Abstract
Introduction
Rare cases of thrombotic microangiopathy (TMA), manifested as thrombotic thrombocytopenic purpura (TTP) or hemolytic uremic syndrome (HUS), have been reported with interferon β products. We performed a cumulative review of TMA cases recorded in a Global Safety Database for patients with multiple sclerosis who received subcutaneous interferon β-1a treatment.
Methods
Search criteria were: all reported cases, serious and non-serious, from all sources (including non-health care professionals and clinical trial reports), regardless of event ranking and causality assessment by reporter or company. Data lock was May 3, 2014, with additional analysis of cases reported between August 1, 2014–November 30, 2014.
Results
Ninety-one patient cases (76.9% female) with 105 events were retrieved. Time to onset varied from 2 months to 14 years, and in 31.9% of patients the event occurred within 2 years of treatment initiation. Seven patients had a fatal outcome (five were secondary to other causes and two reported insufficient information). Forty-four patients recovered, 32 patients had not recovered at the time of the report, and in eight cases outcome was either not reported or unknown. Treatment was discontinued in 84.6% (77/91) of patients. In 67% (61/91) of patients, the reporter suspected a causal association between treatment and TMA/TTP-HUS. Risk factors and/or confounding factors were present in 45.1% (41/91) of patients. Early prodromal syndrome or specific patterns were not detected, although 54.9% (50/91) of cases contained insufficient information. Overall reporting rate of TMA/TTP-HUS was estimated as 7.2 per 100,000 patient-years. Reporting rates for human serum album (HSA)-containing and HSA-free formulations were 5.72 and 7.68 per 100,000 patient-years, respectively.
Conclusion
No new signal relating specifically to increased frequency of TMA/TTP-HUS with HSA-free subcutaneous interferon β-1a was detected and no additional risk mitigation measures are required regarding the different formulations. The benefit–risk balance of subcutaneous interferon β-1a remains positive, and routine pharmacovigilance monitoring is appropriate.
Funding
Ares Trading SA, Aubonne, Switzerland, a subsidiary of Merck Serono SA.
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Introduction
Interferon (IFN) β is a widely prescribed recombinant-protein therapy with a well-established, favorable safety profile. However, rare cases of thrombotic microangiopathy (TMA) have been associated with different IFN β formulations, including intramuscular IFN β-1a, subcutaneous (sc) IFN β-1a, and sc IFN β-1b [1, 2].
TMA is a pathology expressed as thrombocytopenia, microangiopathic hemolytic anemia, and microvascular occlusion. TMA is common to a number of disorders, including hemolytic uremic syndrome (HUS), thrombotic thrombocytopenic purpura (TTP), malignant hypertension, and renal transplantation. TTP and HUS have distinct pathophysiologies and diagnoses, but there is considerable clinical overlap [3]. In many case reports and series, diagnostic uncertainty exists as ADAMTS 13 (von Willebrand factor-cleaving protease) levels are generally not available, prompting the use of the composite term TTP-HUS [3]. TTP-HUS is characterized by renal insufficiency, neurologic impairment, and fever [4], and risk factors include older age [5], female gender [5], systemic lupus erythematosus [6], shiga toxin-producing bacteria (e.g., Escherichia coli) [3], and concomitant exposure to other treatments (e.g., chemotherapeutic agents, quinine/thiamine, ticlopidine, ibuprofen) [7, 8].
The use of sc IFN β-1a (Rebif®, EMD Serono Inc.) is approved for the treatment of patients with relapsing forms of multiple sclerosis (MS) [9]. sc IFN β-1a has been marketed as a formulation containing human serum albumin (HSA) since February 5, 1998 in Canada, May 4, 1998 in the European Union (EU), and March 7, 2002 in the USA [9]. Since August and September 2007, a HSA-free formulation of sc IFN β-1a has been available in the EU and Canada, respectively. The risk of TMA has been described in the summary of product characteristics (SmPC) for sc IFN β-1a since 2008 [10], and was included in both the EU and US labels. More recently, a cluster of four TMA cases associated with HSA-free sc IFN β-1a was reported in South Scotland from 2010 to 2012 [11].
The aim of this cumulative review was to characterize reports of TMA and TTP-HUS for patients with MS who received sc IFN β-1a (Rebif) from a Global Safety Database, and to determine whether any differences in incidence rates were associated with the introduction of the HSA-free formulation of sc IFN β-1a in 2007.
Methods
Reported cases of TMA, TTP, and HUS in patients with MS who received sc IFN β-1a (Rebif) were cumulatively reviewed in the Global Safety Database (Adverse Reaction Information System global, ARISg; ArisGlobal, CT, USA) for sc IFN β-1a (Rebif) treatment, which comprises data for adverse events (AEs) from clinical trials and post-marketing surveillance reports. Search criteria were: all reported cases, serious and non-serious, from all sources (including non-health care professionals and clinical trial reports), regardless of event ranking and causality assessment by reporter or company. The database was searched using a custom Medical Dictionary for Regulatory Activities (MedDRA v17.0; the International Federation of Pharmaceutical Manufacturers & Associations, VA, USA) search strategy recommended by the Pharmacovigilance Risk Assessment Committee (European Medicines Agency) and developed to capture TMA, TTP, and HUS, using the following MedDRA codes: thrombotic thrombocytopenic purpura, hemolytic uremic syndrome, thrombocytopenic purpura, thrombotic microangiopathy, idiopathic thrombocytopenic purpura, immune thrombocytopenic purpura.
A data lock of May 3, 2014 was used to account for the most recent Periodic Safety Update Report. In addition, a time period of August 1, 2014–November 30, 2014 was used to assess the impact of reporting rates of TMA/TTP-HUS following the circulation of a Dear Healthcare Provider (DHCP) letter. At the request of the European Medicines Agency, the DHCP letter detailed the risks of, and need to monitor for, TTP-HUS in patients treated with sc IFN β-1a, and was circulated to healthcare professionals between August 12, 2014 and October 3, 2014 by manufacturers of sc IFN β-1a (Bayer, Biogen Idec, Merck Serono, Novartis).
Overall and formulation (HSA-containing and HSA-free) reporting rates for sc IFN β-1a were calculated using medically and non-medically confirmed patient cases and patient-exposure data. Patient-exposure data were derived from an internal sales source and based on the number of sc IFN β-1a syringes sold over a period of time. The HSA-containing formulation reporting rate was calculated using: total exposure minus HSA-free sc IFN β-1a exposure. Calculation of formulation reporting rates required assigning all patient case reports to the relevant formulation. As the HSA-free formulation is not available in the USA, all US patient case reports were assigned to the HSA-containing formulation. In countries where the HSA-free formulation has replaced the HSA-containing formulation, all events with an onset date ≥6 months after the launch of the new formulation were assumed to be related to the HSA-free formulation.
The analysis in this article is based on previously conducted clinical studies and post-marketing surveillance reports, and does not involve any new studies of human subjects or animals. There was no change to the medical management of patients, and no randomization of participants to different groups.
Statistical analyses are descriptive and further analyses of data were not feasible as the Global Safety Database includes a population of uncertain size.
Results
Case Presentation: Data Lock May 3, 2014
In total, 91 serious patient cases were retrieved with 105 serious events of TMA, TTP, and HUS associated with sc IFN β-1a treatment; 83.8% (n = 88/105) of events were medically confirmed and 16.2% (n = 17/105) non-medically confirmed. No patient cases or events were non-serious. Most patients (n = 70/91; 76.9%) were female and mean age was 44.5 years (range 17–73 years). Time to onset ranged from 2 months to 14 years with a mean of 4.5 years (n = 91; unknown = 20). In 31.9% (n = 29/91) of patient cases, the event occurred within the first 2 years of treatment.
The distribution of patient cases reporting an event according to formulation and year of receipt generally increased over the defined search period (Fig. 1). Patient cases were geographically distributed across five continents and more than half of cases were reported in France and the USA: 33.0% USA; 20.9% France; 12.1% UK; 9.9% Germany; 7.6% Canada; 4.4% Italy; 2.2% Spain; and 1.1% each for Austria, Brazil, Finland, Greece, Iran, Japan, Slovenia, Switzerland, Turkey.
Broadly, the search terms TMA, TTP, HUS, and TP retrieved a similar number of patient cases (Fig. 2). Seven of 91 patients reported TMA with either TTP or HUS and 13 cases without TTP or HUS. The non-search preferred terms renal failure (n = 22/91; 24.2%) and hypertension (n = 15/91; 16.5%) were relatively frequent, while other non-search preferred terms were relatively rare (Table S1 in the supplementary material). Early prodromal syndrome or specific patterns were not detected, although 54.9% (n = 50/91) of patient cases had insufficient information reported about the course of the event.
Seven of 91 (7.7%) patients had a fatal outcome. Five of these deaths were secondary to other causes (myocardial infarction, sepsis, hemorrhagic shock, acute respiratory distress syndrome, and septic/cardiogenic shock) and the remaining two deaths had insufficient information concerning the cause of death. Of the 84 patients without a fatal outcome, 44 of 91 (48.4%) patients recovered, recovered with sequelae, or were reported as recovering; 32 (35.2%) patients had not recovered at the time of the report; and the outcome was not reported or unknown in eight (8.8%) cases. sc IFN β-1a treatment was discontinued in 84.6% (n = 77/91) patients, maintained in 7.7% (n = 7/91), and unknown in 6.6% (n = 6/91). Treatment with sc IFN β-1a was reintroduced in one patient without recurrence of an event.
A causal association between sc IFN β-1a treatment and TMA/TTP-HUS was suspected in 67.0% (n = 61/91) of cases, not suspected/not related or unlikely in 13.2% (n = 12/91), not reported/unknown in 18.7% (n = 17/91), and “not assessable” in one case. Risk factors and/or confounding factors were present in 45.1% (n = 41/91) of reported cases: 24.2% (n = 22/91) prior or concomitant exposure to other treatments (e.g., chemotherapeutic agents, quinine/thiamine, and ibuprofen), 12.1% (n = 11/91) hypertension, 4.4% (n = 4/91) use of tobacco, 3.3% (n = 3/91) hypercholesterolemia, and 2.2% (n = 2/91) exposure to E. coli serotype. Other risk/confounding factors were each listed in two or fewer cases. For the remaining 54.9% of patients with no confounders reported there was generally insufficient information reported.
Case Presentation: August 1, 2014 to November 30, 2014
No increase in patient case reporting was observed in the short period (August 1, 2014–November 30, 2014) following circulation of the DHCP letters. In total, six serious patient cases were reported during the time period of August 1, 2014 to November 30, 2014. Five cases were reported following the circulation of the DHCP letters from August 12, 2014: two patient cases were reported in Germany and one patient each in France, Netherlands, and Canada.
Patient characteristics for cases reported after August 12, 2014 were similar to the May 3, 2014 data lock. Four of five patients were female. TMA was reported in three cases, and TTP and HUS were each reported in one case. No patients had a fatal outcome. Three patients recovered or were reported as recovering, one patient had not recovered at the time of the report, and the outcome was unknown in one case. sc IFN β-1a treatment was discontinued in three patients, maintained in one patient, and reintroduced in one patient without recurrence of an event.
Reporting Rates
The estimated cumulative exposure to sc IFN β-1a in the post-marketing setting as of May 3, 2014 was 1,259,436 patient-years. Overall reporting rate of TMA/TTP-HUS, including medically and non-medically confirmed patient cases, was 7.2 per 100,000 patient-years (n = 91/1,259,436).
Overall, 46 patients received the HSA-containing formulation and 35 received the HSA-free formulation (five patients received the HSA-free formulation only and 30 patients had received both formulations in countries where the HSA-free formulation was launched); 10 patients had insufficient information relating to the start date for the AE, and/or the dates of sc IFN β-1a treatment, and were therefore assessed as ‘unknown’ for the formulation received at the time of the event. All patients known to have received both formulations experienced the onset of TMA-related AEs >6 months after the launch date of the new formulation, and were therefore all considered as HSA-free sc IFN β-1a cases.
Estimated cumulative exposures for each formulation in the post-marketing setting as of May 3, 2014 were: HSA-free formulation, 455,535 patient-years; HSA-containing formulation, 803,901 patient-years. Reporting rates for the HSA-containing and HSA-free formulations were 5.72 and 7.68 per 100,000 patient-years, respectively. The reporting rate for the five patients receiving the HSA-free sc formulation only (minus patients who received both formulations) was 1.1 per 100,000 patient-years.
Discussion
Practice guidelines for TTP and TMA address the difficulties in diagnosis of the disorders due to overlap with autoimmune disease and state that drugs (including quinine, estrogen-containing medications, and pegylated IFN used to treat hepatitis C) appear to be responsible for <15% of all TTP cases [12]. Nevertheless, no fixed guidelines exist for TMA cases associated with sc IFN β-1a due to the rarity of the disorder and, following a recent cluster of patient reports in South Scotland [11], it was deemed that research was required to identify any differences in incidence rates associated with the introduction of a HSA-free formulation of sc IFN β-1a. The present cumulative review of patient case reports from a Global Safety Database for sc IFN β-1a treatment estimated the overall reporting rate of TMA/TTP-HUS (medically and non-medically confirmed) as 7.2 per 100,000 patient-years using patient-exposure data up to May 3, 2014, which further supports the rarity of TMA/TTP-HUS in this patient population. In addition, no notable association between increased frequency of TMA/TTP-HUS and the HSA-free formulation of sc IFN β-1a could be detected. Reporting rates for the HSA-containing and HSA-free formulations were comparable (5.72 and 7.68 per 100,000 patient-years, respectively), and suggest that the increase in frequency of TMA/TTP-HUS associated with sc IFN β-1a treatment is not associated with the introduction of the HSA-free formulation.
Reporting of TMA associated with sc IFN β-1a treatment generally increased per year over the defined search period. Although the possibility remains that this observation is related to a specific increase in TTP-HUS associated with sc IFN β-1a, we propose that it is instead related to an overall increase in reporting of TMA in general. In addition, using a separate, albeit relatively short, period of August 1, 2014 to November 30, 2014, we observed no increase in reporting rates following the circulation of DHCP letters between August 12, 2014 and October 3, 2014, which suggests that TMA/TTP-HUS was already well reported prior to the safety update.
A number of patient characteristics resulting from our dataset are worthy of discussion in relation to the existing limited literature. The majority (76.9%) of identified patient cases were female, which is consistent with both the underlying disease of MS and the limited literature for TMA associated with sc IFN β-1a treatment [2, 13]. Although reviews of case reports have observed cases of early onset of TMA presentation following sc IFN β-1a treatment [2, 11], our dataset identified no obvious prodromal syndrome; time to onset varied from 2 months to 14 years, with a mean of 4.5 years.
The presence of patient risk factors and confounding factors should also be considered in the rare reporting of TMA/TTP-HUS associated with sc IFN β-1a treatment. Of 91 patients identified in our dataset, 45.1% presented with risk factors and/or confounding factors for TMA, including prior or concomitant exposure to chemotherapeutic agents, quinine/thiamine, and ibuprofen; hypertension; use of tobacco; hypercholesterolemia; and exposure to E. coli serotype. Ibuprofen is used to alleviate flu-like symptoms in patients with MS during treatment with IFN β-1a [14]. Case reports have presented ibuprofen use in patients who developed TMA [15] and TTP [16], although an association has not been reported in patients with MS who received sc IFN β-1a treatment. Regarding E. coli exposure, recent cases of TMA/TTP-HUS associated with sc IFN β-1a treatment were reported in Canada [2] and Scotland [11], and were not geographically localized. In particular, Scotland is known to have higher rates of infection with E. coli O157 than other parts of the UK or Europe [17], and previous surveillance of childhood HUS in Scotland identified E. coli O157 in >90% of cases.
This cumulative review of a Global Safety Database has some limitations. Statistical analysis of data was not feasible as the database includes a population of uncertain size. Patient-exposure data are based on market syringe sales and not patient use, while low adherence or treatment holidays are not accounted for. Consequently, calculation of patient exposure from post-marketing data tends to be underestimated. Due to the difficulty in diagnosing TMA/TTP-HUS [12], some cases may go unreported or may be misdiagnosed. Analysis of data is reliant on the reports included in the safety database and may be affected by differences between countries in reporting of AEs. Despite these limitations, the majority of TMA/TTP-HUS cases associated with sc IFN β-1a within the literature are reported as case reports and this review represents the first detailed analysis of the rare condition in patients with MS.
Subcutaneous IFN β-1a has a well-characterized safety profile and 20 years of follow-up data [18–22], and the excellent benefit–risk balance of sc IFN β-1a remains positive. Results from this study alone do not suggest the need for additional risk mitigation measures for different sc IFN β-1a formulations. As no fixed guidelines exist for the diagnosis and treatment of IFN β-1a-associated TMA, this potential rare condition may be difficult to diagnose and should be considered in MS patients treated with IFN β-1a during routine pharmacovigilance monitoring. Special warnings and precautions in the SmPC include monitoring for worsening angina, congestive heart failure, or arrhythmia [10]. New clinical presentation of hypertension or headache should be evaluated carefully, and monitoring of regular blood pressure is advised. Late-onset cases have been characterized by headache, hypertension, thrombocytopenia, and kidney dysfunction [23, 24]. Latest advice from the Medicines and Healthcare Products Regulatory Agency includes vigilance for early symptoms and prompt treatment [25], as early recognition prevents cases from developing into a severe event and death [12].
Conclusions
In this cumulative review of a Rebif Global Safety Database, reporting rates show that no new signal relating specifically to increased frequency of TMA/TTP-HUS with HSA-free sc IFN β-1a was detected. Routine pharmacovigilance will allow further assessment of risk and confirmation whether additional risk mitigation measures are required. The benefit–risk balance of sc IFN β-1a remains positive.
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Acknowledgments
This study was funded by Ares Trading SA, Aubonne, Switzerland, a subsidiary of Merck Serono SA, and the article processing charges and open access fee were funded by Merck KGaA, Darmstadt, Germany. Medical writing support was provided by Shaun Foley, inScience Communications, Springer Healthcare and funded by Merck KGaA, Darmstadt, Germany. All authors meet the International Committee of Medical Journal Editors (ICMJE) criteria for authorship for this manuscript, take responsibility for the integrity of the work as a whole, and have given final approval for the version to be published.
Conflict of interest
Ali-Frédéric Ben-Amor is an employee of Ares Trading SA, Aubonne, Switzerland, a subsidiary of Merck Serono SA. Anton Trochanov is an employee of EMD Serono, Inc, Billerica, MA, USA. Tanya Z. Fischer is an employee of EMD Serono, Inc, Billerica, MA, USA.
Compliance with ethics guidelines
The analysis in this article is based on previously conducted clinical studies and post-marketing surveillance reports, and does not involve any new studies of human subjects or animals. There was no change to the medical management of patients, and no randomization of participants to different groups.
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Ben-Amor, AF., Trochanov, A. & Fischer, T.Z. Cumulative Review of Thrombotic Microangiopathy, Thrombotic Thrombocytopenic Purpura, and Hemolytic Uremic Syndrome Reports with Subcutaneous Interferon β-1a. Adv Ther 32, 445–454 (2015). https://doi.org/10.1007/s12325-015-0212-6
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DOI: https://doi.org/10.1007/s12325-015-0212-6