key: cord-1027612-dxvdwpb5 authors: Nishikori, Momoko; Masaki, Yasufumi; Fujii, Nobuharu; Ikeda, Takashi; Takahara-Matsubara, Mariko; Sugimoto, Saori; Kondo, Eisei title: An expanded-access clinical study of thiotepa (DSP-1958) high-dose chemotherapy before autologous hematopoietic stem cell transplantation in patients with malignant lymphoma date: 2021-11-26 journal: Int J Hematol DOI: 10.1007/s12185-021-03263-y sha: 64c3222e79772c71a0b1adedfb8d8fb2bc178e23 doc_id: 1027612 cord_uid: dxvdwpb5 Thiotepa, an antineoplastic ethylenimine alkylating agent that can penetrate the central nervous system, was recently approved in Japan as high-dose chemotherapy prior to autologous hematopoietic stem cell transplantation (HSCT) for patients with malignant lymphoma. To further evaluate the safety and efficacy of thiotepa, a multicenter, open-label, non-comparative, expanded access program was undertaken in Japan, including a larger population of Asian patients with malignant lymphoma. Intravenous thiotepa (200 mg/m(2)/day) was administered over 2 h on days -4 and -3 before scheduled HSCT, plus intravenous busulfan (0.8 mg/kg) over 2 h every 6 h on days -8, -7, -6 and -5. In the safety analysis population (N = 51), 25 patients (49.0%) had primary central nervous system lymphomas. The most common treatment-emergent adverse event was febrile neutropenia (49/51 [96.1%]). No unexpected safety events were observed, and no event resulted in death or treatment modification. Forty-seven patients (92.2%) had engraftment (neutrophil count ≥ 500/mm(3) for three consecutive days after bone-marrow suppression and HSCT). The survival rate at day 100 post-transplantation was 100%. These data confirm the safety of thiotepa prior to autologous HSCT for patients with malignant lymphoma. Trial registration: JapicCTI-173654. SUPPLEMENTARY INFORMATION: The online version contains supplementary material available at 10.1007/s12185-021-03263-y. For patients with high-risk lymphoma, high-dose-chemotherapy (HDT) and autologous hematopoietic stem cell transplantation (HSCT) are administered with curative intent or with the aim of improving survival duration [1] [2] [3] . Thiotepa (DSP-1958) , an antineoplastic ethylenimine alkylating agent that inhibits DNA synthesis [4] , is used as HDT before autologous HSCT in patients with solid or hematologic malignancies [5] . It has the capacity to cross the blood-brain barrier, and is able to rapidly penetrate into the central nervous system (CNS) [6, 7] . Thiotepa has a lengthy medical history, having first been used for the treatment of leukemia [8] and solid tumors [9] in the 1950s. In Japan, thiotepa has been approved for standard-dose chemotherapy since 1958, but manufacturing had been discontinued in 2008 [10, 11] . However, thiotepa was approved in Europe in 2010 as HDT prior to HSCT in adult and pediatric patients [12] . As a result, oncologists in Japan felt that there was a high medical need for thiotepa as HDT prior to autologous HSCT, especially for the treatment of CNS lymphoma. We have previously reported data from a phase 1 study of a thiotepa-containing HDT regimen in nine patients with pediatric solid tumors and 10 adult patients (≥ 16 years) with malignant lymphoma [5] . The results indicated that thiotepa was well-tolerated; the bone-marrow suppression rate was 100% for both pediatric solid tumors and for adult malignant lymphoma, and the engraftment rates were 66.7% and 100%, respectively. Furthermore, the survival rate at day 100 post-HSCT was 77.8% for pediatric solid tumors and 100% for malignant lymphoma. Thiotepa was subsequently approved in Japan as HDT prior to autologous HSCT for pediatric malignant solid tumors in March 2019 and for malignant lymphoma in March 2020 [13] . An expanded access program was initiated to further evaluate the safety and efficacy of thiotepa HDT in larger patient populations prior to gaining marketing approval. The study included pediatric patients with solid tumors or brain tumors and adult patients (≥ 16 years) with malignant lymphoma; herein, we report data from the patients with malignant lymphoma. The key inclusion criteria were male or female patients aged ≥ 16 years with malignant lymphoma who had completed hematopoietic cell collection for autologous HSCT; Eastern Cooperative Oncology Group (ECOG) performance status (PS) of 0-2 assessed within 14 days before enrollment; and normal hepatic, renal, and cardiac function (aspartate aminotransferase and alanine aminotransferase ≤ 3-fold, γ-glutamyl transferase ≤ 2.5-fold, and total bilirubin and creatinine ≤ 1.5-fold the reference range at the clinical site; left ventricular ejection fraction [LVEF] ≥ 50%) based on tests performed within 14 days before enrollment. All patients provided written informed consent prior to study enrollment; for patients aged 16-19 years, written informed consent was also required from their legal representative. Key exclusion criteria were patients who had undergone any treatment (other than hematopoietic cell collection) for the underlying disease within 13 days before the start of study treatment; previous HSCT within the 6 months prior to the study; receipt of live attenuated vaccine within 90 days or any investigational agent within 27 days before the start of study treatment; pregnancy or lactation; present or previous history of complications affecting drug metabolism or excretion; active infection; presence of human immunodeficiency virus antibody, hepatitis B surface antigen or antibody, or hepatitis B core antibody (although patients positive for hepatitis B surface antigen or antibody, or hepatitis B core antibody could be enrolled if vaccinated for type B hepatitis); pericardial effusion, pleural effusion, or ascites requiring treatment or receipt of treatment for these conditions within 14 days before enrollment; hypersensitivity to thiotepa, macrogol 400, or busulfan; and any other reason which may endanger the patient or confound the study outcomes based on the judgement of the study investigator. This was a multicenter, open-label, non-comparative, expanded access program (JapicCTI-173654) which was conducted in patients with malignant lymphoma at four institutions in Japan between September 2017 and June 2020. The study protocol and related documentation were approved by the ethics committee or independent review board of each study center. The study was conducted in accordance with the Declaration of Helsinki, Good Clinical Practice guidelines, and all applicable legal and regulatory requirements. The study design is shown in Fig. 1A . The study comprised a HDT period and a transplant period, with the day of HSCT defined as day 0. Thiotepa (200 mg/m 2 /day) was administered intravenously (IV) over 2 h on day -4 and day -3 before scheduled HSCT. Busulfan (0.8 mg/kg) was administered IV over 2 h every 6 h (i.e., four times daily, for a total dose of 3.2 mg/kg/day) on days -8, -7, -6 and -5 before the scheduled HSCT. The doses of thiotepa and busulfan could be reduced or interrupted if deemed necessary; such decisions were made at the investigator's discretion and no specific dosage modification instructions were mandated by the protocol. Prophylactic administration of anticonvulsants (e.g., sodium valproate) was recommended in the period between 48 h before and 48 h after administration of busulfan, as this drug may cause seizures in patients with malignant lymphoma [14] . The primary study objective was to assess the safety of IV thiotepa as HDT before autologous HSCT in patients with malignant lymphoma. Safety was assessed by recording treatment-emergent adverse events (TEAEs) and adverse drug reactions (ADRs) occurring between the start of study treatment and day 28 post-HSCT, evaluating ECOG PS, and assessing the results of physical and laboratory tests (12-lead electrocardiogram [ECG], LVEF, laboratory measures, vital signs, and body weight). TEAEs were classified using the Medical Dictionary for Regulatory Activities (MedDRA) version 19.1. In this study, the myelosuppression rate was set as an efficacy endpoint and, therefore, hematologic toxicity Thiotepa 200 mg/m 2 /day IV over 2 h on days -4 and -3. b Busulfan 0.8 mg/kg IV over 2 h every 6 h on days -8, -7, -6 and -5. c Three patents did not have validated data; the sponsor was unable to visit one of the study sites to verify the documentation for most of the data due to the institute's COVID-19 precautions within the study period. Therefore, these patients were excluded from all analyses. d Three additional patients did not have validated data for survival at day 100 after HSCT due to the COVID-19 precautions at the same institute. These patients were excluded from the analysis of survival at day 100 after HSCT. Validated data for other measures, including adverse events, were available and these three patients were included in the safety analysis set. e Includes two patients who did not complete the full 100 days (censored) due to termination of the study when thiotepa received regulatory approval for malignant lymphoma. HDT high-dose chemotherapy, HSCT hematopoietic stem cell transplantation, IV intravenously associated with thiotepa-based HDT prior to HSCT was not included in the evaluation of TEAEs. The secondary objective was to assess the efficacy of IV thiotepa in this patient population. Efficacy endpoints included the bone-marrow suppression rate (defined as the proportion of patients with a neutrophil count < 500/mm 3 at least once during the 28 days after HSCT), the engraftment rate (defined as the proportion of patients with a neutrophil count ≥ 500/mm 3 for 3 consecutive days after bone-marrow suppression and HSCT), time to engraftment (evaluated in those patients with evidence of engraftment, and defined as the number of days between HSCT and the first of three consecutive days with a neutrophil count ≥ 500/mm 3 after bone-marrow suppression and HSCT), and the survival rate at day 100 post-HSCT. The overall sample size of approximately 100 patients (including patients with pediatric solid tumors and those with malignant lymphoma) was determined based on the expected number of participants; no formal study size calculations or hypothesis testing was performed. The safety analysis population included all patients who received at least a single dose of thiotepa. The number and frequency of AEs and ADRs were summarized; physical and laboratory test results were reported as summary statistics and ECG interpretations as shift tables. For the efficacy analyses of bone-marrow suppression rate, engraftment rate and time to engraftment, the safety analysis population was used, and missing data were not imputed. The rate of survival at day 100 post-HSCT was estimated using Kaplan-Meier methodology. Death after HSCT (regardless of cause of death) was defined as an event, and observations were censored on the latest date of confirmed survival. Statistical analyses were conducted using SAS software version 9.4 (SAS Institute Inc., Cary. NC, USA). A total of 55 patients with malignant lymphoma were enrolled into the study. Patient disposition is shown in Fig. 1B . One patient discontinued due to physician decision prior to receiving thiotepa. Three patients from one study site were excluded from all analyses, because the sponsor was unable to verify the documentation due to the institute's COVID-19 precautions within the study period. For the same reason, three additional patients at the same institute did not have validated data for survival at day 100 after HSCT, and were excluded from the analysis of survival at day 100 after HSCT. However, as these three patients had validated data for other measures including TEAEs, it was considered that it was ethically and medically desirable to include them in the safety analysis set. Thus, the safety analysis population comprised 51 patients, all of whom underwent HSCT, and the survival analysis population comprised 48 patients. It should also be noted that the survival analysis at day 100 post-HSCT included two patients who did not complete the full 100 days (censored) due to termination of the study when thiotepa received regulatory approval for malignant lymphoma. Baseline demographics and clinical characteristics for the safety analysis set are shown in Table 1 . Overall, 34/51 (66.7%) patients were male, the median age was 54 years (range 38-72), and 30/51 (58.8%) patients had an ECOG PS The dosing schedules for thiotepa and busulfan are shown in Table 2 . All patients in the safety analysis set received 2 days of thiotepa and 4 days of busulfan treatment; median dose intensities for both were 100%. Dose reductions were uncommon. For thiotepa, 4/51 patients had a reduction from 200 mg/m 2 /day, with three of these patients receiving 160 mg/m 2 /day (80% of the expected dose) and one patient receiving 140 mg/m 2 /day (70% of the expected dose). For busulfan, 7/51 patients had a dose reduction from 3.2 mg/kg/day; of these, five patients received 2.56 mg/kg/day (80% of the expected dose), and two patients received 2.24 mg/kg/day (70% of the expected dose). Concomitant granulocyte colony stimulating factor (filgrastim or lenograstim) was received by 45/51 (93.8%) patients in this analysis. TEAEs occurring in ≥ 10% of patients are shown in Table 3 9%]) all occurred in more than half of patients, many of these events were grade 1 or 2. No TEAEs resulting in death or treatment discontinuation or interruption, or dose reduction, were reported during the study. Four patients reported serious TEAEs up to day 28 post-HSCT (hepatic veno-occlusive disease: grade 3, n = 1, grade 4, n = 1; hepatic dysfunction: grade 4, n = 1; hypoxia and viral infection: grade 3 and grade 4, respectively, n = 1). The cases of veno-occlusive disease were considered possibly related to study treatment (ADRs), most likely due to busulfan administration, while the hepatic dysfunction was considered unlikely to be related to study treatment. None of these events had resolved/recovered at the end of the study (i.e., day 28 post-HSCT), but all resolved/recovered during the survival follow-up period. The viral infection was caused by human herpesvirus 6; it was considered possibly related to treatment (ADR), since herpesvirus reactivation in immunodeficient patients is known to be possible. The infection was subsequently reported to be recovered; the event of hypoxia was considered unrelated to treatment and had resolved by the end of the study. One patient had an abnormal, clinically significant ECG change on day 7 post-HSCT, but no longer had a clinically significant abnormality by day 28. No other clinically significant changes in physical or laboratory test values were noted during the study. Efficacy outcomes are summarized in Table 4 . All 51 patients (100.0%) achieved bone-marrow suppression and 47/51 (92.2%) had engraftment. The median time to engraftment in those 47 patients was 11.0 days. The remaining four patients did not meet the narrow definition of engraftment used in this study (a neutrophil count ≥ 500/mm 3 for 3 consecutive days), because blood sampling was not performed on 3 consecutive days; thus the corresponding consecutive neutrophil counts were unavailable. However, each of the four did achieve a neutrophil count ≥ 500/mm 3 at all (> 3) time points evaluated after autologous HSCT day 11. The median follow-up after autologous HSCT was 109 days. The survival rate at day 100 post-HSCT was 100% (Supplementary Fig. 1 ). In this expanded access study, the safety of IV thiotepa as HDT before autologous HSCT in patients with malignant lymphoma was assessed. This was the largest study to date undertaken in Japan of Asian patients treated with a thiotepa and busulfan HDT regimen, and the resulting data provide important information for oncologists when choosing the optimal treatment for their patients with malignant lymphoma. The safety profile of this treatment regimen was acceptable. The most frequently reported TEAEs (febrile neutropenia and gastrointestinal toxicities) were consistent with those reported in adults with malignant lymphoma in the phase I study [5] , and with the European [12] and Japanese [13] product labels. No unexpected safety outcomes were observed. Two patients in this study had an event of hepatic veno-occlusive disease; this event is a known risk in some patients during HDT or following HSCT [16] . No patients discontinued treatment or died due to an AE in this study. A previous single-center analysis of data from 24 patients treated with thioteopa plus busulfan high-dose chemotherapy, which included patients drawn from the phase 1 pharmacokinetic study [5] and also from this expanded access program, reported the occurrence of secondary failure of platelet recovery (SFPR) in three of the patients evaluated after the end of the study period [17] . SFPR is known to be a complication of hematopoietic stem cell transplantation, although it generally occurs more frequently in allogenic than in autologous transplants [18] . As it was considered possible that the development of SFPR may have been associated with the use of busulfan [17] , clinicians using a thiotepa plus busulfan high-dose chemotherapy regimen prior to autologous HSCT should be aware of the possibility of SFPR and ensure that timely treatment can be initiated. The efficacy results indicated that using thiotepa in this regimen was able to contribute to good clinical outcomes for patients, with all patients achieving bone-marrow suppression and > 90% having engraftment. Furthermore, the survival rate at day 100 post-HSCT was also 100%. Although a total of six patients were excluded from the formal analysis of the survival rate at day 100 post-HSCT due to a lack of validated data from one site (resulting from the institute's COVID-19 precautions), all six remained alive at this time point. These findings confirm the efficacy data observed in the prior phase 1 study [5] . Due to its potent ability to penetrate the CNS [6, 7] , thiotepa shows promise for the treatment of PCNSL, and other lymphomas in which lesions are found within the nervous system. Although PCNSL is relatively rare [19] , other types of malignant lymphoma can recur within the CNS [20] [21] [22] , and survival times are often poor [19] [20] [21] . Thus, a treatment which can provide benefit to these patients would be a valuable addition to the current therapeutic algorithms. In [-, -] this study, 49.0% of patients had PCNSL and several others also had CNS lesions; given that 100-day survival in evaluable patients was 100%, these data suggest that thiotepa may be beneficial for the treatment of patients with CNS-based disease. The main study limitations include that the study was conducted in Japan and enrolled only Asian patients with malignant lymphoma, which means that the data may not be generalizable to the global patient population. The 100-day post-HSCT follow-up means that long-term survival data are not available, and further studies are warranted to evaluate outcomes over longer durations. It is possible that the implementation of emergency restrictions due to COVID-19, and patient censoring at study termination (due to drug approval by the regulatory authorities), may have confounded the outcome calculations, but since a very small number of patients were affected, we consider that these events had a limited impact on the overall study findings. In conclusion, the data from this expanded access study confirmed the safety of IV thiotepa as part of the HDT regimen prior to autologous HSCT for patients with malignant lymphoma in Japan. The results confirmed the data reported in the phase I study, but in a larger population, including many patients with CNS-based disease. There were no new safety concerns, and we consider that thiotepa is suitable for administration to this patient population. The online version contains supplementary material available at https:// doi. org/ 10. 1007/ s12185-021-03263-y. 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The authors would like to express our sincere gratitude to all patients and their families who participated in this study. We thank Sally-Anne Mitchell, PhD (McCANN HEALTH CMC, Japan) for providing medical writing support, which was funded by Sumitomo Dainippon Pharma Co., Ltd., in compliance with Good Publication Practice 3 guidelines (https:// www. ismpp. org/ gpp3).