Brainstem Gliomas

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Practice Essentials

As the name implies, brainstem gliomas occur in the region of the brain stem. Approximately 60% of the time they are centered within the pons, but can arise from the midbrain or medulla, and can infiltrate beyond the brainstem. They account for about 20% of all pediatric primary brain tumors, but constitute less than 2% of all adult gliomas. 



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Axial T2 FLAIR MRI image showing a mass in the brainstem consistent with brainstem glioma.

Signs and symptoms

Common presenting signs and symptoms include the following:

Common clinical findings on physical examination can be summarized as constituting a triad of cranial nerve deficits, long tract signs, and ataxia (of trunk and limbs). Papilledema may be seen. Sixth and seventh cranial nerves are involved commonly. Facial sensory loss and a primary-position, upbeating nystagmus may be seen. Crossed deficits (facial signs and symptoms contralateral to arm/leg signs and symptoms) are also characteristic of brainstem gliomas.

Certain manifestations suggest specific tumor locations, as follows:

Patients with tectal lesions may present with the following:

Patients with cervicomedullary lesions may present with the following:

See Clinical Presentation for more detail.

Diagnosis

The workup for brainstem gliomas may include the following:

Lab studies of blood chemistry and related body fluids are not helpful as a rule. Tissue confirmation is recommended, but sometimes not feasible.

See Workup for more detail.

Management

Treatment of brainstem gliomas may comprise the following:

Observation alone may be considered for some adult patients with the following:

Focal radiotherapy

Chemotherapy

Surgical resection

Surgical therapy is performed in conjunction with radiation therapy, chemotherapy, or both. While it is not required for diagnosis or treatment of brainstem glioma, judicious use of biopsy/resection is recommended when safe. Surgery may improve symptomatic control and provide tissue for molecular testing for both prognosis and potential therapeutic implications. It should particularly be considered in the following situations:

See Treatment and Medication for more detail.

Background

Brainstem gliomas are tumors that occur in the region of the brain referred to as the brain stem, which is the area between the aqueduct of Sylvius and the fourth ventricle. Although various systems are used to classify these tumors, many have divided brainstem gliomas into 3 distinct anatomic locations—diffuse intrinsic pontine,[3] tectal, and cervicomedullary. Intrinsic pontine gliomas carry a grave prognosis. Longer survival is associated with the tectal and cervicomedullary gliomas. Tumors also are characterized on the basis of site of origin, focality, direction and extent of tumor growth, degree of brainstem enlargement, degree of exophytic growth, and presence or absence of cysts, necrosis, hemorrhage, and hydrocephalus.[4]

Pathophysiology

Approximately 60% of brainstem gliomas are centered within the pons, but can originate in the medulla or midbrain and may extend beyond the brainstem. Brainstem gliomas are highly aggressive brain tumors. Anatomic location determines the pathophysiological manifestation of the tumor. With tectal lesions, hydrocephalus may occur as a result of fourth ventricular compression. With pontine and cervicomedullary lesions, cranial nerve or long tract signs are observed commonly.

Histopathologically, brainstem gliomas can range from WHO Grade 1 to 4. Grade 1 is classified as juvenile pilocytic astrocytoma, Grade 2 is diffuse astrocytoma, Grade 3 is anaplastic astrocytoma, and grade 4 is glioblastoma. The grading is based on the presence of nuclear atypia, vascular proliferation, mitoses, and necrosis. Typically, necrosis is seen in Grade 4 (glioblastoma multiforme). Increasing tumor grade is associated with poorer prognosis.

Molecular profiling is now an important part of glioma classification. An IDH1 mutation carries a significantly improved prognosis over the IDH1 wildtype, no matter the tumor grade. Codeletions of chromosome 1p and 19q along with an IDH1 mutation indicates an oligodendroglioma, and is rarely found in brainstem gliomas. For pediatric diffuse gliomas, a newly defined entity termed diffuse midline glioma, H3 K27M-mutant is characterized by K27M mutations in the histone H3 gene, a diffuse growth pattern and a midline location. This newly defined entity occurs primarilty in children, but can be seen in adults, and includes tumors previously referred to as diffuse intrinsic pontine glioma (DIPG).[5] MGMT promoter methylation has not been well studied in brainstem gliomas, however, one series suggested that more than 60% of brainstem gliomas are unmethylated.[6]

Mutations in the histone H3 gene suggest epigenetic dysregulation as an important contributor to the pathogenesis of diffuse intrinsic pontine glioma, particularly in children. Notably, histone H3 mutations rarely occur in adult patients with supratentorial glioblastoma.

Frequency

Brainstem gliomas represent < 2% of all intracranial tumors in adults and approximately 20% of brain tumors in children, with a slight male predominance. Median age at diagnosis in adults is in the mid-30s, but can present at any age.

Mortality/Morbidity

Morbidity from brainstem gliomas occur due to the location of the space-occupying lesion and compression of surrounding structures; because these structures regulate basic body functions of blood pressure, respiration, and swallowing as well as motor and sensory functions, compression can produce substantial neurological disability. Sudden death can result from increased intracranial pressure and subsequent cerebral herniation. This may be a consequence either of edema induced by the tumor or of hemorrhage into the neoplasm.

Pediatric diffuse intrinsic pontine glioma (DIPG) is associated with a dismal prognosis of approximately 10 months with only 10% of patients living > 2 years beyond initial diagnosis. However, median survival for adult patients with brainstem gliomas is in the range of 30–40 months.[2]  Because presentation in adults varies widely, prognostication can be difficult. Other factors that have been shown to negatively influence survival include contrast enhancement within the tumor on MRI, location within the brainstem (pons > medulla > midbrain), and advanced age (> 60 years).[2, 7]

Epidemiology

Race-, sex-, and age-related demographics

CNS tumors vary in incidence by age, sex, ethnic group, and country, and also over time. How much of this variation is due to artifactual influences or etiologic differences has been the subject of many debates.

Some reports have suggested a slight male preponderance, whereas others have failed to observe any sex predilection.

Bimodal age distribution has been noted, with a peak incidence in the latter half of the first decade of life and a second peak in the fourth decade. Approximately three fourths of patients are younger than 20 years.

History

Common presenting symptoms include double vision, weakness, unsteady gait, difficulty in swallowing, dysarthria, headache, drowsiness, nausea, and vomiting. Rarely, behavioral changes or seizures may be seen in children. Older children may have deterioration of handwriting and speech.

Pontine lesions usually present with any or all of the above signs and symptoms, depending on location and extension. Midbrain and lower brainstem/upper spinal cord signs and symptoms may be seen with extension of the neoplasm to involve these structures.

In infants and children presenting with failure to thrive, pontine glioma should be considered in the differential diagnosis.

Tectal lesions typically present with headache, nausea, and vomiting.

Hydrocephalus is a common presentation, especially for tumors in periaqueductal or fourth ventricle outflow locations, because these regions have less tolerance of growth and higher risk of obstructive hydrocephalus.

Cervicomedullary lesions usually present with dysphagia, unsteadiness, nasal speech, vomiting, and weakness.

Physical

Common clinical findings can be summarized as constituting a triad of cranial nerve deficits, long tract signs, and ataxia (of trunk and limbs). Papilledema may be seen.

Sixth and seventh cranial nerves are involved commonly. Facial sensory loss and a primary position, upbeating nystagmus may be seen. Involvement of cranial nerve III or IV suggests a mesencephalic component.

Tectal lesions may present with diplopia reflecting an internuclear ophthalmoplegia, indicating involvement of the medial longitudinal fasciculus. Parinaud syndrome also may be seen, with paralysis of upward gaze and accommodation, light-near dissociation (loss of pupillary reflex to light with preservation of pupilloconstriction in response to convergence), eyelid retraction, and convergence-retraction nystagmus.

Cervicomedullary lesions may present with sensory loss of the face (involvement of the trigeminal nucleus), dysphagia and/or dysphonia from lower cranial nerve involvement (commonly IX and X), long tract signs, and ataxia. Downbeating nystagmus and oculomyoclonus often are seen with medullary involvement.

Causes

Although no familial tendency is prominent overall, an increased incidence of brainstem glioma has been observed consistently in patients with neurofibromatosis (up to 14% in some reports).

In children irradiated for tinea capitis, an increased incidence of CNS tumors, especially meningiomas, gliomas, and nerve sheath tumors, has been reported. No specific reference is made in these reports to tumors of the brain stem. Radiotherapy-induced neoplasms tend to be more aggressive in their natural history than their de novo counterparts.

Laboratory Studies

Lab studies of blood chemistry and related body fluids are not helpful as a rule, though cerebrospinal fluid (CSF) examination is often important for differential diagnosis. The protein content of CSF may be elevated. Because of the risk of increased intracranial pressure due to obstructive hydrocephalus, caution in clinical and imaging assessment prior to lumbar puncture is stressed.

Imaging Studies

MRI

MRI of the head is the diagnostic test of choice. MRI can differentiate vascular malformations and other processes that can be misdiagnosed as a brainstem glioma on CT scan.[8]

The typical MRI appearance of a brainstem glioma is an expansile, infiltrative process with low-to-normal signal intensity on T1-weighted images and heterogeneous high-signal intensity on T2-weighted images. Contrast enhancement may be seen in only up to 40% of adult patients.



View Image

Axial T2 FLAIR image showing a pontine-centered lesion consistent with a brainstem glioma.



View Image

Axial T2 image showing a pontine mass consistent with brainstem glioma.

MR spectroscopy can be useful to distinguish between tumor and non-neoplastic lesions in the brain. An elevation of the choline/NAA ratio suggests neoplasm.

The occurrence of contrast enhancement in a tectal lesion should raise suspicion of a metastatic lesion, especially in an adult, with or without a known history of cancer.

CT scan

Although CT imaging is an appropriate choice when MRI is not available, the appearance of brainstem gliomas is variable on CT scan, and the sensitivity of and characterization of tumors by CT are poorer.

CT identifies calcifications, cystic changes, and displacement of the ventricular system; however, lower brainstem lesions are often not apparent on CT scan.

PET-CT is rarely used, but may be helpful in differentiating aggresive lesions from indolent ones.

Other Tests

Arteriography occasionally is useful in differentiating vascular lesions, including tumors, from gliomas.

Procedures

While not required for diagnosis, biopsy should be considered in all patients where obtaining tissue is safe and feasible. This allows for histologic classification, and more importantly, molecular testing, which may aid in prognosis. Further, this may have therapeutic implications as our understanding of the pathophysiology is evolving and may allow for enrollment into clinical trials.

Medical Care

Treatment of brainstem gliomas has been frustrating. To date, most trials (particularly in the pediatric population) have failed to show a significant benefit to any systemic agent beyond radiotherapy.

Adjuvant chemotherapy is not often used in children because efficacy has not been proven. Data have suggested that preradiation chemotherapy may improve survival in pediatric diffuse intrinsic brainstem gliomas.[9]  The effectiveness of combined radiotherapy and chemotherapy has not been exstensively evaluated in adults. However, retrospective data suggest that upfront temozolomide along with radiation may improve survival in adult patients.[2] The effectiveness of chemotherapy at relapse is uncertain, but it may benefit some patients.

Chemotherapy options, when considered for use in brainstem gliomas, may include conventional agents such as temozolomide and carboplatin/vincristine. Antiangiogenesis agents such as bevacizumab have been used with varying success in supratentorial glioblastomas, however, their role in brainstem gliomas is less clear. Small studies have suggested that a small number of patients may benefit in the shortmterm, but the outcomes are worse than for supratentorial gliomas.[2]  Patients and families should be encouraged to enroll on clinical trials whenever possible.

Focal radiotherapy is the cornerstone of treatment of brainstem gliomas and can improve or stabilize the patient's condition.[1] The conventional dose of radiotherapy ranges from 54 to 60 Gy, and is considered standard upfront therapy. 

Response to radiotherapy depends on several variables, such as tumor location, histologic type, and response to early treatment. Patients who underwent radiation therapy for exophytic tumors have been reported to have better survival rates than those treated for tumors without an exophytic component.

Radiotherapy should be administered to any patient with significant and progressive neurologic symptoms. Some adult patients with a tectal or cervicomedullary lesion, or with mild symptoms of long duration, may be candidates for observation alone; radiotherapy can be reserved for patients with clear evidence of tumor progression.

Surgical Care

Surgical resection is performed in conjunction with radiation therapy, chemotherapy, or both. Surgery is most appropriate in the following cases:

Ancillary Procedures

Patients with hydrocephalus may require ventriculostomy or ventriculoperitoneal shunting for symptomatic relief.

Patients with difficulties in swallowing and diminished gag reflex may need feeding by gastrostomy, such as percutaneous esophagogastrostomy (PEG).

Those patients who have had multiple upper respiratory infections, pneumonia, or altered voice may need postoperative ventilatory assistance.

Consultations

Consultation with the following may prove helpful:

Dexamethasone (Decadron)

Clinical Context:  Can be used to reduce tumor- and radiotherapy-associated cerebral edema.

Class Summary

These agents have anti-inflammatory properties and cause profound and varied metabolic effects. Corticosteroids modify the body's immune response to diverse stimuli.

Temozolomide (Temodar)

Clinical Context: 

Further Outpatient Care

Follow-up neuroimaging with MRI (unless contraindicated) is recommended within 72 hours after surgery and every 2-3 months to monitor response to therapy and progression of disease. This should be considered standard care for these patients.

Further Inpatient Care

Typically, patients are monitored for worsening signs/symptoms. Admission to the hospital may be required to enable therapeutic intervention and stabilization.

Complications

Complications may include the following:

Prognosis

Pontine tumors are the most common variety of brainstem tumor. They also carry the worst prognosis; in children, the median survival duration is 9-12 months even with treatment. Kaplan et al reported a 37% survival rate at 1 year, 20% at 2 years, and 13% at 3 years, with a median survival of 10 months. Only 9 of 119 patients in their study were alive for more than 3 years after diagnosis.[10]

Squires et al, in a study of 12 children with midbrain tectal tumors, reported a median survival duration of more than 50 months.[11]

Favorable prognostic factors include (1) neurofibromatosis, (2) symptoms of at least 12 months' duration before diagnosis, (3) exophytic location, (4) pathology suggestive of low-grade tumor histology, (5) focal tectal and cervicomedullary tumors, and (6) calcification on CT scan.

Poor prognostic indicators include (1) age younger than 2 years, (2) multiple brainstem signs, (3) cranial nerve palsies, (4) diffuse intrinsic lesions of the pons, (5) short duration of signs and symptoms prior to the time of diagnosis, and (6) high-grade histology on tumor biopsy.

Hydrocephalus and tumor necrosis do not affect survival.

Race and gender do not affect survival.

The limited available data suggest that adults fare better than children with brainstem gliomas.

Patient Education

Patients and families of patients acquire information from multiple sources, including, but not limited to, physician, patients, support groups, pharmaceutical companies, and the Internet. Physicians should be aware of this and have an open, informative relationship with their patients, empowering patients to become active members of the team with regard to the decision-making process involving their care.

Author

Douglas E Ney, MD, Associate Professor of Neurology and Neurosurgery, Director of Neurology Residency Program, University of Colorado School of Medicine

Disclosure: Nothing to disclose.

Specialty Editors

Francisco Talavera, PharmD, PhD, Adjunct Assistant Professor, University of Nebraska Medical Center College of Pharmacy; Editor-in-Chief, Medscape Drug Reference

Disclosure: Received salary from Medscape for employment. for: Medscape.

Jorge C Kattah, MD, Head, Associate Program Director, Professor, Department of Neurology, University of Illinois College of Medicine at Peoria

Disclosure: Nothing to disclose.

Chief Editor

Tarakad S Ramachandran, MBBS, MBA, MPH, FAAN, FACP, FAHA, FRCP, FRCPC, FRS, LRCP, MRCP, MRCS, Professor Emeritus of Neurology and Psychiatry, Clinical Professor of Medicine, Clinical Professor of Family Medicine, Clinical Professor of Neurosurgery, State University of New York Upstate Medical University; Neuroscience Director, Department of Neurology, Crouse Irving Memorial Hospital

Disclosure: Nothing to disclose.

Additional Contributors

Edward L Hogan, MD, Professor, Department of Neurology, Medical College of Georgia; Emeritus Professor and Chair, Department of Neurology, Medical University of South Carolina

Disclosure: Nothing to disclose.

Joseph C Landolfi, DO, Director of Neurology, New Jersey Neuroscience Institute; Director of Neuro-oncology, Medical Director, Gamma Knife Program, JFK Brain Tumor Center; Chairman, Institutional Review Board, JFK Health System; Medical Director of Neuro-oncology, Meridian Health System; Professor of Neurology, Seton Hall University School of Graduate Medical Education

Disclosure: Received honoraria from Novacure for speaking and teaching; Received honoraria from Genetech for speaking and teaching.

Acknowledgements

Anita Venkataramana, MBBS Clinical Instructor, Department of Neurology, Division of Neuroimmunology/HIV, Johns Hopkins University

Disclosure: Nothing to disclose.

References

  1. Vesper J, Bölke B, Wille C, Gerber PA, Matuschek C, Peiper M, et al. Current concepts in stereotactic radiosurgery - a neurosurgical and radiooncological point of view. Eur J Med Res. 2009 Mar 17. 14(3):93-101. [View Abstract]
  2. Theeler BJ, Ellezam B, Melguizo-Gavilanes I, de Groot JF, Mahajan A, Aldape KD, et al. Adult brainstem gliomas: Correlation of clinical and molecular features. J Neurol Sci. 2015. 353 (1-2):92-7. [View Abstract]
  3. Frazier JL, Lee J, Thomale UW, Noggle JC, Cohen KJ, Jallo GI. Treatment of diffuse intrinsic brainstem gliomas: failed approaches and future strategies. J Neurosurg Pediatr. 2009 Apr. 3(4):259-69. [View Abstract]
  4. Ueoka DI, Nogueira J, Campos JC, Maranhão Filho P, Ferman S, Lima MA. Brainstem gliomas--retrospective analysis of 86 patients. J Neurol Sci. 2009 Jun 15. 281(1-2):20-3. [View Abstract]
  5. Louis DN, Perry A, Reifenberger G, von Deimling A, Figarella-Branger D, Cavenee WK, et al. The 2016 World Health Organization Classification of Tumors of the Central Nervous System: a summary. Acta Neuropathol. 2016 Jun. 131(6):803-20. [View Abstract]
  6. Babu R, Kranz PG, Agarwal V, McLendon RE, Thomas S, Friedman AH, et al. Malignant brainstem gliomas in adults: clinicopathological characteristics and prognostic factors. J Neurooncol. 2014 Aug. 119 (1):177-85. [View Abstract]
  7. Reyes-Botero G, Laigle-Donadey F, Mokhtari K, Martin-Duverneuil N, Delattre JY. Temozolomide after radiotherapy in recurrent "low grade" diffuse brainstem glioma in adults. J Neurooncol. 2014 Dec. 120 (3):581-6. [View Abstract]
  8. Grau SJ, Rachinger W, Holtmannspoetter M, Herms J, Tonn JC, Kreth FW. Serial Stereotactic Biopsy of Brainstem Lesions in Adults Improves Diagnostic Accuracy Compared to MRI Only. J Neurol Neurosurg Psychiatry. 2009 Jun 10. [View Abstract]
  9. Frappaz D, Schell M, Thiesse P et al. Preradiation chemotherapy may improve survival in pediatric diffuse intrinsic pontine gliomas: Final results of BSG 98 prospective trial. Neuro Oncol. Aug/2008. 10(4):599-607. [View Abstract]
  10. Kaplan AM, Albright AL, Zimmerman RA, Rorke LB, Li H, Boyett JM, et al. Brainstem gliomas in children. A Children's Cancer Group review of 119 cases. Pediatr Neurosurg. 1996. 24(4):185-92. [View Abstract]
  11. Squires LA, Allen JC, Abbott R, Epstein FJ. Focal tectal tumors: management and prognosis. Neurology. 1994 May. 44(5):953-6. [View Abstract]
  12. Grigsby PW, Garcia DM, Simpson JR, et al. Prognostic factors and results of therapy for adult thalamic and brainstem tumors. Cancer. 1989 Jun 1. 63(11):2124-9. [View Abstract]
  13. Landolfi JC, Thaler HT, DeAngelis LM. Adult brainstem gliomas. Neurology. 1998 Oct. 51(4):1136-9. [View Abstract]
  14. Hamilton MG, Lauryssen C, Hagen N. Focal midbrain glioma: long term survival in a cohort of 16 patients and the implications for management. Can J Neurol Sci. 1996 Aug. 23(3):204-7. [View Abstract]
  15. Kesari S, Kim RS, Markos V, Drappatz J, Wen PY, Pruitt AA. Prognostic factors in adult brainstem gliomas: a multicenter, retrospective analysis of 101 cases. J Neurooncol. 2008 Jun. 88(2):175-83. [View Abstract]
  16. Raza S, Donach M. Bevacizumab in adult malignant brainstem gliomas. J Neurooncol. 2009 Jun 9. [View Abstract]
  17. Abbott R, Shiminski-Maher T, Epstein FJ. Intrinsic tumors of the medulla: predicting outcome after surgery. Pediatr Neurosurg. 1996 Jul. 25(1):41-4. [View Abstract]
  18. Albright AL, Guthkelch AN, Packer RJ, et al. Prognostic factors in pediatric brain-stem gliomas. J Neurosurg. 1986 Dec. 65(6):751-5. [View Abstract]
  19. Barkovich AJ, Krischer J, Kun LE, et al. Brain stem gliomas: a classification system based on magnetic resonance imaging. Pediatr Neurosurg. 1990-91. 16(2):73-83. [View Abstract]
  20. Cohen ME, Duffner PK. 2nd ed. Brain Tumors in Children: Principles of Diagnosis and Treatment. New York: Raven Press; 1994.
  21. Cohen ME, Duffner PK, Heffner RR, et al. Prognostic factors in brainstem gliomas. Neurology. 1986 May. 36(5):602-5. [View Abstract]
  22. Dunkel IJ, O'Malley B, Finlay JL. Is there a role for high-dose chemotherapy with stem cell rescue for brain stem tumors of childhood?. Pediatr Neurosurg. 1996. 24(5):263-6. [View Abstract]
  23. Edwards MS, Wara WM, Urtasun RC, et al. Hyperfractionated radiation therapy for brain-stem glioma: a phase I-II trial. J Neurosurg. 1989 May. 70(5):691-700. [View Abstract]
  24. Epstein F, Wisoff J. Intra-axial tumors of the cervicomedullary junction. J Neurosurg. 1987 Oct. 67(4):483-7. [View Abstract]
  25. Fenichel Gerald M. Clinical Pediatric Neurology: A Signs and Symptoms Approach. 3rd ed. Philadelphia: WB Saunders Company; 1997.
  26. Guiney MJ, Smith JG, Hughes P, et al. Contemporary management of adult and pediatric brain stem gliomas. Int J Radiat Oncol Biol Phys. 1993 Jan 15. 25(2):235-41. [View Abstract]
  27. Jallo GI, Biser-Rohrbaugh A, Freed D. Brainstem gliomas. Childs Nerv Syst. 2004 Mar. 20(3):143-53. [View Abstract]
  28. Kaye AH, Laws ER. Brain Tumors. New York: Churchill Livingstone; 1995.
  29. Milstein JM, Geyer JR, Berger MS, Bleyer WA. Favorable prognosis for brainstem gliomas in neurofibromatosis. J Neurooncol. 1989 Nov. 7(4):367-71. [View Abstract]
  30. Rosenblum RK. Brain stem glioma: two case studies. J Pediatr Oncol Nurs. 2005 Mar-Apr. 22(2):114-8. [View Abstract]
  31. Tokuriki Y, Handa H, Yamashita J, et al. Brainstem glioma: an analysis of 85 cases. Acta Neurochir (Wien). 1986. 79(2-4):67-73. [View Abstract]
  32. Walker DA, Liu J, Kieran M, Jabado N, Picton S, Packer R, et al. A multi-disciplinary consensus statement concerning surgical approaches to low-grade, high-grade astrocytomas and diffuse intrinsic pontine gliomas in childhood (CPN Paris 2011) using the Delphi method. Neuro Oncol. 2013 Apr. 15(4):462-8. [View Abstract]

Axial T2 FLAIR MRI image showing a mass in the brainstem consistent with brainstem glioma.

Axial T2 FLAIR image showing a pontine-centered lesion consistent with a brainstem glioma.

Axial T2 image showing a pontine mass consistent with brainstem glioma.

T2-weighted image of a diffuse intrinsic pontine glioma.

T2-weighted image of a right tectal glioma.

Axial T2 FLAIR MRI image showing a mass in the brainstem consistent with brainstem glioma.

Axial T2 FLAIR image showing a pontine-centered lesion consistent with a brainstem glioma.

Axial T2 image showing a pontine mass consistent with brainstem glioma.