Question (Q1): In adult patients with pGBM does the use of temozolomide (TMZ) with alternative dosing or the use TMZ in combination with other cytotoxic treatments result in increased overall survival compared to other chemotherapy?
Eleven eligible studies examined the use of temozolomide for the treatment of pGBM and were included in this analysis. Table 1A summarizes the 6 studies [6-11] that examined the use of TMZ at doses different than what published by Stupp et al [4]. Table 1B summarizes 6 studies [12-17] reporting on the use of TMZ in combination with other cytotoxic agents. All of these studies provided Class III evidence.
Metronomic Temozolomide (TMZ)
Wong et al [6] conducted a very small phase I trial of low dose metronomic TMZ (25- 50mg/m2 daily) in 9 recurrent malignant glioma patients including 6 with glioblastoma. Response rates were not mentioned. The median PFS was 3.1 months and median OS was 12.5 months. The authors concluded that metronomic temozolomide had efficacy in recurrent malignant gliomas but there were too few patients for any meaningful conclusions.
Omuro et al [9] conducted a phase II trial of metronomic temozolomide (50mg/m2 daily) in 37 patients with heavily pretreated glioblastoma patients, including 49% with prior bevacizumab. 11% of patients experienced a partial response (PR) and 25% experienced stable disease (clinical benefit 36%). The 6-month progression-free survival (PFS-6) was 19%. Median overall survival (OS) was 7 months Patients with previous bevacizumab exposure survived significantly less than bevacizumab-naive patients (median overall survival: 4.3 months vs 13 months; hazard ratio = 3.2; P = .001), but those patients had lower KPS (P = .04) and higher number of recurrences (P < .0001). The authors concluded that in this heavily pretreated population with nearly half of patients having failed bevacizumab, the regimen had some activity and deserved further evaluation.
Dose Dense Temozolomide (dd-TMZ)
Han et al [8] treated 60 patients with recurrent high-grade glioma in a phase II single arm prospective trial with 150 mg/m2 of dose dense temozolomide(TMZ) given on days 1 – 7 and day 15 – 21 of a 28 days cycle for 12 cycles after recurrence. Forty patients from the cohort had recurrent glioblastoma (GBM). Primary end point was progression-free survival at 6 months to be better than the historical control of recurrent glioma participants in other phase II trials (PFS-6 10% for GBM). In the current study, PFS-6 achieved was 10% and median OS was 21.6%. They concluded that dose-dense TMZ at recurrence is feasible; however, the primary efficacy endpoint for these patients was not achieved. This study was classified as class III evidence due to the design and lack of control arm.
Norden et al [11] conducted a multicenter phase II trial of dose dense temozolomide 75- 100mg/m2/day) for 21 days of every 28 day cycle in 58 recurrent glioblastoma patients. 13% of patients experienced a PR and PFS-6 was only 11%. MGMT methylated patients had longer OS but not PFS. The authors concluded that dose-dense temozolomide on this schedule was safe in recurrent glioblastoma patients but the efficacy was marginal and predictive biomarkers were needed.
Archavlis et al [10] in this retrospective two- center study, the median survival and complication rate of 111 pGBM patients who received dose dense Temozolomide or re-operation or f interstitial high dose rate brachytherapy (HDR-BRT) at recurrence were compared. The HDR-BRT group did significantly better than both the reoperation (p<0.05) and the ddTMZ groups (p<0.05). Moderate to severe complications were reported in the HDR-BRT group. The Authors concluded that the survival benefit of ddTMZ is lower than HDR-BRT. This study was classified as class III evidence due to the design.
Other Temozolomide (TMZ) dosing.
Van Vugt et al [7] conducted a small retrospective study involving 15 high-grade glioma patients including 13 recurrent glioblastoma patients who had progressed on temozolomide who were treated with 3 days on/11 days off temozolomide regimen (300mg/m2). Toxicity of the regimen was comparable to other temozolomide regimen. The objective response rate (ORR) was 7%, median PFS was 4.1 months, PFS-6 was 25% and median OS was 13.8 months. Although the authors indicate that the regimen was tolerable and warranted further evaluation the small number of patients makes it difficult to know if this regimen is any different from other temozolomide regimens.
Temozolomide (TMZ) in combination with other cytotoxic agents.
Roussakow et al [12] conducted a retrospective review of 54 recurrent glioblastoma patients treated with dose –dense TMZ (21/28 day regimen) with modulated electrohypothermia and compared the data to those of patients treated on trials with dose-dense TMZ. The objective response rate (ORR) was 20%; 33% had stable disease (SD) and median OS was 7.7 months. The authors concluded that modulated electrohyperthermia significantly improved survival of patients receiving the dose dense TMZ using 21/28 days regimen. Economic evaluation suggested that the therapy was cost-effective. However, this was a retrospective and somewhat unconventional analysis. Despite claims of efficacy the results of the treatment group were not significantly different from comparator group. These results will require validation in prospective randomized studies.
Aoki et al [13] reported a phase I/II trial of 49 patients with malignant glioma treated with combination of TMZ and ACNU (nimustine). There were 40 patients unrolled in the phase II trial including one cohort from the phase I trial. For patients with GBM (n=33), median PFS was 10 weeks and PFS at 6 and 12 months after this treatment were 21% and 6% respectively. Median OS was 10.3 months for these patients. OS at 6 and 12 months after this treatment were 74% and 44%, respectively. On multivariate analysis treatment response or disease stabilization attained with this therapy was predictive of OS. The use of combination of TMZ and ACNU at progression according to the authors showed equal or non-inferior efficacy in PFS with moderate myelotoxicity with promising results of OS. The authors do not define their conclusions for GBM patients only, but for all their patient population. Hence it is difficult to have any conclusions for pGBM from this study. This study was classified as a class III due to lack of comparison arm.
Wang et al [14] conducted a phase II study of continuous TMZ (50mg/m2 daily) with cisplatin (40, 30, and 30mg administered on days 1, 2, and 3) in 27 patients with pGBM. There was moderate toxicity. The objective response rate (ORR) was 22.2%, median time-to-progression (TTP) was 23 weeks, the PFS-6 was 37%, 12-month progression-free survival (PFS12) was 11.1% and median OS was 50 weeks. The authors concluded that cisplatin with continuous dose-intense regimen of temozolomide had an acceptable level of toxicity and showed activity in patients with recurrent glioblastoma. This regimen showed more activity than most other regimens for recurrent glioblastomas. Limitations of the study include lack of reporting on pseudo-progression. Furthermore, the study had only one group and no comparison group to make definite conclusions regarding the benefit of the addition of cisplatin to TMZ.
Reynes et al [15] conducted a phase II study of metronomic temozolomide (50mg/m2 daily) with irinotecan (100mg/m2 on days 8 and 22 of 28 days cycles) in 27 recurrent glioblastoma patients at first relapse. No responses were observed. Stable disease was seen in 37.5% of patients. PFS-6 was 20.8% and median PFS was 11.6 weeks. Grade 3/4 adverse events included lymphopenia (15%), fatigue, diarrhea and febrile neutropenia (3.7% each), lymphopenia, neutropenia, and nausea/vomiting (11.1% each). One patient died from pulmonary embolism. The authors concluded that the regimen is feasible but failed to improve on the results obtained with other second-line therapies in recurrent glioblastoma.
Di Cristofori et al [16], reported on a prospective single-arm single institution study in 32 patients using dose-dense TMZ (75 – 150 mg/m2) one week on and one week off plus daily tamoxifen (80 mg/m2). OS was 17.5 months and time to progression after recurrence was 7 months. There was minimal toxicity. The authors concluded that combinatorial administration of tamoxifen and dose-dense TMZ was well tolerated and potentially effective. This study was small and without a control arm as such classified as class III evidence.
Franceschi et al [17] reported a retrospective review of 106 patients with recurrent GBM, comparing standard dosing schedule of temozolomide (n=70) with standard schedule nitrosourea chemotherapy (fotemustine and lomustine) (n=36). Progression Free Survival (PFS) was 7.2 and 5.1 months in TMZ and nitrosourea group respectively (p=0.009). When considering patients in the TMZ group with treatment free interval (TFI) > 5 months, PFS was 8.1 months and 5.8 months for patients treated with TMZ or nitrosourea (p=0.020). No difference in PFS was noticed between the two groups for patients with TFI of less than 5 months. Median OS was 14.2 months and was significantly longer for patients on TMZ than those on nitrosourea (15.2 months vs 11.5 months respectively; p=0.020). Patients with TFI > 5 months derived the largest OS benefits from TMZ rechallenge where the median OS was 17.7 months when compared to 11.6 months with patients that received nitrosourea therapy (p=0.014). They concluded that TMZ re-challenge is a treatment options for patients with TFI > 5 months irrespective of MGMT methylation status. This was a retrospective study and as such classified as class III evidence.
Q1-Synthesis
Since the initial guideline publication [1], attempts to improve the dosage of TMZ as described in the Stupp regimen [2005] have continued. These include among others increased TMZ dosage, known as dose-dense TMZ regimen (ddTMZ) and/or daily TMZ, aka metronomic. The rationale for such approach is that prolonged exposure to higher cumulative doses of TMZ could sensitize tumors to the alkylating damage, with toxicity as a natural limiter for such dose escalation.
Our analysis found a lack of adequately powered randomized studies evaluating the role of different TMZ schedules alone or in combination with other drugs in patients with pGBM. Most of the studies are either single arm phase II studies or retrospective studies, providing Class III evidence. None of the studies shows definite benefit of alternative TMZ dosing compared to the conventional TMZ regimen.
There is Class III evidence supporting Level III recommendation that in patients with pGBM, TMZ may be considered, especially in patients that progress after more than 5 months of a TMZ-treatment free interval based on a Class II study [11]. Since, none of these treatment regimens have been compared with each other, a definitive recommendation on the best treatment regimen cannot be made.
Combination of TMZ with other cytotoxic agents such as nitrosourea, cisplatin, electrohypothermia, or tamoxifen did not provide any additional benefit than TMZ alone.
Question (Q2): In adult patients with pGBM does the use of systemic or in situ nistrosourea result in increased overall survival compared to other chemotherapy?
There were 8 studies eligible which examined the use of systemic or in situ nitrosureas for the treatment of pGBM eligible and were included in this analysis. Table 2 summarizes the 8 studies [17-24] that examined the use systemic or in situ nitrosoureas for the treatment of pGBM. These studies provided Class III evidence.
Fotemustine
Marinelli et al [18] reported the results of a Phase I/II single arm trial of fotemustine in 37 patients with recurrent GBM. Fotemustine was administered IV at doses of 120 mg/m2 in 31 patients and 140 mg/m2 in 6 patients every 2 weeks for up to 1 year or until disease progression or intolerable toxicity occurred. Median PFS was 12.1 weeks and OS was 19.7 weeks. Grades 3 and 4 thrombocytopenia occurred in 4 of 6 patients treated with higher dose and in 3 of 31 patients treated with the lower dose. The authors concluded that fotemustine can be safely administered at 120 mg/m2.
Perez-Segura et al [20] reported a retrospective study of 84 patients with recurrent GBM and 30 with other high-grade gliomas treated with fotemustine given with different schedules at first and second recurrence. They did not find any statistically significant difference on survival between different schedules used. They concluded that fotemustine is a safe and has comparable activity with other available options. OS at 12 months was 24.7% and overall PFS was 3 months. We were unable to separate the results for patients with GBM and anaplastic gliomas.
Lombardi et al [21] reported the results of a retrospective review of 44 patients 65 years of age and older with recurrent GBM treated with alternative fotemustine monotherapy at the time of recurrence (80 mg/m2 every 2 weeks for 5 consecutive administrations and then every 4 weeks as maintenance. PFS and OS after recurrence was respectively 4.1 months and 7 months. Patients with MGMT promoter methylation had longer PFS and OS 4.5 versus 2.9 months (p=0.001) and 9.2 versus 4.5 months (p=0.04) respectively. They concluded that elderly patients with methylated MGMT who relapse after TMZ may be best candidates for this therapy. As a retrospective study this was classified as class III evidence.
Santoni et al [24] retrospectively reviewed 65 elderly glioblastoma patients (> 65 years) patients who were treated with fotemustineat 70-100mg/m2 weekly for 3 weeks and then every 3 weeks. The treatment was reasonably well tolerated. 15.3% of patients experienced grade 3-4 thrombocytopenia and 9.2% Grade 3-4 neutropenia. There was some evidence of efficacy with 1.5% CR, 18.5% PR, and 27.7% SD. The PFS6 was 35.4% and OS was 7.1 months. The authors concluded fotemustine was a valuable therapeutic option for elderly glioblastoma patients with a safe toxicity profile. However, the retrospective nature of the study limits firm conclusions.
De Felice et al [25] conducted a very small prospective single-arm single institution study of 8 patients treated fotemustine (induction with 100 mg/m2 weekly for 3 weeks followed 5 weeks later by a maintenance dose of 75 mg/m2 every 3 weeks) and reported a median OS of 7.5 months from recurrence without hematologic toxicity. They concluded that maintenance with low dose of fotemustine could be considered for patients with recurrent GBM. This is a single arm study of only 8 patients and as such was classified as a class III study.
Other nitrosoureas
Carvalho et al [22] reported a study of 60 patients with recurrent GBM that were treated with procarbazine, lomustine (CCNU) and vincristine PCV (n=19) and bevacizumab/irinotecan(BI) (n=41). The median PFS was 3 months and 5 months respectively and median OS was 5 months and 9 months respectively. The PCV group had worse toxicity profile. At one year the percentage of patients alive was greater for the BI cohort. They concluded that BI therapy is a valuable option in recurrent GBM patients. Because of the retrospective nature of the study this was classified as class III evidence.
Systemic and in situ carmustine (BCNU)
Mack et al [23] conducted a retrospective review of 15 recurrent malignant glioma patients (12 with glioblastoma) treated with systemic BCNU (130–150 mg/m2, day 1/42) and VM26 (45–60 mg/m2, days 1–3/42). The median PFS was 2 months and the median OS was 4 months. Two patients (14%) developed grade 3 and/or 4 hematologic toxicity. The authors concluded that the regimen was not beneficial.
Klein et al [19] retrospectively reviewed a cohort of 79 patients with recurrent GBM and methylated MGMT promoter. Twenty-four patients were older than 65 years of age and 39 younger than 65 years of age were treated with BCNU wafer implantation in the surgical bed while 16 patients older than 65 years of age did not receive BCNU implantation. The majority of patients in all groups received systemic TMZ and very few received ACNU (nimustine), CCNU (lomustine), bevacizumab and irinotecan or a combination of these. Median PFS was 9.2 months in the elderly BCNU group and 7.4 months in the non- BCNU group (p=0.34). Median PFS was 6.7 months in younger group. The OS was respectively 17.2 months and 15.9 months (p=0.35) for elderly groups with or without BCNU implantation. The OS was 19 months for the younger patients. Survival depending on the MGMT methylation status did not differ significantly between all groups as well. There was a higher incidence of seizures and pneumonia in older BCNU group however this was not significantly different between the groups. The authors concluded that BCNU wafer implantation is a reasonable safe treatment for patients older than 65 years of age and although there are higher complications, the tradeoff is still favorable. We classified this study as class III because of the retrospective nature. Furthermore, there was no statistically significant difference between groups in terms of survival and complications. A trend toward increased incidence of seizures was noted in the group of patients that received BCNU wafers.
Q2-Synthesis
Six phase II or retrospective studies providing Class III evidence using the systemic nitrosourea fotemustine appear to show modest activity comparable to other nitrosourea in adult patients with pGBM, including in elderly patients. Patients that benefited the most from use of fotemustine appear to be the elderly patients with methylated MGMT promoter status. One study showed some benefit of the combination of bevacizumab and irinotecan but the contribution of the irinotecan component cannot be determined.
The use of in situ BCNU wafers, assessed in one study, showed that in patients treated with Stupp regiment, did not result in statistically significant increase in OS when used in adult patients with pGBM with or without additional undergoing systemic chemotherapy. Therefore, there is insufficient evidence to make a suggestion about the use of in situ nitrosourea in patients with pGBM who underwent the Stupp regimen. Prior to the Stupp regimen, the previous edition of these guideline, based one a single Class II study [3] provided Level II recommendation that in situ BCNU is indicated in patients with pGBM. In that study, although patients showed a modest increase in OS, they sustained a significantly higher complication rate.
To complete the discussion, it must be noted that Lomustine, known as CCNU (chloroethyl-cyclohexyl- nitrosourea), an oral alkylating agent of the nitrosourea family is often used in clinical practice and increasingly used as a control arm in clinical trials testing immune-therapy (these will be reviewed in another section of this guideline). Although this review was not able to identify Class II evidence about this drug, it is gaining a standard-of-care position in the setting of p GBM in Europe, where bevacizumab is not approved, in the EANO guideline [25] and also in the Adaptive Global Innovative Learning Environment for Glioblastoma (AGILE) consortium [26].
Question (Q3): In adult patients with pGBM does the use of cytotoxic therapies other than TMZ and nitrosurea result in increased survival compared to other available chemotherapy?
There were 8 studies eligible which examined the use of systemic chemotherapy other than TMZ or nitrosureas for the treatment of pGBM eligible and were included in this analysis. These studies summarized in Table 3 provided Class III evidence [27-35].
Platinum compounds
Roci et al [31] conducted a retrospective study of 48 high-grade glioma patients including 42 patients with recurrent glioblastoma treated with carboplatin (AUC 5-7) or cisplatin 70 mg/m2 every 4 weeks. 28% of patients had at least a minor response; 49% had stable disease. PFS6 was 18% and median OS was 7 months. The authors concluded that single-agent carboplatin/cisplatin had modest activity in patients with recurrent high-grade glioma previously treated with one line of chemotherapy but the activity was actually minimal.
Tonder et al [33] conducted a retrospective review of 12 heavily pretreated recurrent high grade glioma patients including 8 glioblastoma patients treated with carboplatin (240mg/m2 on day 1) and etoposide (100mg/m2 on days 2 and 3) every 4 weeks. Significant toxicity was observed with grade 3-4 hematologic toxicity in 67% of patients. The median PFS was 2.5 months and the PFS6 was 0%. The authors concluded that carboplatin in combination with etoposide had an unfavorable risk-benefit profile in heavily pre-treated glioma patients.
Topoisomerase inhibitors
Hu et al [35] reported a phase II study of 29 patients with recurrent GBM treated with gimatecan, a lipophilic oral camptothecin analogue with preclinical activity in glioma models. Treatment regimen was 1 mg/m2/day for five consecutive days during 28 day cycle for 12 cycles. Of the 25 patients that the authors could analyze, only 3 (12%) reached PFS-6. The authors concluded that PFS-6 patients treated with gimatecan at the time of recurrence was no significantly better than the historical PFS-6 for these patients.
Others: Perillyl Alcohol and Ketogenic Diet
Da Fonseca et al [34] reported a single center phase I/II trial on 155 pGBM patients using perillyl alcohol (POH) inhalation schedule 4-times daily started with 66.7 mg/dose; 266 mg/day and escalated up to 133.4 mg/dose. POH caused occasional nose soreness (5/198) and rare nosebleed (2/198). A 6-month progression-free survival rate is cited at 48 % for glioblastoma but includes partial responses and stable disease. The survival rate after 24 months of POH treatment was 6.2 % for primary GBM (n=144), and 63% for secondary GBM (n=11). Partial responses were not separated from stable disease. This manuscript is assessed as providing class III data because it is a phase I/II study. The 48% response rate for glioblastoma at 6 months, though initially impressive sounding, includes stable disease. As this is a somewhat nontraditional definition of efficacy, a formal recommendation regarding the use of POH is not warranted.
In a phase I open-label, prospective, single-arm study Rieger et al [32] treated 20 pGBM patients with ketogenic diet, restricting carbohydrate intake to 60 g/day. Feasibility was the primary endpoint, secondary endpoints included the percentage of patients reaching urinary ketosis, progression-free survival (PFS) and overall survival (OS). No serious adverse events attributed to the diet were observed. Urine ketosis was achieved at least once in 12 of 13 (92%) evaluable patients. Median PFS of all patients was 5 weeks (range, 3-13), median survival from enrollment was 32 weeks. One patient achieved a minor response and two patients had stable disease after 6 weeks. All pts had progression on diet alone. Three patients (15%) discontinued the diet for poor tolerability. This study suggests that ketogenic diet alone is not an effective treatment for pGBM patients.
Other cytotoxic therapy
Fiorentini et al [28] Multicenter retrospective controlled study on 28 pts with pGBM treated with modulated electrohyperthermia (mEHT) which combines heat therapy and electric field compared to best supportive care (BSC). Tumor response at the 3-month follow-up was observed in 29% of pGBM treated with mEHT compared to 4% BSC. The median OS for mEHT was 14 months (range 2-108 months). The authors suggested that mEHT may have a promising role in the treatment of pGBM but the small not-controlled nature of the study makes it hard to form any definitive conclusions.
Silvani et al [29] conducted a phase II trial of ortataxel(75mg/m2 every 3 weeks) in 40 recurrent glioblastoma patients. PFS-6 was only 11.4%. 13.2% of patients had grade III/IV neutropenia and hepatotoxicity and 15.8% had grade III/IV leucopenia. The authors concluded that ortataxel failed to demonstrate significant activity in recurrent GBM patients.
Ja et al [30] report on 19 patients with pGBM in a single center prospective phase I trial treated with escalating doses of retinoic acid naphthalene triazole (RANT). Of the 19 treated patients, 5 achieved minor response, 6 remained in stable conditions, none achieve a partial or complete response. Skin erythema, cheilitis and conjunctivitis was observed only at the highest dose 100mg/sqm. This study suggests that RANT toxicity is tolerable with possibly modest clinical activity.
Q3-Synthesis
There is Class III evidence that the use of chemotherapy other than TMZ, including platinum compounds and topoisomerase inhibitors does not result in significant clinical benefit in patients with pGBM. Therefore, these chemotherapies are suggested against being used in patients with pGBM. Current Class III evidence supports that other cytotoxic therapies like perillyl alcohol or ketogenic diet when used alone are suggested against being used in patients with pGBM.
Question (Q4): In adult patients with pGBM does the use of tumor treating field (TTF) result in increased overall survival compared to chemotherapy?
Tumor-treating fields (TTF) is an antimitotic treatment modality that interferes with glioblastoma cell division and organelle assembly by delivering low-intensity alternating electric fields to the tumor Tumor- treating fields (TTF) are an antimitotic treatment that selectively affects dividing GBM cells by delivering low-intensity, intermediate-frequency (200 kHz) alternating electric fields. These cause misalignment of microtubules subunits in the mitotic spindle during the metaphase to anaphase transition and by dielectrophoretic movement of intracellular macromolecules and organelles during the telophase[36-37]. The treatment is delivered using a device consisting of transducer arrays applied to the patient’s scalp and then connected to a portable battery. The Novocure Optune Device, that allows TTF treatment, was given FDA approval for treatment of recurrent GBM in 2011.Table 4 summarizes the studies using TTF for treatment of adult patients with pGBM. In 4 of these, TTF were used alone and in 2 in combination with other cytotoxic chemotherapy [38-43].
Lu at al [38] reported a single center retrospective study reported adults patients with pGBM treated with bevacizumab-based chemotherapy (BBC) +TTF(n=30) or TMZ, bevacizumab, irinotecan (TBI) + TTF. OS and PFS were significantly better for the TBI +TTF group, 18.9 and 10.7 months compared to 11.8 and 4.7 months in the BBC+TTF group. The authors conclude that the TBI regimen might play a role in treatment of adult patients with pGBM.
Kezari and Ram [39] report a post-hoc analysis of the EF-14 trial which was performed in newly diagnosed GBM patients [Stupp et al 2017]. Patients who failed trial EF-14, were treated with TTF+ chemotherapy at first recurrence (n=144) or (n=60) received chemotherapy alone. The median OS was significantly longer than in the experimental group: 1.8 versus 9.2 months. No grade 3 or 4 toxicities were observed. The authors concluded that TTF plus chemotherapy after first disease recurrence on TTF plus TMZ or TMZ alone prolonged OS in patients in the EF-14 trial without added toxicity. This study provides Class III evidence because it is a retrospective analysis of a phase III trial.
Ansstas et al [40] treated a small group of adult patients (n=8) with TTF after they showed evidence of recurrence while treated with bevacizumab. Pulse bevacizumab was re-started at progression. Median OS from last dose of initial bevacizumab was 237 days (7.9 months), twice that of historical controls for bevacizumab failures. They conclude that the use of TTF therapy with pulse dose bevacizumab as an option in patients with refractory GBM.
Wong et al [41] in a single center retrospective study compare two groups of adult patients with pGBM. A small group (n=3) were treated with TTF+bevacizumab+TCCC (6-thioguanine [80 mg/m2 every 6 hour from days 1 to 3] lomustine [100 mg/m2on day 4] capecitabine [825 mg/m2 every 12 hour from day 5] celecoxib 400 mg every 12 hour from days 11 to 24. The cycle is repeated every 42 days or 6 weeks. All medications are oral). The control group received TTF+bevacizumab (n=35). A trend in prolonged OS was found patients treated with TTF+bevacizumab+TCCC. Though TTF is used in this study, it does not provide support for or against the use of TTF in terms of survival or toxicity.
Stupp et al [43] reported a phase III multi-center trial in patients with pGBM treated with TTF (n=120) compared to chemotherapy (n=117), trial known as EF-11. Median OS was 6.6 versus 6.0 months, PFS rate at 6 months was 21.4% and 15.1% (p=0.13), respectively in TTF and chemotherapy patients, thus demonstrating no survival benefit for TTF. Although improvement in OS was not demonstrated, efficacy and activity with this chemotherapy-free treatment device appeared comparable to chemotherapy regimens commonly used for pGBM. Toxicity favored TTF. This paper provided Class II evidence.
Q4- Synthesis
Class II evidence does state that in adult patients with pGBM TTF provides similar survival rates to chemotherapy with decreased toxicity. However, the question here is asking if TTF provides increased survival over chemotherapy. The evidence available is inconclusive or conflicting and insufficient to clearly answer that query. The use of TTF with other chemotherapy could be considered at the discretion of the managing physician when treating adult patients with pGBM based on the class III evidence from four recent papers.
Question (Q5): In adult patients with pGBM does the use of oncolytic virotherapy result in increased survival compared to chemotherapy?
The field of oncolytic virotherapy encompasses any use of viruses with natural or engineered tumor- selective replication to intentionally infect and kill tumor cells. The defining concept of virotherapy is a conditional, tumor-restricted viral replication with subsequent lysis of tumor cells. This selective replication is based on inherent or engineered mechanisms that exploit tumor cell aberrations for viral propagation. While the concept of using live viruses to infect and destroy tumors dates back over a century ago, the ease of creating novel genetically engineered viruses using molecular biology has accelerated the field of oncolytic viral therapy in the last two decades. There were 8 papers that met our eligibility criteria to document their use for treatment of patients with pGBM (Table 5) [43-50]. These studies are all phase I trials providing Class III evidence.
Lang et al [44] reported a single center Phase 1 trial with 37 patients with pGBM treated with the oncolytic adenovirus DNX-2401 (Delta-24-RGD; tasadenoturev). The trial was divided in two phases: Phase I A Dose-escalation with 8 dose levels in 25 pts; Phase IB permanent catheter with intra-tumoral injection followed by resection 14 days later in 12 pts. Dose-limiting toxicities were not observed in the study. 20% of patients survived > 3 years from treatment, and three patients had a = 95% reduction in the enhancing tumor (12%), with all three of these dramatic responses resulting in > 3 years of progression- free survival from the time of treatment. Direct virus-induced oncolysis was documented. Treatment with DNX-2401 resulted in dramatic responses with long-term survival in recurrent high- grade gliomas that are probably due to direct oncolytic effects of the virus followed by elicitation of an immune-mediated anti-glioma response.
Geletneky et al [45] conducted a multi-center phase I/IIa trial (ParvOryx01) using the oncolytic H-1 parvovirus (H-1PV) in 18 patients with pGBM. The study had 2 arms. Arm 1: the first dose of H-1PV was injected intratumorally. Arm 2: five intravenous virus infusions on days 1–5. On day 10, all patients of both arms underwent tumor resection, and virus was re-injected around the resection cavity. H-1PV treatment showed no dose-dependent side effects or dose-limiting toxicity (DLT). PFS at 6 months was 27%, and median PFS was 111 days. OS was 72%, and median OS was 464 days. The Authors concluded that altogether H-1PV results provide an impetus for further H-1PV clinical development.
Cloughesy et al [46] reported on a phase 1, open-label, ascending dose, multicenter trial in 45 pts with recurrent HGG using Toca 511 (vocimagene amiretrorepvec) a oncolytic, retroviral replicating vector (RRV) that delivers a yeast cytosine deaminase, which converts subsequently administered courses of the prodrug Toca FC (extended-release 5-fluorocytosine) into the antimetabolite 5-fluorouracil. OS was 13.6 months and was statistically improved relative to external control. The favorable assessment of TOCA 511 and Toca FC supports confirmation in a randomized phase 2/3 trial (NCT02414165), currently ongoing.
Kicielinski et al [47] conducted a multi-center phase I trial (REOLYSISN trial) in 12 patients with pGBM and 3 high-grade glioma patients using the oncolytic reovirus. This was a dose escalation study ranging from 1 × 10(8) to 1 × 10(10) tissue culture infectious dose 50, ten times the dose achieved in Forsyth et al [2008]. There was 1 grade 3 adverse event (seizure), no grade 4. MTD was not achieved. The intratumoral infusion of reovirus in patients with recurrent malignant glioma demonstrated the approach to be safe and well tolerated, warranting further studies.
Markert et al [48] conducted a single center phase I trial using the oncolytic herpes simplex virus (HSV) G207, a doubly mutated (deletion of both γ134.5 loci, insertional inactivation of UL39) in six pGBM patietns. This was stereotactically inoculated with total two doses of totaling to 1.15 ×109 plaque-forming units. One patient experienced transient fever, delirium, and hemiparesis, which entirely resolved on high-dose dexamethasone. Radiographic and neuropathologic evidence suggestive of antitumor activity was reported. Evidence of viral replication was demonstrated.G207 appears safe for multiple dose delivery, including direct inoculation into the brain surrounding tumor resection cavity.
Forsyth et al [49] conducted a single center phase I trial in Canada on 12 patients with recurrent high grade glioma, 9 of which had pGBM, using the oncolytic reovirus. The Authors injected 107– 109 pfu of reovirus to 3 intratumoral sites in each patient. No significant toxicity was reported and the MTD was not reached. There was one patient with a more than 6-year survival. The Authors concluded that intratumoral administration of the genetically unmodified reovirus was well tolerated using these doses and schedule, in patients with recurrent high grade gliomas.
Freemen et al [50] conducted a single center phase I/II trial using the NDV-HUJ strand of the Newcastle Disease virus (NDV), an avian paramyxovirus with a negative stranded RNA genome, which is not associated with any serious human disease. This was delivered intravenously to 13 patients with pGBM. Toxicity was minimal with Grade I/II constitutional fever being seen in 5 patients. MTD was not achieved. TTP ranged from 2 to 37 weeks. OS ranged from 3 to 66 weeks. Anti-NDV hemagglutinin antibodies appeared within 5-29 days. NDV-HUJ was recovered from blood, saliva, and urine samples and one tumor biopsy. The Authors conclude that the study findings of good tolerability and encouraging responses warrant the continued evaluation of NDV-HUJ in GBM.
Chiocca et al [51] conducted a phase 1 trial with intratumoral injection of the oncolyticadenovirus ONYX-015, an adenovirus mutant that is thought to replicate more efficiently in cells with disruptions in the p53 tumor suppressor pathway (such as tumor cells). Twenty-four patients with recurrent high grade gliomas, including pGBM, received up to 1010 pfu at 10 different sites at the tumor resection border. No significant toxicity was noted. ONYX-015 application was not associated with a therapeutic effect. There were no serious adverse events (AEs). MTD was not achieved. The TTP after treatment with ONYX-015 was 46 days (range 13- 452). The median survival time was 6.2 months (range 1.3 -28.0). The Authors concluded that injection of ONYX-015 into glioma cavities is well tolerated at doses up to 1010 pfu.
Q5-Synthesis
Since the Martuza’s group pioneering study in 1991 [52] over 20 viruses have been recognized as potential oncolytic therapeutic. Our literature review showed 8 clinical trials over 19 years using this therapy in patients with pGBM. The oncolytic viruses tested were adenovirus ONYX-015, adenovirus DNX-240, herpes simplex HSV G207, New Castle disease NCD- HUJ, parvovirus H-1PV, and parvovirus, reovirus. The latter in two phase I trials: one single and one multi-center. Although the safety profile of the above virus seems safe, the benefits have not been shown by studies reviewed.
The oncolytic retroviral replicating vector (RRV) Toca 511 (vocimagene amiretrorepvec) had shown promising benefits on overall survival of pGBM, which warranted the phase II/III trial. This trial concluded after the time of this literature review reporting negative results [53].
Relationship of Quality of Life to Chemotherapeutic Agent Choice
The lack of Class I evidence in treating patients with pGBM and the abundance of Class III evidence raises the question that when evaluating therapeutic interventions quality of life should play a significant role. The writers initially created a question related to this and carried out literature search to address this issue as detailed in Methods, Search #2. Only one paper met our preliminary search criteria assessing the impact of therapy on patients' health-related quality of life (HRQoL). A second paper addressed QoL as a secondary end- point (Table 6) [42,53]
Stockelmaier et al [54] in a prospective multi-center study in 110 cases assessed health-related quality of life (HRQoL) 1 year after diagnosis of recurrent HGG, including 84 with pGBM [ERASMUS trial]. They analyzed the European Organization for Research and Treatment of Cancer Quality of Life core questionnaire and European Organization for Research and Treatment of Cancer Quality of Life Questionnaire-Brain Neoplasm module questionnaires in an unselected cohort. The authors report that patients receiving second-line chemotherapy showed moderately better physical and role functioning as well as less motor dysfunction than patients receiving third-line chemotherapy. Results were available in 92/110 cases. When they compared HRQoL after second-line chemotherapies, patients receiving intensified temozolomide dosages demonstrated a moderately better outcome for cognitive functioning and less communication deficits (P = 0.055) than patients treated with bevacizumab. Regarding number of recurrent surgeries, they found stable HRQoL scores until second recurrent surgery, whereas after third recurrent surgery HRQoL decreased. The authors concluded that their results from an unselected cohort of recurrent HGGs show that the currently available treatment options have no negative impact on HRQoL. Thus, they implied treatment decisions regarding chemotherapy can be made individually, without fear of jeopardizing HRQoL for better survival. However, only 75% of the patients included in this study had progressive glioblastoma and the information from them could not be separated from those without this tumor type and therefore the paper is not eligible for inclusion I this guideline. Additionally, even if the publication met eligibility criteria, quality of life questionnaires could be sent out as late as a year after recurrence. This leads to two sources of substantial bias, firstly, it selects for those that survive longer after recurrence and have a better prognosis and because a year can have elapsed after the treatment progression, recall bias will clearly enter into the provision of information for the forms. Given the ineligibility and bias concerns, use of this paper for creation of a recommendation could not be justified.
As reviewed in the section above (pertinent to Q4) Stupp et al [43] reported a phase III multi-center trial in patient with pGBM treated with TTF (n=120) compared to chemotherapy (n=117), trial known as EF-11. Median OS was 6.6 versus 6.0months, PFS rate at 6 months was 21.4% and 15.1% (p=0.13), respectively in TTF and chemotherapy patients. Improvement in OS was not demonstrated as efficacy and activity with this chemotherapy-free treatment device appeared comparable to chemotherapy regimens commonly used for pGBM. Adverse events were significantly more common in patients undergoing chemotherapy (16% versus 6%). Quality of life (QoL)data was available in 63 patients (27%). In the domains of global health and social functioning no meaningful differences between chemotherapy and TTF were observed. However, cognitive and emotional functioning favored TTF. Physical functioning was slightly worse with TTF, while role functioning favored TTF. Appetite loss, diarrhea, constipation, nausea and vomiting were directly related to the chemotherapy administration. Increased pain and fatigue was reported in the chemotherapy-treated patients and not in the TTF treatment group. That said, data pertinent to QoL comprises only 27% of the study population. Therefore there is no realistic means to conclude the study was adequately powered for quality of life conclusions as the minority of patients provided quality of life responses. Therefore there is insufficient evidence to make a recommendation on QoL related to TTF in comparison to chemotherapy.
The specific question of QoL was not addressed by the pervious guideline [1]. Because this is clearly an important topic across all disciplines within oncology it was initially addressed in this guidelines. Though a number of citations dealing with quality of life were at least tangentially related to progressive glioblastoma, no publications meeting inclusion criteria and performance criteria were identified. The two citations that met preliminary screening and entered in Table 6 are maintained in this document to serve as a resource in future versions of this guideline.