Journal List > Infect Chemother > v.49(3) > 1035465

Ann, Kim, Choi, Chang, Han, Kim, Lee, Kim, Park, Kim, Sohn, Yun, Lee, Choi, Lee, and Kim: Safety and Efficacy of Ziagen (Abacavir Sulfate) in HIV-Infected Korean Patients

Abstract

Background

Abacavir is a widely-used nucleoside reverse transcriptase inhibitor for the treatment of human immunodeficiency virus (HIV) infection. Mandatory postmarketing surveillance was conducted in Korea to monitor the safety and evaluate the effectiveness of Ziagen® (abacavir sulfate 300 mg; ViiV Healthcare, Middlesex, UK).

Materials and Methods

An open-label, multi-center, non-interventional postmarketing surveillance study was conducted from June 2010 to June 2016 to monitor the safety and effectiveness of Ziagen across 12 hospitals in Korea. Subjects older than 18 years taking Ziagen according to prescribing information were enrolled. The primary outcome was defined as the occurrence of any adverse events after Ziagen administration. Secondary outcomes included the occurrence of adverse drug reactions, occurrence of serious adverse events, and effectiveness of Ziagen administration.

Results

A total of 669 patients were enrolled in this study, with a total observation period of 1047.8 person-years. Of these, 90.7% of patients were male. The mean age of patients was 45.8±11.9 years. One-hundred ninety-six (29.3%) patients reported 315 adverse events, and four patients reported seven serious adverse events, without any fatal events. There was one potential case of an abacavir hypersensitivity reaction. Among the 97 adverse drug reactions that were reported from 75 patients, the most frequent adverse drug reactions included diarrhea (12 events), dyspepsia (10 events), and rash (9 events). No ischemic heart disease was observed. In the effectiveness analysis, 91% of patients achieved HIV-1 RNA under 50 copies/mL after 24 months of observation with abacavir administration.

Conclusion

Our data showed the safety and effectiveness of Ziagen in a real-world setting. During the study period, Ziagen was well-tolerated, with one incident of a clinically suspected abacavir hypersensitivity reaction. The postmarketing surveillance of Ziagen did not highlight any new safety information. These data may be helpful in understanding abacavir and the HIV treatment practices in Korea.

INTRODUCTION

Abacavir is a nucleoside reverse transcriptase inhibitor (NRTI) used for the treatment of human immunodeficiency virus (HIV) infection. In combination with other antiretroviral agents, abacavir has proven antiretroviral efficacy, which is attributable to its ability to reduce HIV-1 replication and improve immunologic parameters [1234]. Abacavir is one of the first-line recommendations among NRTIs in many international treatment guidelines [567]. It can cause hypersensitivity reactions, especially in patients who are positive for the HLA-B*5701 allele, and the association of abacavir and ischemic heart disease remains inconclusive based on available data [89101112]. Ziagen® (abacavir sulfate 300 mg; ViiV Healthcare, Middlesex, UK) was first approved in Korea in 2001 as an orphan drug and later became available on the market in 2010. We carried out a postmarketing surveillance study to evaluate the safety and effectiveness of Ziagen in a real-world setting.

MATERIALS AND METHODS

1. Study design and population

An open-label, multi-center, non-interventional postmarketing surveillance study was conducted from June 2010 to June 2016 to monitor the safety and effectiveness of Ziagen across 12 hospitals in Korea. Patients with confirmed HIV infection taking Ziagen according to prescribing information were included. Subjects who started Ziagen before the study period were also included, and the observation started on the day consent was obtained. Patients with contraindications for abacavir described in the prescribing information, such as moderate to severe hepatic impairment (Child-Pugh class B or C), end-stage renal diseases (estimated glomerular filtration rate ≤15 mL/min/1.73 m2 or those receiving renal replacement treatments), or confirmed HLA-B*5701 carriers, were excluded. The primary outcome was defined as the occurrence of any adverse events (AEs) following Ziagen administration. Secondary outcomes included the occurrence of unexpected adverse drug reactions (ADRs), occurrence of serious adverse events (SAEs), and the effectiveness of Ziagen administration. Effectiveness was assessed via measurement of changes in plasma HIV-1 RNA viral load and CD4+ T-cell counts for each participant during the study period. Regarding the non-interventional study design, a subjective assessment of clinical improvement was also included for the subjects whose observation period on the study was over 24 weeks. A total of 780 subjects were planned to be enrolled, with an estimated 20% drop out rate, in order to provide 600 evaluable subjects for the primary analysis. This study was approved by the Institutional Review Board of each participating hospitals.

2. Definitions

Based on WHO-ART 092, an AE was defined as any untoward medical occurrence in a subject temporarily associated with the use of Ziagen, whether or not considered related to the medicinal product. An SAE was defined as any untoward medical occurrence at any dose that (1) results in death, (2) is life-threatening, (3) requires inpatient hospitalization or prolongation of existing hospitalization, (4) results in persistent or significant disability/incapacity, or (5) results in a congenital anomaly/birth defect. An ADR was defined as all noxious and unintended responses related to Ziagen. Physicians classified the relatedness of the event to the drug into 6 categories (certain, probable/likely, possible, unlikely, conditional/unclassified, and unassessable/unclassifiable) by WHO-UMC causality categories [13]. If the causality between Ziagen and AEs is considered certain, probable/likely, possible, conditional/unclassified, or unassessable/unclassifiable, the AEs were classified as ADRs. ADRs that are not listed in the Korean prescribing information were classified as unexpected ADRs.

3. Demographic and clinical data

Physician visits were scheduled in accordance with each physician’s routine practice. At the initial visit, demographic information (including subject’s sex, age, height, body weight, and pregnancy status); medical history (including allergy history, renal impairment, hepatic impairment, other concomitant diseases, treatment duration of Ziagen, time since HIV diagnosis, and HIV treatment history); concomitant medications; laboratory values (including viral load); and CD4+ T-cell counts were recorded. Physicians were guided to record any treatment-emergent AEs during the follow-up visits. Results of all HIV-1 RNA viral loads and CD4+ T-cell counts performed within the study period were collected. At the final study visit, the effectiveness of Ziagen was subjectively evaluated as improved, no change, worsened, or not assessed based on the investigator’s medical judgment.

4. Statistical analysis

Continuous variables were expressed as the mean ± one standard deviation, and discrete variables were expressed as the frequency and rate. Once all AEs were classified by preferred terms and system-organ classes, the frequency and percentage of each AE were calculated. Because of the non-interventional design of the study, not all subjects had their HIV-1 RNA viral loads and CD4+ T-cell counts evaluated every 3 months. Test results without an exact date and invalid test results were excluded from the analysis. The available values were collected for each 3-month time frame, and the ratio of participants with HIV-1 RNA <50 copies/mL and mean CD4+ T-cell counts were calculated. Statistical calculation was carried out using SAS version 9.0 (SAS Institute Inc, Cary, NC, USA).

RESULTS

1. Characteristics of study participants

Data were collected from 671 patients; however, due to 2 cases of protocol deviation, 669 patients were included in safety analysis. The total observation period was 1047.8 person-years. The majority (90.7%) of included patients were male. The mean age of patients was 45.8 ± 11.9 years. Patients older than 65 years and those diagnosed with HIV infection within the past year represented 6.9% and 16.4% of the population, respectively. The majority of patients (63.8%) took abacavir with another NRTI plus a boosted protease inhibitor (PI). Patients with concomitant diseases represented 70.3% of the population; eight patients had renal impairment (chronic kidney disease stage 2 to 3 [14]); 43 patients had hepatic impairment (Child-Pugh class A score; Table 1).
Table 1

Baseline characteristics of the subjects included in safety analysis

ic-49-205-i001
Total, n (%) 669 (100)
Male gender, n (%) 607 (90.7)
Age, mean (SD), y 45.8 (11.9)
 18-64, n (%), y 623 (93.1)
 65-80, n (%), y 46 (6.9)
BMI, mean (SD), kg/m2 22.3 (2.9)
Time since HIV diagnosis, mean (SD), y 4.4 (4.0)
 Less than 1 year, n (%) 110 (16.4)
 2-5 years, n (%) 267 (39.9)
 6-10 years, n (%) 216 (32.3)
 Over 10 years, n (%) 61 (9.1)
Duration of Ziagen administration observation, n (%)a
 Less than 3 months 120 (17.9)
 4-12 months 424 (63.4)
 Over 12 months 125 (18.7)
ART regimen at study registration, n (%)
 Ziagen + 1 NRTI + NNRTI 145 (21.7)
 Ziagen + 1 NRTI + PI 427 (63.8)
 Ziagen + 1 NRTI + INI 49 (7.3)
 Others 50 (7.5)
History of any allergy, n (%) 12 (1.8)
Any concomitant diseases, n (%) 470 (70.3)
 Renal impairment 8 (1.2)
 Hepatic impairment 43 (6.4)
 Cardiovascular diseases 101 (21.5)
Concomitant drug use, n (%)
 Antihypertensive drugs 92 (13.8)
 Glucose-lowering drugs including insulin 39 (5.8)
 Lipid-lowering drugs 99 (14.8)
aSubjects who started Ziagen before the study period were also included; the observation began on the day of consent.
SD, standard deviation; BMI, body mass index; ART, antiretroviral therapy; NRTI, nucleoside reverse transcriptase inhibitor; NNRTI, non-nucleoside reverse transcriptase inhibitor; PI, protease inhibitor; INI, integrase inhibitor

2. Safety and tolerability

One-hundred ninety-six patients reported 315 adverse events. The incidence of diarrhea (23/669, 3.4%) was the highest, followed by that of dyspepsia (19/669, 2.8%), dizziness (18/669, 2.7%), pharyngitis (15/669, 2.2%), and rash (14/669, 2.1%).
Four patients reported SAEs. A 72-year-old man presented with nausea, vomiting, fever, and lethargy after 54 days of Ziagen administration. His symptoms resolved within 24 hours of stopping Ziagen use. HLA-B*5701 allele status was not available. The investigator reported that this case may possibly be an abacavir hypersensitivity reaction. Other presentations of cellulitis, abscess formation, and general weakness were determined to not be associated with use of the study drug (Table 2).
Table 2

Clinical characteristics of cases with serious adverse events

ic-49-205-i002
Age Gender Adverse event Treatment duration Outcome Drug cessation Association with Ziagen
1 72 M Nausea, vomiting, fever, lethargy 54 days Resolved Yes Possible
2 80 M Foot cellulitis 209 days Resolved No Unlikely
3 44 M Liver abscess 282 days Resolved No Unlikely
4 40 M General weakness 7 days Resolved No Unassessable
M, male.
Seventy-five patients reported 97 ADRs. Diarrhea was the most common ADR (12/669, 1.8%), followed by that of dyspepsia (10/669, 1.5%), rash (9/669, 1.3%), nausea (7/669, 1.0%), and dizziness (5/669, 0.7%; Table 3).
Table 3

Frequency and expectedness of adverse drug reactions

ic-49-205-i003
Number Incidence, % Listeda
Gastrointestinal
 Diarrhea 12 1.8 Yes
 Dyspepsia 10 1.5 Yes
 Nausea 7 1.0 Yes
 Abdominal pain 2 0.3 Yes
 Vomit 4 0.6 Yes
 Oral ulcer 1 0.1 Yes
Respiratory tract
 Pharyngitis 1 0.1 Yes
 Cough 1 0.1 Yes
 Increased sputum 1 0.1 No
Skin and appendages
 Rash 9 1.3 Yes
 Pruritus 4 0.6 No
 Urticaria 2 0.3 Yes
 Increased sweating 1 0.1 No
 Skin nodules 1 0.1 No
 Dermatitis 1 0.1 No
Nervous system
 Dizziness 5 0.7 Yes
 Numbness 1 0.1 Yes
Systemic disorders
 Fever 2 0.3 Yes
 Worsened general Condition 1 0.1 No
 Fatigue 1 0.1 Yes
 Generalized ache 2 0.3 Yes
 Flush 1 0.1 No
 Chills 1 0.1 Yes
 Weakness 1 0.1 Yes
 Edema 1 0.1 Yes
Psychiatric disorder
 Sleep disorder 2 0.3 Yes
 Loss of appetite 4 0.6 Yes
 Lethargy 1 0.1 Yes
 Bad dreams 1 0.1 Yes
Metabolic disorder
 Hypertriglyceridemia 4 0.6 Yes
 Hyperlipidemia 1 0.1 Yes
 Hypercholesterolemia 1 0.1 Yes
 Dyslipidemia, Unspecified 1 0.1 Yes
Hepatobiliary system
 Hyperbilirubinemia 2 0.3 Yes
 Elevated ALT 3 0.4 Yes
 Elevated AST 3 0.4 Yes
 Jaundice 1 0.1 Yes
Total 97 events (75 patients)
aAEs listed in Korean prescribing information.
ALT, alanine transaminase; AST, aspartate transaminase; AE, adverse event.
In addition to the one possible case of abacavir hypersensitivity reaction, no further cases of abacavir hypersensitivity reaction were reported in this study. No cases of ischemic heart disease were reported.

3. Effectiveness

The proportion of patients who achieved HIV-1 RNA <50 copies/mL increased over time during Ziagen treatment (Fig. 1). A total of 669 patients had initial HIV-1 RNA viral loads. Initially, 44.6% of patients had viral loads below 50 copies/mL; but, after 24 months of abacavir administration, 90.8% of the 76 patients who had a 24-month HIV-1 RNA blood test achieved HIV-1 RNA under 50 copies/mL. In addition, the mean CD4+ T-cell count increased from 334.7 cells/mm3 at baseline to 577.6 cells/mm3 after 24 months of abacavir treatment (Fig. 2). Excluding 158 subjects whose observation duration was less than 24 weeks, 511 of the 669 patients were eligible for the subjective effectiveness analysis. Three-hundred sixty-nine patients (72.2%) were rated as improved, 30 (5.9%) were rated as unchanged; 5 (1.0%) were rated as worsened; and 107 (21%) were non-assessed.
Figure 1
Proportion achieving HIV-1 RNA <50 copies/mL.
aMissing test date or unknown test results.
ic-49-205-g001
Figure 2
Changes in CD4+ T-cell counts.
aMissing test date or unknown test results.
ic-49-205-g002

DISCUSSION

This was a postmarketing surveillance study of 669 patients in Korea designed to observe the safety and effectiveness of Ziagen.
A 3-drug regimen with a 2-NRTI backbone plus one core agent (non-nucleoside reverse transcriptase inhibitor [NNRTI], PI, integrase inhibitor [INI]) has become the standard treatment of HIV infection. Abacavir is one of the most commonly used NRTI backbones, which is recommended in major international treatment guidelines in combination with dolutegravir and lamivudine [6715]. Abacavir is also available as a fixed-dose combination as abacavir/lamivudine and dolutegravir/abacavir/lamivudine.
A total of 669 patients were included in the 6-year postmarketing surveillance study. Due to the introduction of the abacavir/lamivudine fixed-dose combination in 2012 in Korea, recruitment of subjects has been slow since 2014. Most patients were recruited between 2011 and 2013. Male patients accounted for 90.7% of the total study population, reflecting a male-dominant sex ratio in Korea [1617]. In terms of the antiretroviral therapy regimen (Table 1), 63.8% of patients used abacavir with another NRTI and a PI. In comparison with other NNRTI dominance in other Asian countries during the study period, our data reflect the popular use of PI-based regimens in Korea [1819]. Since INIs were only introduced in 2010, a small portion of patients was taking an INI with abacavir in Korea. Although we set HLA-B*5701 carrier status as an exclusion criterion, HLA-B*5701 allele status was unknown in all subjects.
Although generally well tolerated, there have been reports of AEs related to abacavir [120]. In this study, there were four SAEs; however, none of the SAEs were certain or probable/likely linked to the use of Ziagen by investigator assessment. There was one patient (Case 1 in Table 2) presenting with nausea, vomiting, fever, and lethargy on the 54th day of abacavir administration whose condition improved within 24 hours of drug cessation. This case is a clinically suspected abacavir hypersensitivity reaction based on the presenting symptoms and time of resolution after abacavir cessation. Abacavir hypersensitivity may occur in 5% to 8% of patients and requires careful attention, as it can be life threatening without appropriate management [2122]. Abacavir hypersensitivity is strongly associated with the HLA-B*5701 allele; thus, genotypic screening is recommended before the use of abacavir-containing products [8232425]. Research reporting the incidence of HLA-B*5701 varies considerably by ethnicity, and its prevalence can be as low as 0.3% to 0.5% in Korea [262728]. A report showed no HLA-B*5701-positive HIV-infected patients in a study of 534 Korean subjects (95% confidence interval [CI], 0.00-0.69) [28]. This report raised a question about the cost-effectiveness of HLA-B*5701 testing versus careful patient monitoring for abacavir hypersensitivity reactions after prescribing abacavir in regions with a very low incidence of the HLA-B*5701 allele. In our study, the incidence of abacavir hypersensitivity was 0.09 (95% CI, 0.0048-0.4700) per 100 person-years of follow-up.
Although the risk of ischemic heart disease and the use of abacavir were not associated in several recent meta-analyses [1011], the overall evidence is inconclusive [912]. In the present study, no patients using abacavir had evidence of ischemic heart disease. Similarly, no abacavir-related cardiovascular events were observed in the postmarketing surveillance study of abacavir and abacavir/lamivudine in Japan [2029].
The incidences of ADRs were considerably low in our study. The most frequent ADRs reported were gastrointestinal (GI) disturbance, including diarrhea (12 cases, 1.8%), dyspepsia (10 cases, 1.5%), and nausea (7 cases, 1.0%). It is difficult to identify abacavir-specific AEs, since abacavir was used in combination with other medications including antiretroviral drugs and other concomitant drugs. It is interesting to note the low incidence of GI AEs, despite the high proportion of subjects (63.8%) taking boosted PI–based regimens in Korea, which is lower than the 10% reported incidence of GI disturbance in the postmarketing surveillance report in Japan [20]. The lower incidence of GI-related AEs in Korea may require further investigation.
In the effectiveness analysis, we assessed the proportion of patients achieving plasma HIV-1 RNA <50 copies/mL. There were 44.6% of 669 patients with suppressed viral load at the start of study. After 24 months of an abacavir-containing treatment regimen, 90.8% out of 76 patients who had HIV-1 RNA results at 24 months achieved plasma HIV-1 RNA under 50 copies/mL. The mean CD4+ T-cell count increased from 334.7 cells/mm3 at baseline to 577.6 cell/mm3 after 24 months of an abacavir-containing treatment regimen. Without a well-controlled comparator arm, it is hard to evaluate the effectiveness of abacavir as a single agent; however, we could observe a numerically positive virologic and immunologic effect of abacavir-containing antiretroviral therapy from this study.
This study has several limitations. Firstly, it is a postmarketing surveillance study with limited variables. We could not collect actual laboratory results such as serum creatinine and liver enzymes. Secondly, due to the observational study design, interventions for study participants, including prescheduled blood test intervals, were not allowed; the data were inconsistent with regard to the duration of abacavir use or specific intervals of individual viral load testing. Lastly, the study does not include a comparator arm; thus, it is hard to directly attribute the positive effectiveness data solely to the antiviral activity of abacavir. These data may provide supportive information to healthcare practitioners, as our study results reflect positive real-world data of HIV treatment using an abacavir-containing regimen.
In conclusion, we report in a postmarketing surveillance study the real-world data from 669 patients using abacavir. Abacavir was generally well tolerated. The incidence of abacavir hypersensitivity was rare. Cardiovascular AEs were not reported with the use of abacavir in this study. More patients achieved plasma HIV-1 RNA <50 copies/mL with abacavir administration than baseline, and the CD4+ T-cell count was increased from baseline. These results may be helpful for understanding abacavir use and HIV treatment patterns in Korea. We are collecting further safety and effectiveness information for abacavir from spontaneous reports and postmarketing surveillance of other drugs containing abacavir.

Acknowledgements

Heawon Ann, Hyun-Young Choi, Ki-Hyon Kim, and Yil-Seob Lee are employees of GlaxoSmithKline Korea. Editorial assistance was provided under the direction of the authors by MedThink SciCom.

Notes

Funding This work was funded by GlaxoSmithKline Korea.

Conflict of Interest No conflicts of interest.

References

1. Staszewski S, Katlama C, Harrer T, Massip P, Yeni P, Cutrell A, Tortell SM, Harrigan RP, Steel H, Lanier RE, Pearce G. A dose-ranging study to evaluate the safety and efficacy of abacavir alone or in combination with zidovudine and lamivudine in antiretroviral treatment-naive subjects. AIDS. 1998; 12:F197–F202.
crossref
2. Staszewski S, Keiser P, Montaner J, Raffi F, Gathe J, Brotas V, Hicks C, Hammer SM, Cooper D, Johnson M, Tortell S, Cutrell A, Thorborn D, Isaacs R, Hetherington S, Steel H, Spreen W; CNAAB3005 International Study Team. Abacavir-lamivudine-zidovudine vs indinavir-lamivudine-zidovudine in antiretroviral-naive HIV-infected adults: A randomized equivalence trial. JAMA. 2001; 285:1155–1163.
crossref
3. Walmsley SL, Antela A, Clumeck N, Duiculescu D, Eberhard A, Gutiérrez F, Hocqueloux L, Maggiolo F, Sandkovsky U, Granier C, Pappa K, Wynne B, Min S, Nichols G. SINGLE Investigators. Dolutegravir plus abacavir-lamivudine for the treatment of HIV-1 infection. N Engl J Med. 2013; 369:1807–1818.
crossref
4. DeJesus E, Herrera G, Teofilo E, Gerstoft J, Buendia CB, Brand JD, Brothers CH, Hernandez J, Castillo SA, Bonny T, Lanier ER, Scott TR; CNA30024 Study Team. Abacavir versus zidovudine combined with lamivudine and efavirenz, for the treatment of antiretroviral-naive HIV-infected adults. Clin Infect Dis. 2004; 39:1038–1046.
crossref
5. The Korean Society for AIDS. Clinical guidelines for the diagnosis and treatment of HIV/AIDS in HIV-infected Koreans. Infect Chemother. 2011; 43:89–128.
6. AIDS info. Guidelines for the use of antiretroviral agents in HIV-1-infected adults and adolescents. Accessed 14 June, 2017. Available at: https://aidsinfo.nih.gov/contentfiles/lvguidelines/AdultandAdolescentGL.pdf.
7. Günthard HF, Saag MS, Benson CA, del Rio C, Eron JJ, Gallant JE, Hoy JF, Mugavero MJ, Sax PE, Thompson MA, Gandhi RT, Landovitz RJ, Smith DM, Jacobsen DM, Volberding PA. Antiretroviral drugs for treatment and prevention of HIV infection in adults: 2016 recommendations of the international antiviral society-USA panel. JAMA. 2016; 316:191–210.
crossref
8. Mallal S, Phillips E, Carosi G, Molina JM, Workman C, Tomazic J, Jägel-Guedes E, Rugina S, Kozyrev O, Cid JF, Hay P, Nolan D, Hughes S, Hughes A, Ryan S, Fitch N, Thorborn D, Benbow A; PREDICT-1 Study Team. HLA-B*5701 screening for hypersensitivity to abacavir. N Engl J Med. 2008; 358:568–579.
crossref
9. Choi AI, Vittinghoff E, Deeks SG, Weekley CC, Li Y, Shlipak MG. Cardiovascular risks associated with abacavir and tenofovir exposure in HIV-infected persons. AIDS. 2011; 25:1289–1298.
crossref
10. Cruciani M, Zanichelli V, Serpelloni G, Bosco O, Malena M, Mazzi R, Mengoli C, Parisi SG, Moyle G. Abacavir use and cardiovascular disease events: a meta-analysis of published and unpublished data. AIDS. 2011; 25:1993–2004.
11. Ding X, Andraca-Carrera E, Cooper C, Miele P, Kornegay C, Soukup M, Marcus KA. No association of abacavir use with myocardial infarction: findings of an FDA meta-analysis. J Acquir Immune Defic Syndr. 2012; 61:441–447.
12. Rasmussen LD, Engsig FN, Christensen H, Gerstoft J, Kronborg G, Pedersen C, Obel N. Risk of cerebrovascular events in persons with and without HIV: a Danish nationwide population-based cohort study. AIDS. 2011; 25:1637–1646.
13. The Uppsala Monitoring Centre. The use of the WHO-UMC system for standardised case causality assessment. Accessed 14 June, 2017. Available at: http://www.who.int/medicines/areas/quality_safety/safety_efficacy/WHOcausality_assessment.pdf.
14. National Kidney Foundation. KDOQI clinical practice guideline for hemodialysis adequacy: 2015 update. Am J Kidney Dis. 2015; 66:884–930.
15. Korean Society for AIDS. The 2015 clinical guidelines for the diagnosis and treatment of HIV/AIDS in HIV-infected Koreans. Infect Chemother. 2015; 47:205–211.
16. Korea Centers for Disease Control and Prevention (KCDC). Annual report on the notified HIV/AIDS in Korea. Accessed 14 June, 2017. Available at: http://cdc.go.kr/CDC/cms/content/mobile/59/19359_view.html.
17. Korea Centers for Disease Control and Prevention (KCDC). Annual report on the notified HIV/AIDS in Korea. Accessed 14 June, 2017. Available at: http://cdc.go.kr/CDC/info/CdcKrInfo0128.jsp?menuIds=HOME001-MNU1130-MNU1156-MNU1426-MNU1448&cid=28485.
18. Boettiger DC, Kerr S, Ditangco R, Merati TP, Pham TT, Chaiwarith R, Kiertiburanakul S, Li CK, Kumarasamy N, Vonthanak S, Lee C, Van Kinh N, Pujari S, Wong WW, Kamarulzaman A, Zhang F, Yunihastuti E, Choi JY, Oka S, Ng OT, Kantipong P, Mustafa M, Ratanasuwan W, Sohn A, Law M. Trends in first-line antiretroviral therapy in Asia: results from the TREAT Asia HIV observational database. PLoS One. 2014; 9:e106525.
crossref
19. Kim MJ, Kim SW, Chang HH, Kim Y, Jin S, Jung H, Park JH, Kim S, Lee JM. Comparison of antiretroviral regimens: adverse effects and tolerability failure that cause regimen switching. Infect Chemother. 2015; 47:231–238.
crossref
20. Kurita T, Kitaichi T, Nagao T, Miura T, Kitazono Y. Safety analysis of Ziagen® (abacavir sulfate) in postmarketing surveillance in Japan. Pharmacoepidemiol Drug Saf. 2014; 23:361–371.
crossref
21. Bannister WP, Friis-Møller N, Mocroft A, Viard JP, van Lunzen J, Kirk O, Gargalianos P, Bánhegyi D, Chiesi A, Lundgren JD. EuroSIDA Study Group. Incidence of abacavir hypersensitivity reactions in euroSIDA. Antivir Ther. 2008; 13:687–696.
22. Hetherington S, McGuirk S, Powell G, Cutrell A, Naderer O, Spreen B, Lafon S, Pearce G, Steel H. Hypersensitivity reactions during therapy with the nucleoside reverse transcriptase inhibitor abacavir. Clin Ther. 2001; 23:1603–1614.
crossref
23. Saag M, Balu R, Phillips E, Brachman P, Martorell C, Burman W, Stancil B, Mosteller M, Brothers C, Wannamaker P, Hughes A, Sutherland-Phillips D, Mallal S, Shaefer M; Study of Hypersensitivity to Abacavir and Pharmacogenetic Evaluation Study Team. High sensitivity of human leukocyte antigen-b*5701 as a marker for immunologically confirmed abacavir hypersensitivity in white and black patients. Clin Infect Dis. 2008; 46:1111–1118.
crossref
24. Young B, Squires K, Patel P, Dejesus E, Bellos N, Berger D, Sutherland-Phillips DH, Liao Q, Shaefer M, Wannamaker P. First large, multicenter, open-label study utilizing HLA-B*5701 screening for abacavir hypersensitivity in North America. AIDS. 2008; 22:1673–1675.
crossref
25. Rauch A, Nolan D, Martin A, McKinnon E, Almeida C, Mallal S. Prospective genetic screening decreases the incidence of abacavir hypersensitivity reactions in the Western Australian HIV cohort study. Clin Infect Dis. 2006; 43:99–102.
crossref
26. Sun HY, Hung CC, Lin PH, Chang SF, Yang CY, Chang SY, Chang SC. Incidence of abacavir hypersensitivity and its relationship with HLA-B*5701 in HIV-infected patients in Taiwan. J Antimicrob Chemother. 2007; 60:599–604.
crossref
27. Phillips EJ. Genetic screening to prevent abacavir hypersensitivity reaction: are we there yet? Clin Infect Dis. 2006; 43:103–105.
crossref
28. Park WB, Choe PG, Song KH, Lee S, Jang HC, Jeon JH, Park SW, Park MH, Oh MD, Choe KW. Should HLA-B*5701 screening be performed in every ethnic group before starting abacavir? Clin Infect Dis. 2009; 48:365–367.
crossref
29. Kurita T, Kitaichi T, Nagao T, Miura T, Kitazono Y. Safety analysis of Epzicom® (lamivudine/abacavir sulfate) in post-marketing surveillance in Japan. Pharmacoepidemiol Drug Saf. 2014; 23:372–381.
crossref
TOOLS
ORCID iDs

Heawon Ann
https://orcid.org/0000-0003-3170-0109

Shin-Woo Kim
https://orcid.org/0000-0002-3755-8249

Similar articles