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Pseudoprogression in a Patient With Glioblastoma Presenting as a Neurosurgical Emergency

Published online by Cambridge University Press:  29 July 2015

Wajid M.H. Sayeed
Affiliation:
Section of Neurology, Department of Internal Medicine, University of Manitoba, Winnipeg, Manitoba, Canada
Jacob C. Easaw*
Affiliation:
Division of Neuro-Oncology, Department of Oncology, Tom Baker Cancer Centre, Calgary, Alberta, Canada
Amitabh D. Singh
Affiliation:
Division of Neuro-Oncology, Department of Oncology, Tom Baker Cancer Centre, Calgary, Alberta, Canada
*
Correspondence to: Jacob C. Easaw, Department of Oncology, Tom Baker Cancer Centre, 1331 29th Street NW, Calgary Alberta T2N 4N2. E-mail: jay.easaw@albertahealthservices.ca
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Abstract

Type
Brief Communications
Copyright
Copyright © 2015 The Canadian Journal of Neurological Sciences Inc. 

Glioblastoma (GBM) is an aggressive primary intracranial neoplasm that, if left untreated, carries a median survival of about 10 weeks. Following the landmark publication by Stupp et al in 2005,Reference Stupp, Mason and van den Bent 1 the standard of care for patients with newly diagnosed GBM has been 6 weeks of radiotherapy (in fractions of 2 Gy for a total of 60 Gy), with concurrent daily low-dose temozolomide (TMZ) (dosed at 75 mg/m2 daily) followed by up to 12 cycles of adjuvant TMZ (five of every 28 days, dosed at 150-200 mg/m2/day). Most centres follow patients receiving this therapy with MRI every 8-12 weeks to assess disease status.

Combined TMZ and radiation are known to cause increased contrast enhancement in the first postchemoradiotherapy MRI in nearly half of all patients.Reference Roldán, Scott and McIntyre 2 However, a diagnosis of either pseudoprogression (radiation-induced change) or true disease progression can only be made retrospectively by comparing with another MRI done 2 months later. Pseudoprogression occurs from radiation-induced inflammation characterized by abnormal vessel permeability, causing the contrast material to leak into the brain parenchyma, thus mimicking disease progression. These changes diminish in the MRI done 2 months later.Reference Stupp, Mason and van den Bent 1

Previously, tumour response to therapy was assessed by the MacDonald criteria. In 2010, a new set of criteria was published by the Response Assessment in Neuro-Oncology (RANO) Working Group,Reference Wen, Macdonald and Reardon 3 which precluded the diagnosis of true disease progression within the first 12 weeks of completion of chemoradiotherapy unless either new lesions appear outside the radiation field or histopathology confirms a mitotically active neoplasm. In our previous article, we have shown that clinical deterioration does not help to differentiate between true disease progression and pseudoprogression.Reference Singh and Easaw 4

Because a diagnosis of true disease progression often prompts a change in treatment (possible reoperation and different chemotherapy), it is important for oncologists and neurosurgeons alike to recognize this problem—the inability to differentiate pseudoprogression from true disease progression—and not abandon the ongoing chemotherapy plan without a follow-up MRI (done beyond the 12-week period). Consequently, Canadian guidelines recommend that patients continue with a minimum of three cycles of TMZ followed by a repeat MRI in the absence of urgent clinical or radiographic indications for surgical intervention.

From a neurosurgical perspective, surgery done within 12 weeks of completing chemoradiation may be considered in exceptional cases. In our centre, it is general practice not to operate upon patients with possible pseudoprogression because about 50% of such cases stabilize with further cycles of TMZ.Reference Roldán, Scott and McIntyre 2 In this article, we present an important exception to usual practice in which surgery was indicated despite what was later confirmed to be pseudoprogression.

Case Report

A 48-year-old man presented to the neurooncology service at Tom Baker Cancer Centre, Calgary, following surgery for a right temporal GBM in July 2013. His initial symptoms included severe headaches, inattention, and progressively diminished memory. MRI of his brain revealed a 7.1×3.9 cm heterogeneously enhancing lesion in the right temporal lobe, for which he underwent surgery (Figure 1). The tumour showed no IDH mutation, and was negative for epidermal growth factor receptor vIII. The test for O6-methylguanine-DNA methyltransferase promoter methylation was indeterminate.

Figure 1 Left: preoperative T1 gadolinium-enhanced MRI demonstrating 7.1×3.9 cm right temporal enhancing lesion with associated mass effect. Right: postoperative T1 gadolinium-enhanced MRI showing reduction in mass effect.

Postoperatively, the patient was treated with 6 weeks of concurrent chemotherapy (TMZ) and radiotherapy (60 Gy) from mid-August to early October 2013. He presented in November 2013 to the clinic complaining of severe, holocranial headaches and fatigue and was treated with intravenous dexamethasone. Oral dexamethasone was thereafter increased to 4 mg three times daily. Because his functional status was suboptimal at that time, adjuvant chemotherapy was deferred.

Two weeks later, the patient was reevaluated for initiating adjuvant TMZ. In the interim, however, he had deteriorated clinically with worsening fatigue, nausea, confusion, and declining memory despite being on high-dose steroids. Physical examination revealed a drowsy patient who was giving intermittent responses to command. Right-sided ptosis and left pronator drift were noted, which were not present earlier.

An emergent MRI of the brain revealed enlargement of an enhancing lesion within the field of radiation, resulting in uncal herniation causing compression and torsion of the midbrain (Figure 2).

Figure 2 T1 gadolinium-enhanced MRI (done 7 weeks after chemoradiation) demonstrating markedly increased contrast enhancement (as compared with postoperative MRI in Figure 1 [right]) causing uncal herniation. Axial (left) and coronal (right) images show midbrain compression and herniation of the uncus into the suprasellar cistern, respectively.

Although the MRI was done within 12 weeks of completing chemoradiation (when approximately 50% of patients with increasing contrast enhancing areas have pseudoprogression), his surgeon was alerted to the possibility of the neurosurgical emergency. He was admitted and underwent a surgical decompression in late November 2013. Histopathology of excised tissue showed glioblastoma of moderate cellularity with a low proliferative rate (no mitotic figures, low Ki67), and microvasculature demonstrating thickened, hyalinized walls with rare examples of fibrinoid necrosis. This was consistent with postradiation glioblastoma. The extent of decompression was inadequate, and the patient’s neurological condition worsened, necessitating another surgery (anterior temporal lobectomy). His clinical condition improved thereafter and he was started on adjuvant TMZ (5/28 day schedule). The patient went on to survive an additional 5 months and then died in March 2014.

Discussion

This case provides an example of an absolute indication for surgical decompression to address a life-threatening condition, despite it being due to the typically nonmalignant phenomenon of pseudoprogression.

Pseudoprogression poses significant challenges for management because it is a diagnosis that can only be made retrospectively. Although some authors have used the presence of characteristics such as decreased cellularity and fibrinoid necrosis to define pseudoprogression on biopsy, no universally agreed-upon histopathological definition of pseudoprogression exists, and features seen at biopsy frequently overlap early radiation-induced necrotic changes.Reference Roldán, Scott and McIntyre 2 , Reference Singh and Easaw 4 Ultimately, the diagnosis is confirmed on clinical and radiographic grounds.

Before the publication of the RANO criteria in 2010, the MacDonald criteria were commonly used in clinical trials to judge response to treatment. One of their major limitations, and thus one of the reasons for their revision, was overdiagnosis of disease progression, leading overaccrual and false-positive results in clinical trials for recurrent glioblastoma.Reference Wen, Macdonald and Reardon 3 The RANO criteria divide tumour response into four categories: complete response, partial response, stable disease, and progressive disease (Table 1). Importantly, the RANO criteria emphasize that true disease progression cannot be diagnosed on MRI alone within 12 weeks of chemoradiotherapy, barring new lesions beyond the 80% (radiation) isodose line. The revised criteria do not imply that pseudoprogression is itself harmless, and as our case demonstrates, it can have life-threatening consequences if not recognized.

Table 1 Summary of RANO criteria

Adapted from Wen et al.Reference Wen, Macdonald and Reardon 3

CR, complete response; PR, partial response; SD, stable disease; PD, progressive disease; FLAIR, fluid attenuated inversion recovery.

In the cohort published by Roldan and coworkers, the incidence of early pseudoprogression (occurring within 2 months of completing chemoradiotherapy) was 50% in patients with GBM.Reference Roldán, Scott and McIntyre 2 Our patient had presented with worsening of his neurological condition and ipsilateral ptosis (indicative of partial third nerve paresis). His MRI was done 7 weeks after completing chemoradiotherapy. By convention, he would have been treated by an increase in steroids and surgery (or a change in chemotherapy) would have been deferred until a second MRI showed further increase in the enhancing areas. Had such an approach been taken, the patient would have likely suffered catastrophic uncal herniation and resultant midbrain compression.

Although there is no standard of care for imaging to distinguish pseudoprogression from true progression, several strategies are under investigation for noninvasive assessment of potentially worrisome lesions. Conventional MRI features such as new callosal involvement and new subependymal enhancement can be indicative of true progression, but its utility is otherwise limited. Other MRI-based modalities as well as positron emission tomography tracers such as 18F-deoxyglucose, O-(2-18F-fluoroethyl)-l-tyrosine, 18F-dopamine, 11C-methionine, and 13N-NH3 have been recently tested.5 Although no single modality has been shown to be uniformly successful in differentiating between pseudoprogression and true progression, the combination of multiple modalities may hold the key to the creation of a useful imaging approach to diagnosis.

It is important for oncologists to recognize imminent neurosurgical emergencies in patients with possible pseudoprogression and arrange for an urgent surgical consultation. Likewise, it is important for neurosurgeons to be aware of the phenomenon and significance of pseudoprogression that occurs in about half the patients undergoing chemoradiation and is conventionally seen during the first 12 weeks after completing chemoradiation.Reference Roldán, Scott and McIntyre 2 Because there are no radiological or clinical criteria to distinguish between true disease progression and pseudoprogression during this period, surgery may be deferred in a majority of patients until a subsequent MRI shows further increase in contrast enhancing areas, suggestive of true disease progression. The authors urge readers to assess both the MRI and the clinical status of patients during the first 12 weeks postchemoradiation with extreme care as a means to identify patients in need of urgent surgical decompression, despite the possibility of pseudoprogression being present.

Disclosures

WMHS, JE, and AS have no disclosures to report.

References

1. Stupp, R, Mason, WP, van den Bent, MJ, et al. Radiotherapy plus concomitant and adjuvant temozolomide for glioblastoma. N Engl J Med. 2005;10:987-996.Google Scholar
2. Roldán, GB, Scott, JN, McIntyre, JB, et al. Population-based study of pseudoprogression after chemoradiotherapy in GBM. Can J Neurol Sci. 2009;36:617-622.CrossRefGoogle ScholarPubMed
3. Wen, PY, Macdonald, DR, Reardon, DA, et al. Updated response assessment criteria for high-grade gliomas: response assessment in neuro-oncology working group. J Clin Oncol. 2010;28:1963-1972.CrossRefGoogle ScholarPubMed
4. Singh, AD, Easaw, JC. Does neurologic deterioration help to differentiate between pseudoprogression and true disease progression in newly diagnosed glioblastoma multiforme? Curr Oncol. 2012;19:e295-e298.CrossRefGoogle ScholarPubMed
5. O’Brien, BJ, Colen, RR. Post-treatment imaging changes in primary brain tumors. Curr Oncol Rep. 2014;16:397.CrossRefGoogle ScholarPubMed
Figure 0

Figure 1 Left: preoperative T1 gadolinium-enhanced MRI demonstrating 7.1×3.9 cm right temporal enhancing lesion with associated mass effect. Right: postoperative T1 gadolinium-enhanced MRI showing reduction in mass effect.

Figure 1

Figure 2 T1 gadolinium-enhanced MRI (done 7 weeks after chemoradiation) demonstrating markedly increased contrast enhancement (as compared with postoperative MRI in Figure 1 [right]) causing uncal herniation. Axial (left) and coronal (right) images show midbrain compression and herniation of the uncus into the suprasellar cistern, respectively.

Figure 2

Table 1 Summary of RANO criteria