About the Authors:

Naho Kuroishi

Roles Conceptualization, Data curation, Investigation, Methodology, Project administration, Writing – original draft

* E-mail: [email protected]

Affiliation: Medical Affairs MSD K.K., Tokyo, Japan

ORCID logo http://orcid.org/0000-0001-6379-2947

Asuka Watananbe

Roles Data curation, Investigation, Methodology, Writing – review & editing

Affiliation: Pharmacovigilance Area MSD K.K., Tokyo, Japan

Ryuta Sakuma

Roles Conceptualization, Data curation, Methodology, Writing – review & editing

Affiliation: Medical Affairs MSD K.K., Tokyo, Japan

Daniel J. Ruzicka

Roles Funding acquisition, Writing – review & editing

Affiliation: Medical Affairs MSD K.K., Tokyo, Japan

Mitsuyoshi Hara

Roles Supervision, Writing – review & editing

Affiliation: Pharmacovigilance Area MSD K.K., Tokyo, Japan

Introduction

Antiretroviral therapy (ART) has dramatically improved the overall survival of people living with human immunodeficiency virus (HIV), but the life-long tolerability of ART has yet to be revealed. Raltegravir (Isentress, Merck & Co., Inc., Kenilworth, NJ, USA) is the world’s first in class of HIV integrase strand transfer inhibitor (INSTI) for the treatment of HIV-1 infection. The safety and efficacy of raltegravir administration in clinical trials for up to 5 years among HIV-infected patients in North American, South American, Australian, and South Asian countries have been previously reported [1–8]. After its approval in 2007 in the United States, 112 other countries also approved raltegravir [9]. In Japan, use of a 400-mg raltegravir tablet twice daily was approved by the regulatory authority in June 2008, and this drug has been marketed in Japan since July 2008. However, the safety and efficacy of raltegravir has not been evaluated in clinical trials specifically targeting Japanese patients.

In Japan, around 1,500 HIV/Acquired immunodeficiency syndrome (AIDS) cases have been reported annually since 2007 and 1,448 HIV/AIDS (1,380 males) cases were reported in 2016. Men who have sex with men (MSM), including bisexual contacts, made up 73% (735/1,011) of all HIV cases and the majority was in their 20’s to 40’s. The cumulative number of reported HIV/AIDS cases (excluding coagulating agent-related cases) was 27,443 as of the end of 2016 [10].

A rapid drug approval process is applied for antiretroviral agents in Japan, and this approval is based on non-clinical and clinical data reported from overseas as an orphan drug. As such, raltegravir was approved for clinical use under the condition of conducting a post-marketing surveillance to collect domestic data on the safety and effectiveness of this agent in clinical practice. Because antiretroviral agents are usually used concomitantly with other anti-HIV drugs, all pharmaceutical companies with an approved anti-HIV drug work together to conduct a HIV-related drug (HRD) cooperative survey [11].

The surveillance of raltegravir through the HRD cooperative survey started at the time of its marketing, in July 2008. To date, no data on the long-term tolerability and effectiveness in Japan of either raltegravir or other INSTI agents are available. Furthermore, only a few studies on the long-term effectiveness of key drug have been conducted in other countries; they include the 12-year experience of nevirapine use in France [12], a 9-year cohort of efavirenz and nevirapine in Senegal [13], a 10-year cohort on efavirenz and nevirapine in Uganda [14], and the 7-year efficacy of a lopinavir/ritonavir-based regimen in the United States [15]. Therefore, the objective of the present study was to assess the long-term tolerability and effectiveness of raltegravir in Japanese clinical practice, using the HRD cooperative survey data collected as post-marketing surveillance over the approximately 9 years from 2008 to 2017.

Methods

Study design

This observational survey used post-marketing surveillance data collected for the HRD cooperative survey and was conducted in accordance with the requirements of the pharmaceutical affairs law and the ministerial ordinance of ‘Good Post-Marketing Study Practice (GPSP)’. At their discretion, investigators of the contracted institutions registered patients who were newly prescribed with particular antiretroviral agents and provided data on the safety and effectiveness of the antiretroviral agents for each treated patient. Patient background information, such as age, sex, comorbidity on administration (including hepatic disease and renal disease), presence of allergy, status of anti-HIV drug use, and concomitant drug use (dose level, dosing period), was collected at registration. Data were collected by filling out a case report form upon registration and annually thereafter. If a patient experienced an adverse event (AE), the corresponding data were reported immediately using the AE report form. The management of the HRD cooperative survey was delegated to CMIC PMS Co., Ltd. (Tokyo, Japan). All data were fully anonymized before the authors of this study accessed them.

Study population

Data on patients registered as newly treated with raltegravir between July 2008 (the beginning of raltegravir marketing) and March 2017 were drawn from the HRD cooperative survey for this study. Of the 33 institutions in which patients were prescribed raltegravir, three institutions did not agree to the disclosure of information, so they were excluded from these analyses.

Ethics statement

This post-marketing surveillance (PMS) conducted in accordance with Good Post-marketing Study Practice for drugs [GPSP; Ministry of Health, Labour, and Welfare (MHLW) ministerial ordinance]. The survey protocol was reviewed and approved in advance by the Pharmaceuticals and Medical Devices Agency (PMDA). The requirements of ethical approval by an institutional review board and informed consent from individual patients for this survey were waived. However, all 30 facilities obtained approval in advance by their institutional review board according to each institutional rule. Names of the 30 facilities were anonymized for publication due to the contract of HRD cooperative survey. Of these 30 facilities, 29 are HIV specialized hospitals, 22 are national or public hospitals, and mean number of beds are 758 (range 135–1,379).

Safety assessments

To assess the safety of raltegravir, AEs and abnormal variations in laboratory test parameters (i.e. haematology test, clinical biochemical test, urine analysis, and ocular abnormalities) were collected during the treatment period. All events with a relationship between the AE and drug were defined as adverse drug reactions (ADRs). AEs and ADRs were classified according to the Medical Dictionary for Regulatory Activities/Japanese version (MedDRA/J Ver.20.0).

Effectiveness assessments

For the assessment of effectiveness, the CD4+ cell counts, HIV-1 RNA levels, and HIV infection clinical stages (i.e. Centers for Disease Control and Prevention [CDC] categories [16]) before and after raltegravir administration (baseline and treatment period) were collected. Infection clinical stages were classified as follows: category A was defined as asymptomatic HIV infection, category B was defined as symptomatic HIV infection, and category C was defined as acquired immunodeficiency syndrome (AIDS).

Statistical analysis

Patient demographics, clinical characteristics, AEs, and ADRs were summarized descriptively from the collected data. The long-term safety of raltegravir was assessed by summarizing the risk of ADRs by the time of occurrence from the start of raltegravir treatment: <90 days, between 90 and <180 days, between 180 and <270 days, between 270 days and <1 year, between 1 year and <2 years, between 2 and <3 years, between 3 and <4 years, between 4 and <5 years, between 5 and <6 years, and ≥6 years. To assess potential risk factors for ADRs, the ADR occurrence was further analysed according to baseline characteristics using a Fisher’s exact test or Cochran-Armitage test. Changes in the median HIV-1 RNA levels and median CD4+ cell counts were calculated over time at 0, 3, 6, 12, 24, 36, 48, 60, 72, 84, and 96 months after the start of raltegravir treatment for treatment-naïve patients and treatment-experienced patients. The proportion of patients with <50 copies/mL of HIV-1 RNA, including blip cases (i.e. patients with <50 copies/mL of HIV-1 RNA with transient increases up to 1,000 copies/mL), was also calculated for the virologic assessment, and its 95% confidential intervals was estimated using Clopper-Pearson method. All statistical tests were two-sided at a significance level of 0.05 and were conducted using SAS Release 9.4 (SAS Institute, Inc., Cary, NC, USA).

Results

Patient disposition

A total of 1,303 patients were prescribed with raltegravir across 30 institutions of the HRD cooperative survey. Of these, 10 patients were excluded due to the fact that their prescription of raltegravir was written before its launch in Japan. 1,293 patients were included for the safety analysis. For the analysis of raltegravir effectiveness, one patient with an off-label use of raltegravir and 115 patients with no recorded CD4+ cell counts, number of HIV-1 RNA copies, or CDC categories either before or after raltegravir administration were excluded. Finally, data from the remaining 1,178 patients were included for the effectiveness analysis (Fig 1).

[Figure omitted. See PDF.]

Fig 1. Patient disposition.

CRF: case report form, CDC: Centers for Disease Control and Prevention.

https://doi.org/10.1371/journal.pone.0210384.g001

Patient demographics and clinical characteristics

The patient demographics and clinical characteristics at baseline are summarized in Table 1. In the safety analysis set (n = 1,293), 94.1% of patients were male, and the median age at baseline was 41 years (Interquartile range, IQR: 34–50 years). The majority of patients belonged to pre-treatment CDC category A (54.5%), followed by categories C (30.9%) and B (6.0%). The prevalence of comorbidity was 68.5%. Hepatic disease and renal disease were present at baseline in 25.1% and 4.9% of the patients, respectively. Comorbidities that were reported in >50 patients at baseline were: pneumocystis jirovecii pneumonia (n = 122; 9.4%), hypertension (n = 99; 7.7%), hyperlipidaemia (n = 68; 5.3%), insomnia (n = 66; 5.1%), diabetes mellitus (n = 55; 4.3%), and hyperuricaemia (n = 50; 3.9%). Most patients (99.1%) were prescribed with a dose of 800 mg of raltegravir per day. The median treatment period from the start of raltegravir administration was 1,123 days, and 84.2% of the patients had been treated with raltegravir longer than 1 year.

[Figure omitted. See PDF.]

Table 1. Patient baseline characteristics.

https://doi.org/10.1371/journal.pone.0210384.t001

Safety analysis

Adverse drug reactions and laboratory abnormalities.

Of 1,293 patients in the safety analysis population, 346 ADRs were reported in 223 patients, with an overall risk rate of 17.25%. Of those, 55 serious ADRs were reported in 31 patients (2.40%). The most common ADRs were abnormal hepatic function (17 events; 1.31%), hyperlipidaemia (14 events; 1.08%), renal impairment (11 events; 0.85%), hyperuricaemia (11 events; 0.85%), liver disorder (11 events; 0.85%), dyslipidaemia (9 events; 0.70%), hypertension (9 events; 0.70%), hypertriglyceridaemia (8 events; 0.62%), immune reconstitution inflammatory syndrome (8 events; 0.62%), insomnia (7 events; 0.54%), and increased blood creatinine levels (7 events; 0.54%) (Table 2).

[Figure omitted. See PDF.]

Table 2. Adverse drug reactions and laboratory abnormalities reported in patients with ≥ 5 events (n = 1,293).

https://doi.org/10.1371/journal.pone.0210384.t002

For predefined events of interest on monitoring the safety of raltegravir, the most frequently reported ADRs that were related to musculoskeletal and connective tissue disorders were back pain (3 events; 0.23%), followed by rhabdomyolysis (2 events; 0.15%) and osteoporosis (2 events; 0.15%) (Table 2, S1 Appendix). As for skin and subcutaneous tissue disorders, pruritus (4 events; 0.31%) and rash (3 events; 0.23%) were reported. The reported cardiac disorder-related ADRs were cardiac failure (2 events; 0.15%) and atrial fibrillation, myocardial infarction, supraventricular extrasystoles, and ventricular extrasystoles (1 event each; 0.08%). Benign, malignant, and unspecified neoplasms were reported as ADRs in 6 cases (0.46%), including Kaposi’s sarcoma (2 events; 0.15%), bladder cancer (1 event; 0.08%), skin papilloma (1 event; 0.08%), squamous cell carcinoma of the lung (1 event; 0.08%), and thymoma (1 event; 0.08%).

Long-term safety.

The ADR risk by the time period from raltegravir treatment initiation was 10.20% (20/196 cases), 16.16% (37/229 cases), 16.13% (40/248 cases), 22.11% (44/199 cases), 18.44% (26/141 cases), and 23.68% (18/76 cases) for treatment durations of between 1 and <2 years, 2 and <3 years, 3 and <4 years, 4 and <5 years, 5 and <6 years, and ≥6 years, respectively (Table 3). In particular, the risk of metabolism and nutrition disorders increased as the raltegravir treatment period lengthened: 1.02% (2/196 cases), 2.18% (5/229 cases), 4.44% (11/248 cases), 7.04% (14/199 cases), 7.09% (10/141 cases), and 10.53% (8/76 cases) after treatment periods of between 1 and <2 years, 2 and <3 years, 3 and <4 years, 4 and <5 years, 5 and <6 years, and ≥6 years, respectively (Cochrane-Armitage test: p < 0.001).

[Figure omitted. See PDF.]

Table 3. Risk of adverse drug reactions by time period from the start of raltegravir treatment.

https://doi.org/10.1371/journal.pone.0210384.t003

Assessment of baseline factors affecting ADR development.

ADR rates were significantly higher in patients with an older age (p = 0.039), CDC category of B (p = 0.019), the presence of any comorbidities (19.86%, p < 0.001), the presence of hepatic disease (22.77%, p = 0.003), the presence of allergic disease (26.49%, p < 0.001), or an increasing number of concomitant medications (p < 0.001) (Table 4).

[Figure omitted. See PDF.]

Table 4. Risk of adverse drug reactions according to baseline characteristics.

https://doi.org/10.1371/journal.pone.0210384.t004

Analysis for effectiveness parameters

Virologic responses.

At the start of the treatment, the median HIV-1 RNA viral loads among the treatment-naïve patients were considerably higher compared with those of treatment-experienced patients (64,000 vs. 39 copies/mL), but this level rapidly decreased to 78.5 copies/mL after one month of raltegravir treatment. Median HIV-1 RNA viral loads in treatment-naïve and treatment-experienced groups each maintained below 40 copies/mL after three months of raltegravir treatment (Fig 2, S2 Appendix). Regarding long-term virologic suppression in both treatment-naïve and treatment-experienced patients, the proportion of patients with HIV-1 RNA viral loads of less than 50 copies/mL (including blip cases) was 81.79% (503/615 cases, 95%CI: 78.51–84.76) at 3 months and 89.47% (620/693, 86.94–91.65) at 6 months, and it exceeded 90% with 92.94% (724/779, 90.91–94.64), 93.70% (654/698, 91.63–95.38), 93.81% (515/549, 91.45–95.67), 93.30% (348/373, 90.26–95.62), 92.09% (198/215, 87.64–95.33), 91.01% (81/89, 83.05–96.04), and 92.00% (23/25, 73.97–99.02) at 12, 24, 36, 48, 60, 72, and 84 months, respectively. Although this proportion reached 100% (95%CI: 29.24–100.00) at 96 months, this group included only three treatment-experienced patients (Fig 3, S3 Appendix).

[Figure omitted. See PDF.]

Fig 2. Changes in the median HIV-1 RNA viral loads of treatment-naïve patients and treatment-experienced patients.

The markers indicate the median.

https://doi.org/10.1371/journal.pone.0210384.g002

[Figure omitted. See PDF.]

Fig 3. Proportion of patients with <50 copies/mL of HIV-1 RNA in patients treated with raltegravir.

Error bars indicate 95% confidence intervals.

https://doi.org/10.1371/journal.pone.0210384.g003

Immunologic responses.

At the start of raltegravir treatment, the median CD4+ cell counts in treatment-naïve patients were lower compared with those in treatment-experienced patients (216 vs. 408 cells/μL), but the CD4+ cell counts in the treatment-naïve group reached 346 cells/μL after 3 months and 522 cells/μL after 36 months of raltegravir treatment (Fig 4, S4 Appendix). The CD4+ cell counts in both the treatment-naïve and treatment-experienced groups displayed an increasing trend throughout the treatment period; the CD4+ cell counts were maintained at over 500 cells/μL after 36 months in treatment-naïve patients and after 48 months in treatment-experienced patients.

[Figure omitted. See PDF.]

Fig 4. Change in median CD4+ cell counts of treatment-naïve patients and treatment-experienced patients.

The markers indicate the median.

https://doi.org/10.1371/journal.pone.0210384.g004

CDC categories.

Most of the patients assessed as belonging to category A (505/512 cases; 98.6%) and category B (51/53 cases; 96.2%) maintained their pre-treatment CDC category even after raltegravir administration. Only nine cases had disease progression.

Discussion

This study was conducted using the results of a nine-year post-marketing surveillance on raltegravir in Japan. Data from 1,303 patients were initially extracted from the HRD cooperative survey, and, after excluding 10 ineligible patients, a total of 1,293 patients were included in the safety analysis. The overall ADR risk (17.25%) in this survey was fairly low, compared with previous international clinical trials reporting the ADR incidence for raltegravir, which ranged from approximately 44%‒61% with study periods spanning 1‒5 years [1–8]. Hyperlipidaemia and abnormal hepatic function were the most commonly reported ADRs in our study, with risks slightly exceeding 1%. No specific tendency was observed in the occurrence of other ADRs, including rash, cardiovascular disorders, elevated creatine kinase, and musculoskeletal and connective tissue disorders (i.e. rhabdomyolysis and myopathy) reported in previous clinical trials with a 2-year maximum of raltegravir administration [1,2,4,17]. Muscle symptoms including myalgia, pain in extremity and rhabdomyolysis (0.31%, 4 cases) and CPK increase (0.15%, 2 cases) were fairly low in this survey, compared with other observational study (SCOLTA project) in patients receiving raltegravir, which were 5.2% and 21.1%, respectively [18]. SCOLTA project also investigated drug-related central nervous system (CNS) symptoms which were 10.4%, whereas all psychiatric and nervous system disorders in this survey were low at 2.01% (26 cases) [19]. As for neoplasms, either benign or malignant, Kaposi’s sarcoma could be considered a disease-specific complication, but the proportion of all remaining malignancies was as low as 0.08%. For long-term safety, no specific tendency was observed in the overall ADR risk by raltegravir treatment period, but the risk of metabolism and nutrition disorders increased as the raltegravir treatment period lengthened. However, nearly 40% of the patients were 45 years of age or older at the initiation of raltegravir and many patients have comorbidities including diabetes mellitus or hyperlipidaemia, therefore it cannot be concluded that the trend was caused by long-term use of raltegravir. Although the risk of malignancies in patients treated with raltegravir should continue to be monitored, the <1% risk of most reported ADRs in this long-term safety assessment of a large Japanese cohort with over 1,000 patients suggests the general tolerability of raltegravir.

The effectiveness analysis was conducted on data from a total of 1,178 patients. The median HIV-1 RNA viral loads in treatment-naïve patients decreased rapidly after one month of raltegravir treatment and were identical in both treatment-naïve and treatment-experienced patients after 3 months of raltegravir treatment. Although decreasing numbers on raltegravir treatment as time goes on, using this as denominator, the proportion of patients with <50 copies/mL of HIV-1 RNA remained at 92.00% (23/25 cases, 95%CI: 73.97–99.02) in patients treated for 7 years, which is higher than or at a similar level as the corresponding proportions reported by previous clinical trials conducted overseas for a maximum of 5 years [1–8], suggesting a long-term virologic suppression by raltegravir treatment in Japanese patients.

Similarly, the median CD4+ cell counts in treatment-naïve patients were initially lower than those in treatment-experienced patients, but they rapidly increased to 346 cells/μL after 3 months of raltegravir treatment and were maintained at >500 cells/μL after 3 years of raltegravir in treatment-naïve patients and after 4 years in treatment-experienced patients. Previous studies reported that the changes in CD4+ cell counts from baseline were 189 cells/μL, 240 cells/μL, and 374 cells/μL in treatment-naïve patients (STARTMRK study) and 109 cells/μL, 123 cells/μL, and 293 cells/μL in patients with triple-class drug resistance in whom previous ART had failed (BENCHMRK-1 and -2 study) after approximately 1 year, 2 years, and 5 years of raltegravir administration, respectively [3–8]. In the present survey, we found an increase by 218 cells/μL, 278 cells/μL, and 325 cells/μL in treatment-naïve patients and by 41 cells/μL, 72 cells/μL, and 127.5 cells/μL in treatment-experienced patients after 1-, 2-, and 5-year treatment with raltegravir, respectively; this result may indicate an equivalent or better improvement regarding CD4+ cell counts resulted from virological suppression in raltegravir-treated Japanese patients. The observed improvement in the immunologic response even for treatment-experienced patients implies that an improvement for patients is likely after changing their ART regimen to include raltegravir.

There are several limitations to the present study. First, our results may be specific to particular groups of patients with HIV infection. The included patients in this study were registered at designated institutions, and, although in principle all patients receiving raltegravir were registered, each enrolment decision was made by contractor investigators. Therefore, a selection bias is inevitable. Second, the effectiveness results in this study cannot be purely attributed to raltegravir because antiretrovirals are commonly used in combinations. The present results support the effectiveness of raltegravir, but they must be interpreted with care. Third, as this data was drawn from HRD cooperative survey conducted by all companies having an HIV drug approved in Japan, we can only extract data of patients still on treatment with raltegravir at the time of the annual report. If patients collected as raltegravir data and switched for viral loads ≥50 copies/mL judged from collected effectiveness data, these patients were counted as failure. However, after they have switched to another ART regimen, we might not have been able to follow them any longer in this study. Therefore, a selection bias for over estimating effectiveness is inevitable. Fourth, as we had no control group for comparison, the safety and effectiveness results for raltegravir cannot be compared with those in HIV-infected patients who received no or other antiretroviral treatments. Last, data on patients who were treated with raltegravir for longer than 7 years were scarce, which may have limited the precision of those results.

In conclusion, long-term treatment with raltegravir is well-tolerated and effective regarding viral suppression, as measured by HIV-1 RNA levels and CD4+ cell counts, in Japanese HIV patients. Such benefits can be expected not only for patients who are about to start antiretroviral therapy but also for patients who switch antiretroviral regimens to one including raltegravir.

Supporting information

[Figure omitted. See PDF.]

S1 Appendix. Adverse drug reactions and laboratory abnormalities reported in patients (n = 1,293).

https://doi.org/10.1371/journal.pone.0210384.s001

(DOCX)

S2 Appendix. Changes in the median HIV-1 RNA viral loads of treatment-naïve patients and treatment-experienced patients.

Detection threshold of HIV-1 RNA viral loads were treated as 39 until 2011, and 19 since 2012.

https://doi.org/10.1371/journal.pone.0210384.s002

(DOCX)

S3 Appendix. Proportion of patients with <50 copies/mL of HIV-1 RNA in patients treated with raltegravir.

aCase counts include blip cases (<50 copies/mL with transient increases up to 1000 copies/mL).

https://doi.org/10.1371/journal.pone.0210384.s003

(DOCX)

S4 Appendix. Change in median CD4+ cell counts of treatment-naïve patients and treatment-experienced patients.

https://doi.org/10.1371/journal.pone.0210384.s004

(DOCX)

Acknowledgments

The authors thank all investigators who conducted the HRD cooperative survey for providing necessary data on patients treated with antiretroviral therapy.

We also thank Mika Kawaguchi of Clinical Study Support, Inc., Nagoya, Japan for writing and editorial assistance, which was provided under contract with MSD K.K., Tokyo, Japan.

Citation: Kuroishi N, Watananbe A, Sakuma R, Ruzicka DJ, Hara M (2019) Long-term tolerability and effectiveness of raltegravir in Japanese patients: Results from post-marketing surveillance. PLoS ONE 14(1): e0210384. https://doi.org/10.1371/journal.pone.0210384