Sociedad de Cirugía de Bogotá, Fundación Universitaria de Ciencias de la Salud (FUCS), Bogotá, Colombia

3microscopIA Research Group, microscopIA, Bogotá, Colombia

4Department of Biomedical Engineering, Universidad de Los Andes, Bogotá, Colombia

5Research Institute, Fundación Universitaria de Ciencias de la Salud (FUCS), Bogotá, Colombia

Address for correspondence Edgar G. Ordóñez-Rubiano, MD Department of Neurological Surgery, Hospital de San José Calle 10 # 18-75, Bogotá 110111 Colombia egordonez@fucsalud.edu.co

Epub ahead of print: 2022-06-08, Published: 2022-08-07

Journal of Neurosciences in Rural Practice

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This is an open access article published by Thieme under the terms of the Creative Commons Attribution-NonDerivative-NonCommercial License, permitting copying and reproduction so long as the original work is given appropriate credit. Contents may not be used for commercial purposes, or adapted, remixed, transformed or built upon. (https://creativecommons.org/licenses/by-nc-nd/4.0/)

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This article was originally published by Thieme Medical and Scientific Publishers Pvt. Ltd. and was migrated to Scientific Scholar after the change of Publisher.

Abstract

Objectives To evaluate the surgical management outcomes in pediatric patients with diffuse intrinsic pontine gliomas (DIPGs) who underwent intended biopsies and partial resections in a middle-income country, highlighting the barriers and challenges of these procedures for further investigation.

Methods A retrospective review of a prospective acquired series of patients who underwent biopsy or resection for DIPG between January 2012 and June 2018 at our institution was performed.

Results A total of 43 patients with posterior fossa tumors were identified. From these, seven pediatric DIPG cases were enrolled. Five were males. The median age was 5 years (range: 1–12 years). Only one patient (14.3%) had a ganglioglioma, while the others presented pilocytic and diffuse astrocytomas. Two (28.6%) patients had an intentional biopsy, and the other five (71.4%) had a partial resection. In the three (28.6%) patients who presented with associated hydrocephalus, the endoscopic third ventriculostomy was performed in the same surgical time. The median preoperative Lansky play-performance scale (LPPS) was 80 (range: 60–100), while the median postoperative LPPS was 23 (range: 7–52).

Conclusion A decrease in overall survival was noted compared with data reported in other series. Multifactorial barriers were discussed including the social, geographic, and economic features that may influence on final outcomes.

Keywords

brain stem

neurosurgeon

pediatric

diffuse intrinsic pontine glioma

Show Related Articles from PubMed

Introduction

Diffuse intrinsic pontine gliomas (DIPGs) are high-grade brain stem gliomas accounting for ∼10 to 20% of all pediatric brain tumors.1 Annually ∼200 to 300 children are diagnosed with DIPG in the United States. DIPG typically occurs between 6 and 9 years of age.2 It is the leading cause of childhood mortality due to central nervous system (CNS) malignancies with a median overall survival (OS) ranging from 8 to 12 months. More than 50% of patients experience cranial nerve, cerebellar, and long tract impairments. DIPG diagnosis is challenging; although biopsy or resection allows a histopathological classification, deciding whether to perform an invasive approach or not must be made on a case-by-case manner. Currently, a discussion remains on the feasibility and safety of a brain stem biopsy, arguing the benefit of molecular characterization for management, reducing the mortality rate, potential drug discovery, and investigation purposes against patients' risks. Besides those cases when an intentional biopsy is indicated, diagnosis may be conducted through only imaging criteria, laboratories, and a detailed clinical history. MRI reaches overall sensitivity of 94% and has proven its utility for tumor classification and prognosis.3 4 5 6 Furthermore, the imaging-based diagnosis and clinical history still face significant variations among neurosurgeons and neuro-oncologists, rekindling the debate on stereotactic biopsy when diagnosing and deciding further treatment.7

Management decision keeps evolving as more biomarkers and molecular research are conducted to develop targeted therapies.7 However, advances in treatment have not reached a meaningful improvement in OS and no curative options are available yet.8 This case series aim to evaluate the surgical management outcomes in pediatric patients with DIPG through a retrospective review of a prospective acquired cases series including biopsies and intended partial resections in a middle-income country (MIC), highlighting the barriers and challenges of these procedures for further investigation.

Methods

A retrospective review of the electronic medical records of patients who underwent biopsy or resection for DIPG between January 2012 and June 2018 at the Hospital Infantil Universitario de San José, Bogotá, Colombia was performed. Data corresponded to procedures performed by a dedicated pediatric neurosurgeon (P.E.B.). Database review was performed based on surgical codes. The exclusion criteria included: aged 18 or older, brain tumors different from DIPG, patients diagnosed or treated previously in a different institution, and patients who underwent procedures other than biopsy or tumor resection. All procedures were performed using a freehand frameless image-guided technique. Surgical features were described previously.9 The following data were collected: sex, age, clinical presentation at diagnosis, histopathological classification, tumor localization, as well as surgical and adjuvant treatments. The primary outcomes were the postoperative Lansky play-performance scale (LPPS) for children score, hospital length of stay (LOS), and OS. Our institutional research ethics committee approved this retrospective study. Authorization was requested to our institutional ethics board to include the subjects' information in this study, preserving their identity in analyzing the data and all images presented. Given the retrospective nature of this study, the ethics committee considered a low risk from this research for the patients and no informed consents were required for this study accordingly.

Results

A total of 43 patients with posterior fossa tumors were identified. From these, seven pediatric DIPG cases were enrolled. Patients included five males and two females with a median age of 5 years (range: 1–12 years). Symptoms preceded diagnosis by a median of 42 weeks (range: 1–108 weeks). New daily persistent headache was the most common reason for consultation, experienced by four patients (42.9%). Other features at admission included nausea and vomiting, upper limb paresis, hemiparesis, hemisensory syndrome, cyanotic breath-holding spells, psychomotor developmental delay, diplopia, dysconjugate gaze, and blepharoptosis. Besides previous features, hydrocephalus was reported in three patients (42.9%). Diagnosis was initially based on imaging criteria in all cases. All patients presented a diagnosis of low-grade glioma. Only one patient (14.3%) had a ganglioglioma, while the others presented pilocytic and diffuse astrocytomas. Complete immunophenotype report was only available for patients 1 and 5. Patient 1 presented positivity for glial fibrillary acidic protein (GFAP) and epithelial membrane antigen (EMA), while patient 5 presented positivity for GFAP, oligodendrocyte transcription factor 2, and synaptophysin and S-100 protein. For the remaining cases, the sample was insufficient to process additional immunophenotype data. Table 1 summarizes the clinical features of the patients.

Table 1

Clinical characteristics of patients with DIPG

Patient	Sex	Age (y)	Clinical presentation	Location	Hydrocephalus	Histopathological classification	Nonsurgical treatment
1	F	11	Headache	Lower medulla	No	Pilocytic astrocytoma	Chemotherapy Radiotherapy
2	M	12	Headache Nausea and vomiting	Pons	No	Low-grade astrocytoma	Chemotherapy Radiotherapy
3	M	1	Upper limb paresis Hemisensory syndrome	Lower medulla	No	Pilocytic astrocytoma	Radiotherapy
4	M	4	Cyanotic breath-holding spells Psychomotor developmental delay	Lower medulla	No	Diffuse astrocytoma	Chemotherapy Radiotherapy
5a	F	5	Headache	Pons	Yes	Ganglioglioma	Radiotherapy
6a	M	12	Diplopia Dysconjugate gaze Third cranial nerve palsy	Posterior midbrain	Yes	Diffuse astrocytoma	Radiotherapy
7a	M	4	Hemiparesis	Midbrain	Yes	Diffuse astrocytoma	Radiotherapy

Abbreviation: DIPG, diffuse intrinsic pontine glioma.

a Documented hydrocephalus.

Two (28.6%) patients had an intentional biopsy, and the other five (71.4%) had a partial resection. In the three (28.6%) patients who presented with associated hydrocephalus, the tumor biopsy/resection and an additional endoscopic third ventriculostomy were performed in the same surgical time. Regarding nonsurgical treatment, three (28.6%) patients received chemotherapy and radiotherapy, while the other four (57.1%) only received radiotherapy based on the pediatric oncologist recommendation. In general, there was an overall decrease in the LPPS after both biopsy and partial resection. The median preoperative LPPS was 80 (range: 60–100), while the median postoperative LPPS was 23 (range: 7–52); there was a median reduction of 10 points in the LPPS (range: 10–40). The median medical LOS was 18 days (range: 6–35 days), and six (85.7%) patients required postoperative care in the pediatric intensive care unit (ICU), with a median ICU stay of 3 days (range: 1–8 days). Median survival was 23 days (range: 7–52 days). Table 2 summarizes the surgical outcomes of each patient and the corresponding follow-up.

Table 2

Surgical management and clinical outcomes of patients with DIPG

Patient	Type of surgery	Surgical approach	Tumor volume (mL)	Medical LOS (d)	ICU LOS (d)	Preoperative LPPS score	Postoperative LPPS score	Survival (d)
1	Partial resection	Far lateral	2.81	9	2	100	90	43
2	Partial resection	Far lateral	4.54	23	1	60	50	52
3	Partial resection	Far lateral	10.18	6	4	70	60	22
4	Partial resection	Retrosigmoid	6.39	18	0	80	60	7
5	Partial resection	Retrosigmoid and ETV	24.02	17	1	80	60	23
6	Intentional biopsy	Ventricular biopsy and ETV	21.29	35	8	90	50	50
7	Intentional biopsy	Ventricular biopsy and ETV	21.74	18	4	70	60	20

Abbreviations: DIPG, diffuse intrinsic pontine glioma; ETV, endoscopic third ventriculostomy; ICU, intensive care unit; LOS, length of stay, LPPS, Lansky play-performance scale.

Discussion

DIPG remains the leading cause of death due to a brain tumor in pediatric patients. Despite clinical trials over the past years, OS persists low, and most children die within 2 years after diagnosis.10 Symptoms result from the mass effect and underlying dysfunction about the ventral pons. Major critical pathways are involved with these tumors, including nuclei and tracts of vital human functions, long pathways, and most of cranial nerves nuclei. An illustrative tractography demonstrating displacement of the ascending arousal network and the corticospinal tracts is demonstrated in Fig. 1. Consequently, major clinical deficits lead patients to a rapid functional decline and decease.

Currently, radiotherapy (standard fractionated radiation alone) remains the standard of care and multiple treatments have been investigated to achieve additional overwhelming benefit, including multiple chemotherapy and immunotherapy regimens.11 Radiotherapy alone results in temporary neurological improvement without a substantial change in OS. Surgical resection is not an option in most cases and neither provides significant improvements in OS.12 Although there is no significant advance in the surgical management of DIPG over the past decades, stereotactic biopsy has gained some attention, especially for research purposes. Obtaining samples contribute to a better understanding of the molecular basis to develop new targeted therapies.13 These protocols have led to identifying biomarkers and crucial oncogenic pathways in DIPG pathogenesis.14

As DIPG is diffusely infiltrative, complete resection results almost impossible and there is a risk for severe neurologic sequelae.15 It has been acknowledged that some selected cases may benefit from attempting resection or debulking of low-grade tumors. However, ∼8% of brain stem biopsies may result in any new-onset deficit.16 A meta-analysis including 735 stereotactic biopsies for pediatric brain stem tumors reported 6.7% for overall morbidity, 0.6% for permanent morbidity, and 0.6% for mortality.17 However, as the treatment of DIPG is radiotherapy alone in many centers worldwide, this study contributes with five cases in which partial resection was intended, and the outcomes were assessed.

Challenges and Barriers for DIPG Treatment in a MIC Setting

Despite multiple efforts made to improve outcomes of DIPG patients worldwide, there is lack of consensus of a standard treatment protocol.18 Additionally, a big concern remains of DIPG treatment in MICs, where multiple limitations influence on the final outcome.19 DIPG remains an orphan disease in MICs, and the registry and documentation of the evolution of the disease is scarce.

From these five cases with partial resection, OS was considerably lower than reported from a DIPG biopsy where median OS has been estimated between 6 and 14 months after the procedure.20 Both subgroups, partial resection and biopsy experienced an overall reduction in the LPPS. A higher decline in LPPS may be appreciated in those patients with partial resection. Due to the number of patients recorded in this series, no firm conclusions could be drawn between the clinical outcomes between biopsy and intended resection. Final outcomes are related to a multifactorial environment including the middle-income economy of the health care system, the poor education of the parents, and the evident low access to pediatric neurosurgeons.

To note, the access to pediatric reference centers is limited in MICs and a delayed attention to CNS malignancies is not infrequent in this scenario. Unfortunately, the impact of a delayed consultation is reflected directly on the OS and immediate postoperative outcome. In terms of litigations in our country, radiotherapy is restricted only to patients with confirmed histopathological diagnosis and, consequently, to initiate adjuvant treatment, a biopsy or an intended resection is always required. In addition, 2 to 3 weeks after sample acquisition are needed to establish a definite diagnosis of DIPG. Usually, the samples are insufficient for running all complementary tests. This study was performed before the access to molecular studies was available in our setting. In further cases, the molecular profile will help physicians in MICs to approach in a holistic personalized manner, the targeted therapies to improve OS.

Additional to the limited resources, neurosurgeons and patients' families face the limited access to pediatric clinical oncologists and radiotherapeutic oncologists. The poor networking among specialties also limits the multidisciplinary treatment needed for this complex entity and lead to a poorer prognosis. Data concerning outcomes and epidemiology of DIPGs are restricted for MICs, probably as a consequence of lack of data given the high probability to die during this long process before treatment of even before an initial medical consultation.

Regarding surgical treatment, availability for renting neuronavigation systems and the access to advanced neuroimaging including diffusion tensor imaging have allowed some progress aiming to reduce neurological decline after procedures.9 Most likely, rapid progression of disease is produced by the notable advanced stages when these tumors are detected and not directly related to the procedure itself. We hope this case series will add remarkable information and will promote the initiative to improve clinical care of this neglected disease in MICs.

Study Limitations

The limited number of cases as well as the retrospective nature of this study represent the most remarkable limitations. However, even with few cases, the information is an important basis for further epidemiological characterization of the disease. No data in regard to epigenetics are described given the lack of institutions and equipment for processing.

Conclusion

A case series of patients with DIPG in a MIC is presented. A decrease in OS was noted compared with data reported in other series. Multifactorial barriers were discussed including the social, geographic, economic, and education features that may influence on the final outcomes of patients. Pediatric neurosurgeons are encouraged to describe other limitations and clinical features in other MICs that may help understand problematics and make an improvement of DIPG treatment.

Conflict of Interest

None declared.

Funding None.

References

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[Google Scholar]
Fisher P. G., Breiter S. N., Carson B. S., et al . A clinicopathologic reappraisal of brain stem tumor classification. Identification of pilocystic astrocytoma and fibrillary astrocytoma as distinct entities. Cancer. 2000;89(7):1569-1576.
[Google Scholar]
Broniscer A, Laningham F. H., Kocak M, et al . Intratumoral hemorrhage among children with newly diagnosed, diffuse brainstem glioma. Cancer. 2006;106(6):1364-1371.
[Google Scholar]
Cage T. A., Samagh S. P., Mueller S, et al . Feasibility, safety, and indications for surgical biopsy of intrinsic brainstem tumors in children. Childs Nerv Syst. 2013;29(8):1313-1319.
[Google Scholar]
Pfaff E, El Damaty A, Balasubramanian G. P., et al . Brainstem biopsy in pediatric diffuse intrinsic pontine glioma in the era of precision medicine: the INFORM study experience. Eur J Cancer. 2019;114:27-35.
[Google Scholar]
Schumacher M, Schulte-Mönting J, Stoeter P, Warmuth-Metz M, Solymosi L, . Magnetic resonance imaging compared with biopsy in the diagnosis of brainstem diseases of childhood: a multicenter review. J Neurosurg. 2007;106:111-119. (2, Suppl):
[Google Scholar]
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[Google Scholar]
Khatua S, Zaky W, . Diffuse intrinsic pontine glioma: time for therapeutic optimism. CNS Oncol. 2014;3(5):337-348.
[Google Scholar]
Ordóñez-Rubiano E. G., Valderrama-Arias F. A., Forbes J. A., et al . Identification of preoperative language tracts for intrinsic frontotemporal diseases: a pilot reconstruction algorithm in a middle-income country. World Neurosurg. 2019;125:e729-e742.
[Google Scholar]
Hargrave D, Bartels U, Bouffet E, . Diffuse brainstem glioma in children: critical review of clinical trials. Lancet Oncol. 2006;7(3):241-248.
[Google Scholar]
Srikanthan D, Taccone M. S., Van Ommeren R, Ishida J, Krumholtz S. L., Rutka J. T., . Diffuse intrinsic pontine glioma: current insights and future directions. Chin Neurosurg J. 2021;7(1):6.
[Google Scholar]
Frazier J. L., Lee J, Thomale U. W., Noggle J. C., Cohen K. J., Jallo G. I., . Treatment of diffuse intrinsic brainstem gliomas: failed approaches and future strategies. J Neurosurg Pediatr. 2009;3(4):259-269.
[Google Scholar]
Williams J. R., Young C. C., Vitanza N. A., et al . Progress in diffuse intrinsic pontine glioma: advocating for stereotactic biopsy in the standard of care. Neurosurg Focus. 2020;48(1):E4.
[Google Scholar]
Lapin D. H., Tsoli M, Ziegler D. S., . Genomic insights into diffuse intrinsic pontine glioma. Front Oncol. 2017;7:57.
[Google Scholar]
Mathew R. K., Rutka J. T., . Diffuse intrinsic pontine glioma: clinical features, molecular genetics, and novel targeted therapeutics. J Korean Neurosurg Soc. 2018;61(3):343-351.
[Google Scholar]
Hersh D. S., Kumar R, Moore K. A., et al . Safety and efficacy of brainstem biopsy in children and young adults. J Neurosurg Pediatr. 2020;26(5):552-562.
[Google Scholar]
Hamisch C, Kickingereder P, Fischer M, Simon T, Ruge M. I., . Update on the diagnostic value and safety of stereotactic biopsy for pediatric brainstem tumors: a systematic review and meta-analysis of 735 cases. J Neurosurg Pediatr. 2017;20(3):261-268.
[Google Scholar]
Lian X, Kats D, Rasmussen S, et al . Design considerations of an IL13Rα2 antibody-drug conjugate for diffuse intrinsic pontine glioma. Acta Neuropathol Commun. 2021;9(1):88.
[Google Scholar]
Ezzat S, Kamal M, El-Khateeb N, et al . Pediatric brain tumors in a low/middle income country: does it differ from that in developed world? J Neurooncol. 2016;126(2):371-376.
[Google Scholar]
Wang Z. J., Rao L, Bhambhani K, et al . Diffuse intrinsic pontine glioma biopsy: a single institution experience. Pediatr Blood Cancer. 2015;62(1):163-165.
[Google Scholar]

Introduction

Methods

Results

Discussion

Conclusion

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[1] Janjua M. B., Ban V. S., El Ahmadieh T. Y., et al . Diffuse intrinsic pontine gliomas: diagnostic approach and treatment strategies. J Clin Neurosci. 2020;72:15-19.
[Google Scholar]

[2] Fisher P. G., Breiter S. N., Carson B. S., et al . A clinicopathologic reappraisal of brain stem tumor classification. Identification of pilocystic astrocytoma and fibrillary astrocytoma as distinct entities. Cancer. 2000;89(7):1569-1576.
[Google Scholar]

[3] Broniscer A, Laningham F. H., Kocak M, et al . Intratumoral hemorrhage among children with newly diagnosed, diffuse brainstem glioma. Cancer. 2006;106(6):1364-1371.
[Google Scholar]

[4] Cage T. A., Samagh S. P., Mueller S, et al . Feasibility, safety, and indications for surgical biopsy of intrinsic brainstem tumors in children. Childs Nerv Syst. 2013;29(8):1313-1319.
[Google Scholar]

[5] Pfaff E, El Damaty A, Balasubramanian G. P., et al . Brainstem biopsy in pediatric diffuse intrinsic pontine glioma in the era of precision medicine: the INFORM study experience. Eur J Cancer. 2019;114:27-35.
[Google Scholar]

[6] Schumacher M, Schulte-Mönting J, Stoeter P, Warmuth-Metz M, Solymosi L, . Magnetic resonance imaging compared with biopsy in the diagnosis of brainstem diseases of childhood: a multicenter review. J Neurosurg. 2007;106:111-119. (2, Suppl):
[Google Scholar]

[7] Hankinson T. C., Campagna E. J., Foreman N. K., Handler M. H., . Interpretation of magnetic resonance images in diffuse intrinsic pontine glioma: a survey of pediatric neurosurgeons. J Neurosurg Pediatr. 2011;8(1):97-102.
[Google Scholar]

[8] Khatua S, Zaky W, . Diffuse intrinsic pontine glioma: time for therapeutic optimism. CNS Oncol. 2014;3(5):337-348.
[Google Scholar]

[9] Ordóñez-Rubiano E. G., Valderrama-Arias F. A., Forbes J. A., et al . Identification of preoperative language tracts for intrinsic frontotemporal diseases: a pilot reconstruction algorithm in a middle-income country. World Neurosurg. 2019;125:e729-e742.
[Google Scholar]

[10] Hargrave D, Bartels U, Bouffet E, . Diffuse brainstem glioma in children: critical review of clinical trials. Lancet Oncol. 2006;7(3):241-248.
[Google Scholar]

[11] Srikanthan D, Taccone M. S., Van Ommeren R, Ishida J, Krumholtz S. L., Rutka J. T., . Diffuse intrinsic pontine glioma: current insights and future directions. Chin Neurosurg J. 2021;7(1):6.
[Google Scholar]

[12] Frazier J. L., Lee J, Thomale U. W., Noggle J. C., Cohen K. J., Jallo G. I., . Treatment of diffuse intrinsic brainstem gliomas: failed approaches and future strategies. J Neurosurg Pediatr. 2009;3(4):259-269.
[Google Scholar]

[13] Williams J. R., Young C. C., Vitanza N. A., et al . Progress in diffuse intrinsic pontine glioma: advocating for stereotactic biopsy in the standard of care. Neurosurg Focus. 2020;48(1):E4.
[Google Scholar]

[14] Lapin D. H., Tsoli M, Ziegler D. S., . Genomic insights into diffuse intrinsic pontine glioma. Front Oncol. 2017;7:57.
[Google Scholar]

[15] Mathew R. K., Rutka J. T., . Diffuse intrinsic pontine glioma: clinical features, molecular genetics, and novel targeted therapeutics. J Korean Neurosurg Soc. 2018;61(3):343-351.
[Google Scholar]

[16] Hersh D. S., Kumar R, Moore K. A., et al . Safety and efficacy of brainstem biopsy in children and young adults. J Neurosurg Pediatr. 2020;26(5):552-562.
[Google Scholar]

[17] Hamisch C, Kickingereder P, Fischer M, Simon T, Ruge M. I., . Update on the diagnostic value and safety of stereotactic biopsy for pediatric brainstem tumors: a systematic review and meta-analysis of 735 cases. J Neurosurg Pediatr. 2017;20(3):261-268.
[Google Scholar]

[18] Lian X, Kats D, Rasmussen S, et al . Design considerations of an IL13Rα2 antibody-drug conjugate for diffuse intrinsic pontine glioma. Acta Neuropathol Commun. 2021;9(1):88.
[Google Scholar]

[19] Ezzat S, Kamal M, El-Khateeb N, et al . Pediatric brain tumors in a low/middle income country: does it differ from that in developed world? J Neurooncol. 2016;126(2):371-376.
[Google Scholar]

[20] Wang Z. J., Rao L, Bhambhani K, et al . Diffuse intrinsic pontine glioma biopsy: a single institution experience. Pediatr Blood Cancer. 2015;62(1):163-165.
[Google Scholar]

Treatment Limitations for Pediatric Diffuse Intrinsic Pontine Gliomas in a Middle-Income Country

Abstract

Abstract

Keywords

brain stem

neurosurgeon

pediatric

diffuse intrinsic pontine glioma

Introduction

Methods

Results

Discussion

Challenges and Barriers for DIPG Treatment in a MIC Setting

Study Limitations

Conclusion

Conflict of Interest

References

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