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DOI: 10.31038/CST.2020511

Abstract

Purpose/Objective(s): Valproic Acid (VPA) is an antiepileptic agent with HDACi (histone deacetylase inhibitor) activity shown to radiosensitize glioblastoma (GBM) cells. We evaluated the addition of VPA to standard radiation therapy (RT) and temozolomide (TMZ) in an open- label, phase II study (NCI-06-C-0112). The intent of the current study was to compare our patient outcomes with modern era standard of care data (RTOG 0525) and general population data (SEER 2006–2013).

Materials/Methods: 37 patients with newly diagnosed GBM were treated in a phase II NCI trial with daily VPA (25 mg/kg) in addition to concurrent RT and TMZ (2006 – 2013) and 411 patients with newly diagnosed GBM were treated in the standard TMZ dose arm of RTOG 0525 (2006 – 2008). Using the SEER database, adult patients (age > 15) with diagnostic codes 9440- 9443 (third edition (IDC-O-3) diagnosed between 2006 – 2013 were identified and 6083 were included in the analysis. Kaplan-Meier method was used to estimate OS and PFS. The effect of patient characteristics and clinical factors on OS and PFS was analyzed using univariate analysis and a Cox regression model. A landmark analysis was performed to correlate recurrence to OS and conditional probabilities of surviving an additional 12 months at diagnosis, 6, 12, 18, 24 and 30 months were calculated for both the trial data and the SEER data.

Results: Updated median OS in the NCI cohort was 30.9m (22.2- 65.6m), compared to RTOG 0525 18.9m (16.8–20.3m) (p= 0.007) and the SEER cohort of 11m. Median PFS in the NCI cohort was 11.1m (6.6 – 49.6m) compared to RTOG 0525 with a median PFS of 7.5m (6.9–8.2m) (p = 0.004). Younger age, class V RPA and MGMT status were significant for PFS in both the NCI cohort and the RTOG 0525 cohort, in addition KPS was also significant for OS. In comparison to RTOG 0525, the population in the NCI cohort had a more favorable KPS and RPA, and a higher proportion of patients receiving bevacizumab after protocol therapy however with the exception of RPA (V) (8% vs 18%) (0.026), the effects of these factors on PFS and OS were not significantly different between the two cohorts.

Conclusion: Previously reported improvements in PFS and OS with the addition of VPA to concurrent RT and TMZ in the NCI phase II study were confirmed by comparison to both a trial population receiving standard of care (RTOG 0525) and a contemporary SEER cohort. These results provide further justification of a phase III trial of VPA/RT/TMZ.

Introduction

In the United States, primary brain tumors represent 2% of tumor subtypes with 23,000 new cases and 14,000 deaths per year with grade 4 glioblastoma (GBM) the most common. Standard therapy consists of maximal surgical resection followed by concurrent radiation therapy (RT) and temozolomide (TMZ) followed by adjuvant TMZ, which results in an overall survival (OS) of 27.2% at 2 years and 9.8% at 5 years [1]. Although, the efficacy of this therapy remains limited, attempts to increase the effectiveness of the RT/TMZ protocol [2, 3] have not been successful.

Since the pattern of recurrence following the RT/TMZ combination indicates failure in or adjacent to the initial RT treatment volume, enhancing the effectiveness of RT could lead to an improved therapeutic response. It is this premise that prompted the use of histone deacetylase inhibitors (HDACi) [4, 5]. Inhibition of HDAC activity has been shown to selectively increase tumor cell radiosensitivity in a variety of in vitro models and enhance radiation-induced growth delay of subcutaneous human tumor xenografts [4, 5]. HDACi reduces the repair of DNA double strand breaks (DSBs) leading to radiation-induced cell death [4, 5].

Valproic acid (VPA), a non-enzyme-inducing antiepileptic drug (non-EI-AED), is orally bioavailable, crosses the blood-brain barrier and has minimal toxicity and thus, it provides an attractive option as a radiation sensitizer. In 2006 we initiated a study designed to investigate the safety, tolerability and effectiveness of concomitant RT/TMZ and relatively high dose VPA followed by adjuvant TMZ in patients with newly diagnosed GBM. The previously published median OS in the study was 29.6 months (range: 21–63.8 months) with a PFS of 10.5 months (range: 6.8–51.2 months) while toxicity was similar to that of other phase II studies involving RT/TMZ [6].

Over the past 10 years the reported median survival data for GBM has increased from 14 months to around 20 months [7]. The reasons for this increase are likely multifactorial including a combination of superior surgical resection, earlier initiation of systemic therapies at first recurrence and the management of patients within subspecialized neuro-oncology teams. Since our Phase II NCI trial did not include a standard of care arm, we compared the outcome of the patients treated on our Phase II trial with concurrent VPA with the outcomes of patients who received standard of care concurrent RT and TMZ in the modern era. Thus, we performed a secondary analysis of the RTOG 0525 standard of care arm in conjunction with our NCI data. The most recent molecular RPA based analysis of the RTOG 0525 standard arm included MGMT, Ki-67, mTOR and survivin in addition to age, KPS, extent of resection, and neurologic function, and revealed the median OS times for the three classes as 21.9, 16.6 and 9.4m [7]. Since both the NCI and the RTOG cohorts represent patients treated on trial who as a result tend to have superior outcomes, an additional comparison with data from GBM patients in the SEER database, who are more likely to be more representative of the GBM patient population at large, was also conducted. The intent was to assess the outcome of patients in the Phase II VPA trial in comparison with both modern era GBM patients treated on trial (RTOG 0525) and the population at large (SEER).

Methods and Materials

Patient population

NCI Phase II study of VPA concurrent with chemoirradiation (CRT)

The NCI study was a two center, open-label, phase II study (NCI-06-C-0112) that was conducted in patients with histologically confirmed GBM, aged 18 years or older and a life expectancy greater than 8 weeks, with surgery no more than 6 weeks prior to enrollment. Pathology review was obtained in all patients. Patients were required to have an ECOG performance status ≤ 2 and adequate hematological, renal and hepatic function. Exclusion criteria included previous VPA, chemotherapy or radiotherapy treatment, a known disorder of urea metabolism and any history of a second malignancy other than non-melanoma skin cancer or cervical cancer < 3 years since diagnosis. The concurrent use of sulfamethoxazole, salicylates or naproxen was not allowed. The protocol was reviewed and approved by the NCI Institutional Review Board, and written informed consent was signed by all patients. 37 patients with newly diagnosed GBM were treated in a phase II NCI trial with daily VPA (25 mg/kg) in addition to concurrent RT and TMZ 2006 – 2013.

RTOG 0525 population

The RTOG 0525 study examined the effect of dose dense TMZ on 833 patients randomized to two arms (dose dense vs standard of care). Inclusion and exclusion criteria were largely similar to those of the phase II NCI study (patients older than age 18 years with a newly diagnosed, histologically confirmed GBM, KPS of at least 60 and adequate hematologic, renal, and hepatic function). Having verified that RTOG 0525 shares inclusion and exclusion criteria with our own study, we were specifically interested in the 411 patients who were randomized to and received standard of care in order to facilitate comparison with the phase II NCI study patient population. A secondary analysis request was submitted to NRG for the baseline characteristics (age, sex, KPS, type of surgical intervention, RPA class and MGMT status) of the patient population randomized to standard of care arm in RTOG0525. To further compare the impact of adjuvant treatment between these two populations, we requested the number of cycles of adjuvant TMZ the patient received and whether the patient did or did not receive Bevacizumab. In order to compare OS and PFS as the relevant endpoints we requested time to death or progression for the standard of care arm from initiation of treatment.

SEER population

Using the SEER database, adult patients (age > 15) with diagnostic codes 9440–9443 (third edition (IDC-O-3) diagnosed between 2006 – 2013 were identified and 6083 were included in the analysis. The intention was to analyze the GBM population captured in SEER over a similar time span as the patient populations captured in the NCI study and the RTOG 0525 studies.

Statistical Analysis

Pretreatment characteristics of the Phase II NCI study population and the RTOG 0525 population were compared using log rank test. Outcomes between the two studies were compared using log rank test and cox regression model for confounders. Kaplan-Meier method was used to estimate OS and PFS. The effect of patient characteristics and clinical factors on OS and PFS was analyzed using univariate analysis and a Cox regression model. A landmark analysis [8, 9] was performed to assess residual survival of additional 12 months.

Results

The NCI cohort represents 37 patients on the NCI phase II trial. Patient characteristics including the patient’s performance status and RPA class as well as treatment details and progression and survival outcomes were available, however MGMT status was only available in 51% of the patients as many patients were accrued prior to standard MGMT testing (Table 1). The RTOG 0525 cohort represents 411 patients included on the standard of care arm of RTOG 0525. Similar to the NCI cohort, patient’s characteristics are available and MGMT status was available in 91% of the patients in this cohort (Table 1). In comparison to RTOG 0525, the population in the NCI cohort had a more favorable KPS and RPA, and a higher proportion of patients receiving bevacizumab as salvage (Table1). However, with the exception of RPA (V) (8% vs 18%), the effects of these factors on PFS and OS were not significantly different between the two cohorts (Table 2 and Table 3). Median OS in the NCI cohort was 30.9m (22.2- 65.6m), compared to RTOG 0525 18.9m (16.8- 20.3) (p= 0.003) (Figure 1), and SEER cohort 11m (supplemental table). Younger age, KPS and class V RPA, were significant for OS in both the NCI cohort and the RTOG 0525 cohort while MGMT status was only significant for the RTOG 0525 cohort (Table 2). Median PFS was 11.1 and 7.5m in the NCI study and the RTOG study respectively (Figure 2). PFS was superior in the NCI study as compared to the RTOG study at 6, 12 and 24 months (p=0.0005) (Figure 2). Younger age, class V RPA and MGMT status were significant for PFS in both the NCI cohort and the RTOG 0525 cohort (Table 3). The SEER cohort represents a population of patients captured in the US SEER database. Unlike the NCI or RTOG cohorts, patient’s performance status, RPA class and MGMT status as well as the extent of systemic management and PFS were not recorded within the database and therefore were not available for comparison.

Table 1. Pretreatment  characteristics. Recursive partitioning analysis (RPA), gross total resection(GTR), sub-total resection (STR), valproic acid (VPA), methylguanine-DNA methyltransferase (MGMT), epidermal growth factor receptor (EGFR)

NCI

RTOG 0525

n

%

n

%

P

Age (y)

median

54.3 (range 31–72)

57 (range 22–84)

0.183

Sex

Male

25

68

239

58

Female

12

32

172

42

0.347

RPA

3

13

35

85

21

4

16

43

251

61

5

3

8

75

18

0.026

Unknown/missing

5

14

0

0

KPS

<=90

18

49

321

78

100

19

51

90

22

<0.001

Resection

GTR

19

51

230

56

STR

17

46

167

41

biopsy

1

3

14

3

0.671

MGMT status

methylated

9

24

122

30

unmethylated

10

27

254

62

0.272

unknown

18

49

35

8

BEV given

No

15

40

296

72

Yes

21

57

115

28

<0.001

unknown

1

3

0

0

Table 2. Univariate analysis for OS.

NCI

RTOG 0525

Difference in HR

HR

95% CI

p-value

HR

95% CI

p-value

Pvalue

Age (continuous variable)*

1.6

1.0–2.4

0.046

1.3

1.2–1.4

<0.001

0.399

Age: 50–60 years

2.2

0.8–6.1

0.147

1.6

1.2–2.1

0.002

0.564

Age: > 60 years

3.2

1.0–10.0

0.043

1.8

1.4–2.4

<0.001

0.331

KPS (<=90)

2.7

1.1–6.4

0.029

1.5

1.1–1.9

0.007

0.205

RPA (class IV)

1.8

0.6–5.0

0.266

1.5

1.1–2.1

0.004

0.773

RPA (class V)

5.7

1.3–26.1

0.024

2.2

1.5–3.2

<0.001

0.231

Extent of resection=STR

1.4

0.6–3.1

0.383

1.1

0.9–1.4

0.448

0.53

Avastin (yes)

0.7

0.3–1.6

0.389

0.7

0.5–0.9

0.002

1.00

MGMT (unmethylated)

3.6

0.9–13.9

0.068

1.9

1.5–2.5

<0.001

0.390

*HR corresponds to increase of age by 10 years

Table 3. Univariate analysis for PFS.

NCI

RTOG 0525

Difference in HR

HR

95% CI

p-value

HR

95% CI

p-value

p-value

Age (continuous variable)*

1.3

0.9–2.0

0.156

1.2

1.1–1.3

<0.001

0.59

Age: 50–60 years

1.6

0.6–4.2

0.297

1.4

1.1–1.8

0.008

0.775

Age: > 60 years

2.9

1.0–8.1

0.048

1.5

1.2–1.9

0.002

0.231

KPS (<=90)

1.8

0.8–3.8

0.128

1.1

0.8–1.4

0.517

0.21

RPA (class IV)

1.4

0.5–3.6

0.517

1.2

0.9–1.6

0.128

0.829

RPA (class V)

12.2

2.4–62.9

0.003

1.7

1.2–2.4

0.002

0.021

Extent of resection=STR

1.1

0.5–2.4

0.743

1.1

0.9–1.3

0.482

0.90

Avastin (yes)

1.4

0.6–3.1

0.462

1.3

1.0–1.6

0.029

0.89

MGMT (unmethylated)

3.9

1.0–14.6

0.045

1.6

1.2–2.0

<0.001

0.187

*HR corresponds to increase of age by 10 years

CST 2020-501_Andra Krauze_F1

Figure 1. Overall survival (OS) comparison NCI phase II study, RTOG 0525 and SEER 2006–2013.

CST 2020-501_Andra Krauze_F2

Figure 2. Kaplan-Meier analysis of progression free survival (PFS) between RTOG 0525 and the phase II NCI study examining the addition of Valproic acid (VPA) to concurrent radiation (RT) and temozolomide (TMZ).

Since significant factors that underlie the ability to analyze survival are not available across the all three data sets, a landmark analysis was used to estimate the survival probabilities in each of the data sets conditional on the patients having survived at least 6 months. From the analysis, with a landmark time of 6m, the percent of patients surviving an additional 12m was 77, 57 and 43 in the NCI study, RTOG 0525 and SEER respectively (Table 4). The difference was statistically significant at the initiation of treatment, at 6m and at 18m. VPA patients’ survival was superior to both RTOG and SEER patients up until 30m when they coalesced to a similar likelihood of surviving an additional 12m (Figure 3).

Table 4. Landmark analysis. Probability and 95% CI of surviving additional 12 months.

NCI

RTOG

SEER

Time from initiation of treatment (months)

Probability of surviving additional 12 months

Lower 95% CI

Upper 95% CI

Probability of surviving additional 12 months

Lower 95% CI

Upper 95% CI

P

Probability of surviving additional 12 months

Lower 95% CI

Upper 95% CI

P-value*

0

0.92

0.83

1

0.70

0.66

0.75

<0.001

0.45

0.44

0.47

0.000

6

0.77

0.64

0.92

0.57

0.52

0.62

0.010

0.43

0.42

0.45

<0.001

12

0.61

0.46

0.81

0.49

0.43

0.55

0.167

0.43

0.41

0.44

0.032

18

0.71

0.55

0.92

0.51

0.45

0.59

0.049

0.48

0.46

0.51

0.016

24

0.73

0.53

1

0.62

0.53

0.72

0.385

0.56

0.53

0.59

0.165

30

0.69

0.47

1

0.61

0.5

0.75

0.610

0.62

0.58

0.65

0.587

*Comparing survival probability between NCI and SEER

CST 2020-501_Andra Krauze_F3

Figure 3. Landmark analysis – Kaplan-Meier survival estimate vs. timing of recurrence using landmark analysis setting the landmark time at 6 months.

Discussion

In recent years the published outcomes of GBM patients on trial has improved as compared to published Stupp data [1, 7], nonetheless, outcomes for GBM patients remain poor. Between 2006 and 2013 we carried out a Phase II trial with the goal of investigating the safety, tolerability and effectiveness of concomitant RT/TMZ and relatively high dose of VPA followed by adjuvant TMZ in patients with newly diagnosed GBM [6]. In order to compare the outcome of our Phase II NCI study with modern GBM treatment and outcomes, we performed a secondary analysis of the standard of care arm of RTOG 0525. To ensure adequate comparison with the GBM population at large, we also carried out a SEER analysis spanning the same time period as the previous two trials (2006–2013). The NCI study and RTOG study patients were sufficiently similar to allow for a meaningful analysis although the NCI patients had superior KPS, RPA and use of Bevacizumab. None of these factors were found to have a statistically significant impact on the analysis. We found that the NCI study patients had a superior PFS and OS compared to either the RTOG 0525 patients or the SEER patients, who in turn had the poorest survival.

Median OS for the NCI patients far surpassed RTOG 0525 and the SEER cohort outcomes at 30.9m (22.2–65.6). It also surpassed other modern published GBM data [2,3,7]. The effect observed on OS was sustained to 30 months post initiation of treatment. In recent years, landmark analyses have been employed in order to contextualize outcome results by clarifying the relationship between progression and survival [8, 9]. We carried out a landmark analysis on the premise that those patients that had not died at the 12 month time point may have superior biological behavior possibly distinguished by biomarkers such as MGMT, Ki-67, survivin or mpTOR as well as other as yet undiscovered biomarkers which may correlate with the administration of VPA. The analysis suggests a significant benefit to the administration of VPA with 71% of patients having a probability of surviving another 12 months at the 18m time point in the NCI study as compared to 51% in the RTOG 0525 and 48% in the SEER cohort. The data also showcases that fact that the modern day RTOG 0525 cohort, presumably representing a highly selected, superior performing population nonetheless has probability of surviving another 12 months that is very similar to the SEER cohort once they pass the 6m time point. By contrast the NCI VPA treated cohort approaches similar probabilities of survival to the SEER cohort much later, approaching 30 months. This could indicate a potential alteration in tumor biology that occurs in patients treated with VPA which could be explored further in larger cohorts.

In our phase II study we explored the effectiveness of VPA as a radiosensitizer [6] and the hypothesis that VPA favorably alters tumors response continues to be explored in the literature [10–18]. While a recent analysis of four contemporary randomized clinical trials [14] showed no improvement in outcome to the addition of VPA, dose dependency was not addressed in this analysis and existing data suggests that the effect of VPA is dose dependent [15]. By contrast a 2014 meta-analysis suggested improved survival of patients with VPA administration [16, 17] although dose response was not addressed. It is possible that the effects of VPA may include modification of tumor behavior that may be both disease and dose dependent. Biomarker studies aimed at exploring possible avenues underlying the effects of VPA are ongoing within the NCI study cohort and in the literature at large [18].

There are several limitations to our analysis, including the fact that the number of patients on the standard of care arm in RTOG 0525 (411) greatly exceeded the number of patients in the NCI study (37), and that MGMT status was unknown in 49% of NCI study patients, as the bulk of the study was carried out preceding the era of wide spread MGMT methylation testing. In the phase II NCI study time to death or progression was calculated from the initiation of VPA which preceded the initiation of RT and TMZ by 1 week, while in RTOG 0525 time to death or progression was calculated from initiation of concurrent CRT and it was not possible to account for this discrepancy, although the difference of 1 week is unlikely to significantly alter our conclusions. In addition, progression on RTOG 0525 was determined according to Macdonald criteria, whereas the NCI study used RECIST criteria, although both studies accounted for pseudoprogression in determining response. However since SEER does not capture patient characteristics such as KPS, RPA, progression data or MGMT status, a comparison of these characteristics between the NCI study and RTOG 0525 and SEER was not possible. We understand that while anticonvulsant (AED) usage was collected on RTOG 0525, the use of VPA specifically, as a type of AED was not collected.

Conclusion

Previously reported improvements in PFS and OS with the addition of VPA to concurrent RT and TMZ in the NCI phase II study were confirmed in comparison to both a trial population receiving standard of care (RTOG 0525) and a contemporary SEER cohort. These results warrant further consideration of VPA for analysis in a phase III trial.

Declarations

Ethics approval and consent to participate

This study reports on data collected from humans. This research was exempt from NCI IRB approval as one of the six exemptions to the regulatory requirements are described in section 46.101(b) of 45 CFR 46, subsection (4): Research involving the collection or study of existing data, documents, records, pathological specimens, or diagnostic specimens, if these sources are publicly available or if the information is recorded by the investigator in such a manner that subjects cannot be identified, directly or through identifiers linked to the subjects.

Supplemental Table. Comparison of PFS and OS between NCI and RTOG  0525 study cohort. Log-rank test was employed to compare PFS and OS between NCI and RTOG 0525 study cohort and between the  NCI and SEER cohort.

NCI (n=37)

RTOG 0525 (n=411)

SEER GBM 2006–2013
(n=6083)

PFS

OS

PFS

OS

OS

# of events (%)

30 (81)

27 (73)

374 (91)

320 (78)

5359 (88)

median (months)(95% CI)

11.1 (8.0,51.9)

30.9 (22.2, 65.6)

7.5 (6.9, 8.2)

18.9 (16.8, 20.3)

11

6 months (%)

78.4 (66.2, 92.8)

97.3 (92.2, 100)

61 (56.5,65.9)

91.9 (89.3,94.6)

65.5 (64.3,66.7)

12 months (%)

45.9 (32.4,65.2)

91.7 (83.2,100)

30 (25.9,34.8)

70.4 (66.1,75)

45.5 (44.2,46.7)

24 months (%)

37.8 (25,57.2)

56.4(41.9,75.8)

14.4(11.3,18.2)

34.2 (29.9,39.2)

20.7 (19.6,21.8)

p-value*

0.0005*

0.003*

<0.001**

*Log-rank test comparing PFS and OS between NCI and RTOG0525 study cohort;

**log-rank test comparing OS between NCI and SEER cohort

Availability of data and material

The datasets supporting the conclusions of this article are included within the article and its additional files.

Funding

This work was supported in part by the Centers for Cancer Research, NCI. #ZIASC 010372.

Authors’ contributions

AVK conceived the study, participated in its design and coordination, collected patient data, performed statistical data analysis and drafted the manuscript.

MSD, CMG, DJH, SS, RL treated patients included in the original phase II study and RTOG 0525 (MG) and collected patient data.

JS performed the statistical data analysis.

KC, PJT conceived the original NCI phase II study.

KC and AVK conceived the secondary analysis and participated in draft of the manuscript.

Acknowledgements

This work was supported in part by the intramural program of the NCI under funding ZIA-SC- 010373.

List of Abbreviations

CRT – Concurrent Chemoirradiation CNS – Central Nervous System

EORTC – European Organisation for Research and Treatment of Cancer GBM – Glioblastoma

KPS – Karnofsky Performance Status MRI – Magnetic Resonance Imaging NCI – National Cancer Institute

OS – Overall Survival

PFS – Progression Free Survival

RPA – Recursive Partitioning Analysis RT – Radiation Therapy

TMZ – Temozolomide

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Article Type

Research Article

Publication history

Received: December 12, 2019
Accepted: January 06, 2020
Published: January 11, 2020

Citation

Andra Krauze, Megan Mackey, Theresa Cooley-Zgela, Peter Mathen, Shih JH, et al. (2020) The Addition of Valproic Acid to Concurrent Radiation Therapy and Temozolomide Improves Patient Outcome: A Correlative Analysis of RTOG 0525, SEER and A Phase II NCI Trial. Cancer Stud Ther J Volume 5(1): 1–8. DOI: 10.31038/CST.2020511

Corresponding author

Andra Krauze,
Radiation Oncology Branch,
Center for Cancer Research,
National Cancer Institute,
NIH, 9000 Rockville Pike,
Building 10, CRC Bethesda,
MD 20892, USA;
Tel: (301) 496-5457; Fax: (301) 480-5437;
E-mail: andra.krauze@bccancer.bc.ca