Abstract
Cabotegravir and rilpivirine long-acting injectable antiretroviral therapy for the treatment of HIV-1 infection brings promise of a new mode of delivery and potential solutions to some problems of oral therapy, but also new challenges and unanswered questions. Adding to the increasing body of evidence for newer two-drug combinations, phase II and phase III trial data to date demonstrate cabotegravir and rilpivirine combination injectable therapy to be non-inferior to selected oral triple-therapy alternatives. Most importantly, this therapy is reported to be acceptable to individuals taking the 4-weekly or 8-weekly injections, despite frequent injection-site reactions. Key outstanding questions include management of missed or delayed dosing, drug interactions and management of virological failure, as well as the efficacy of cabotegravir and rilpivirine in all HIV-1 subtypes. We describe clinical evidence to date and efficacy and challenges in selected populations, including women; those with prior virological failure; individuals with a history of difficulty adhering to oral therapy and individuals with co-infections. We await real-world data and longer-term evidence while moving forward to this new era of antiretroviral therapy.
Keywords: antiretroviral therapy, integrase inhibitors, non-nucleoside reverse transcriptase inhibitors
Introduction
The global response to HIV (human immunodeficiency virus) has meant more people living with HIV (PLWH) are diagnosed, on treatment and living longer than ever before.1 But there still remain several unmet needs in HIV treatment across the globe, including more tolerable treatments, easier to adhere to, and, stemming from the UNAIDS 90-90-90 targets,2 addressing the “4th 90”: improvement of quality of life in those living and aging with HIV.3,4
Long-acting (LA) injectable therapy offers much-reduced dosing frequency and an additional option among two-drug combinations now available. Delivery of LA injectable antiretroviral therapy (ART) may require a conformational change in HIV healthcare delivery for some, with possibilities for more innovative, patient-centered health care models.
Pre-clinical data on LA cabotegravir and detail on rilpivirine pharmacokinetics have been described previously.5,6 Here, we describe phase II and III clinical trials, discuss resistance and suitability for specific populations.
Drug characteristics
Cabotegravir (GSK1265744) is an integrase strand transfer inhibitor (INSTI) of the carbamoyl pyridone class and a structural analog of dolutegravir. At the time of writing, cabotegravir is still an investigational antiretroviral agent, manufactured as a once-daily oral tablet and as an intramuscular (IM) and subcutaneous (SC) injectable. Not yet licensed, it is available, in Europe, through the manufacturer’s expanded access program.7 Cabotegravir is formulated as an LA suspension for monthly to quarterly injection dosing.8 The half-life (t1/2) of LA injectable cabotegravir is 20–40 days with some individuals having measurable concentrations cabotegravir up to a year after one single dose.8,9
Rilpivirine (TMC278) is a second-generation non-nucleoside reverse transcriptase inhibitor (NNRTI), licensed for the treatment of HIV-1 infection in individuals aged ≥12 years with plasma HIV-1 RNA (ribonucleic acid) ≤100,000 copies/mL,10,11 based on the ECHO and THRIVE studies.12,13 It is licensed as a 25 mg oral tablet and in co-formulation as single tablet regimens with dual nucleoside reverse transcriptase inhibitors (NRTIs) and with dolutegravir.14–16 An LA injectable suspension has been developed for use with cabotegravir as injectable ART and, like cabotegravir, is available through an expanded access program.17 The t1/2 of LA rilpivirine is 30–90 days.18–20
Oral rilpivirine needs to be taken with a meal for optimal absorption and cannot be co-administered with proton-pump inhibitors.21 Frequently occurring side effects (SE) are headaches, insomnia, dizziness and nausea, increases in total and low-density lipoprotein cholesterol, rises in pancreatic amylase and derangement of transaminases.22 Data on cabotegravir side effects to date come from trials and are discussed later.
Healthy volunteer studies of oral rilpivirine given with dolutegravir or cabotegravir demonstrate no significant pharmacokinetic interactions, no requirement to dose-adjust either drug and a favorable short-term safety profile.23 To date, there are two key phase II and two phase III clinical trials that support the efficacy and safety of oral and injectable cabotegravir with rilpivirine (CR); LATTE and LATTE-2, ATLAS and FLAIR.
Clinical trial evidence
Phase II studies
The Long-Acting antireTroviral Treatment Enabling trial (LATTE) is a phase IIb randomized, partially blinded, dose-ranging study of once-daily oral CR, which has now reported 96-week results.24 It compared three dose-ranging CR arms with two NRTIs plus efavirenz (Figure 1).
LATTE recruited ART-naïve HIV-1 positive adults (age ≥18 years) with no major resistance-associated mutations (RAMs) at baseline. Investigators and participants were blinded only to the cabotegravir dose. As shown in Figure 1, at week 24, participants switched from the induction to maintenance phase. Participants in arms 1–3 only continued to the maintenance phase if HIV-1 RNA was <50 copies/mL, but those in arm 4 continued the same oral efavirenz-based regimen regardless of viral load (VL). Resistance testing was done at baseline and protocol-defined virological failure (PDVF). Randomization was stratified by baseline HIV-1 VL (< or ≥100,000 copies/mL) and by NRTI backbone (abacavir-lamivudine or tenofovir-emtricitabine).
The primary end point was an intention-to-treat (ITT) analysis in the exposed population of the proportion of participants with HIV-1 RNA<50 copies/mL at week 48. Of 243 patients enrolled and receiving at least one dose of an oral induction regimen, 207 patients took at least one dose of the oral maintenance regimen. At week 48, the combined overall response (HIV-1 VL<50 copies/mL) in the CR arms was 82% versus 71% in the 2-NRTI and efavirenz arm. This difference in virological suppression was seen through to week 96 (combined 76% for CR vs 63% for 2-NRTI and efavirenz). In all CR regimens (regardless of cabotegravir dose), there were fewer participants with baseline HIV-RNA≥100,000 copies/mL who sustained virological suppression at week 96 than with lower VLs. However, the authors concluded that numbers were too small to draw significant conclusions from this. An efficacy analysis of the ITT maintenance-exposed population found numerical superiority of cabotegravir 60 mg and 30 mg in achieving viral suppression at week 96 compared with 10 mg.
Overall, the CR regimens had better tolerability, fewer adverse event (AE)-related discontinuations and a lower proportion with virological non-response. In the cabotegravir arms, there was a higher frequency of headaches, depression and vomiting (22%, 11% and 8% of the participants on cabotegravir versus 8%, 6% and 5% on efavirenz). Two participants taking cabotegravir 60 mg had increasing transaminases on a background of steatohepatitis that improved on drug discontinuation. Dizziness, abnormal dreams, nausea, fatigue and insomnia were, as expected, the most frequent AEs in the NRTI and efavirenz arm. The 30 mg cabotegravir dose was taken forward for assessment as LA injectable.
LATTE-2 is a phase IIb, randomized, open-label, non-inferiority study of LA CR, aiming to select a dosing regimen.25 It recruited ART-naïve HIV-1 positive adults (aged ≥18 years) with CD4 counts≥200 cells/µL and HIV-1 VL≥1000 copies/mL. As depicted in Figure 2, participants had a 20-week oral induction phase of cabotegravir 30 mg plus abacavir–lamivudine, with oral rilpivirine added at week -4 (16 weeks into induction phase). Those with HIV-1 RNA<50 copies/mL at week -4 were randomized to one of the three maintenance treatment arms: LA cabotegravir 400 mg plus rilpivirine 600 mg every 4 weeks (q4w); LA cabotegravir 600 mg plus rilpivirine 900 mg every 8 weeks (q8w) or oral cabotegravir 30 mg plus abacavir-lamivudine daily. The study allowed a 14-day window for injections to more closely resemble real-world settings.
The primary outcomes were the proportion of the maintenance-exposed population with HIV-1 RNA <50 copies/mL at week 32 of the maintenance period, proportion with PDVF and the incidence and severity of AEs and laboratory abnormalities. The extended analysis continued to 160 weeks, with those randomized to oral cabotegravir 30 mg plus abacavir-lamivudine and virologically suppressed at 96 weeks switching to LA CR at 100 weeks, with optimized loading doses (cabotegravir 600 mg and rilpivirine 900 mg) then q4w or q8w regimens.26
Of 309 participants, 21 (7%) withdrew during the induction period. Among these, five stopped due to lack of efficacy, three for liver events according to pre-specified criteria and three for other AEs. During the maintenance period, 28/286 (10%) participants had withdrawn by week 96. Ten withdrew due to AEs, of which eight were in the q4w injectable arm.
There was comparable virological suppression between both injectable arms and the oral treatment arm at week 32, also seen at weeks 48 and 96 (Table 1). Among three with PDVF, one patient in the q8w arm had treatment-emergent resistance after 4 weeks with reverse transcriptase (RT) mutations K103N, E138G and K238T conferring low-level resistance to rilpivirine, and Q148R mutation conferring high-level resistance to raltegravir, elvitegravir and cabotegravir, but lower-level resistance to dolutegravir and bictegravir. In a second participant in the q8w arm, the mixture R269R/G was detected at week 48; mutations at codon 269 are not known to decrease cabotegravir susceptibility.27
Table 1.
LA cabotegravir and rilpivirine q4w (n=115) | LA cabotegravir and rilpivirine q8w (n=115) | Oral cabotegravir plus abacavir– lamivudine (n=56) | |
---|---|---|---|
Number (%) of participants in the maintenance-exposed population with HIV-1 RNA <50 copies/mL at week 32 | 108 (94%) | 109 (95%) | 51 (91%) |
Number of participants with protocol-defined virological failure at 96 weeks | Zero | Two participants (stopped at weeks 4 and 48) | One participant (stopped at week 8) |
Number (%) of participants with HIV-1 RNA <50 at week 16026 a | 95 (83%) | 104 (90%) | |
“Optimized” q4w arm (n=10) 10 (100%) |
“Optimized” q8w arm (n=34) 33 (97%) |
||
Number and severity of AEs and laboratory abnormalities (%)
|
8 (7%) 13 participants (11%) ISRs 32 participants (28%) |
2 (2%) (both ISRs) 13 participants (11%) ISRs 21 participants (18%) |
1 (2%) 9 participants (16%) Nil 12 participants (21%) 1 participant developed possible drug-induced liver injury meeting liver-stopping criteria, which improved upon discontinuation |
Notes: aNote this is not a primary outcome. bOnly one serious AE was considered to be treatment-related: migraine in the oral induction phase. cOne participant developed possible drug-induced liver injury meeting liver-stopping criteria which improved upon discontinuation prior to randomization.
Abbreviations: LA, long-acting; q4w, every 4 weeks; q8w, every 8 weeks; AE, adverse events; HIV, human immunodeficiency virus; RNA, ribonucleic acid.
Injection site reactions (ISRs) were the most common AE reported in both injectable arms. Pain occurred in >95% of all patients and nodules and swelling in >25%. Most ISRs were mild and short-lived (median 5 days). ISR frequency decreased from day 1 (≥85% in both arms) to approximately half this at week 4. Headaches were common, in up to 25% in all arms, although these were mostly mild and not treatment-related.
At week 48, all arms achieved mean trough concentrations greater than the in vitro protein-adjusted 90% inhibitory concentration for cabotegravir and rilpivirine against HIV-1 wild type (0.166 µg/mL and 12 ng/mL, respectively). Based on the results of LATTE-2, an optimized q4w dosing regimen for a future phase III study was selected, although both q4w and q8w schedules are undergoing further evaluation. In an extension to 160 weeks, enrolled participants in the injectable arms continued on their current treatment regimen and those on the oral arm who were virologically suppressed were switched to receive an optimized loading dose followed by the q4w or q8w injectable regimen. At week 160, both IM LA regimens have continued to maintain virological control and no patients have experienced protocol-defined virological failure after week 48.26
Phase III studies
Two phase III trials have now reported 48-week data as conference presentations, both showing LA CR to be non-inferior to continued oral triple therapy in terms of the proportion of participants with viremia at that time.28,29
FLAIR is an ongoing open-label study enrolling ART-naïve, hepatitis B surface antigen negative individuals, with no NNRTI RAMs other than K103N (Figure 3). Baseline integrase resistance testing was not done, consistent with current international clinical practice for ART-naïve individuals. On enrolment, all commenced a 20-week induction phase of the oral fixed-dose combination abacavir, lamivudine and dolutegravir. At week 20, those with HIV RNA <50 copies/mL as measured at week 16 proceeded to randomization 1:1 to either continue this oral therapy or to switch to a 4-week oral lead-in of CR. After this 4-week period, a loading dose of LA cabotegravir 600 mg and rilpivirine 900 mg was administered, followed by q4w maintenance doses of IM LA cabotegravir 400 mg and rilpivirine 600 mg.
The primary endpoint was proportion with HIV RNA >50 copies/mL at 48 weeks (ie, 44 weeks after starting injectable therapy), using the required FDA “snapshot” algorithm. Secondary outcomes included resistance at confirmed virological failure, safety and tolerability and patient-reported outcomes. The trial recruited (ITT population) 566 individuals, with 283 in each arm.
For the primary outcome of proportion viremic at 48 weeks (HIV RNA>50 copies/mL), 2.1% (6/283) in the LA arm and 2.5% (7/283) in oral arm were viremic, showing non-inferiority of LA versus oral triple therapy. There were four (1.4%) individuals in the LA treatment arm who discontinued due to lack of efficacy and three (1.1%) in the oral treatment arm. There were three participants with confirmed virological failure in the LA treatment arm. Detail available to date on these showed that all three were from Russian study sites and all infected with type A1 virus. At the time of virological failure, one had the NNRTI RAM E138K, one had the mixture E138E/A/K/T and one K101E. Integrase mutation Q148R was found in two, G140R in one and all showed the integrase polymorphism L74I. However, on testing baseline HIV RNA, the L74I was present in all before treatment start. Alone, L74I does not affect INSTI susceptibility, although it contributes to resistance when found with other mutations, including at position 148.27 Drug levels in these three individuals were within the range of those who were virologically suppressed, indicating that injections had been administered and that subtherapeutic levels alone do not explain the failure. Data on the baseline mutations and polymorphisms among those who remained virologically suppressed are needed to compare and we await further information to understand the significance of these descriptive data.
As in LATTE-2, the most common AE was ISR, decreasing in severity and frequency over time. Two participants withdrew from the LA arm because of ISRs, but the majority were non-severe and self-limiting. Participants again reported high levels of satisfaction with the LA treatment.28
ATLAS is a phase III, open-label, randomized study recruiting virologically suppressed participants, stable for at least six months on an oral regimen of two NRTIs plus a third agent (protease inhibitor (PI), NNRTI or INSTI).29,30 Of note, those on fixed-dose combination abacavir, lamivudine and dolutegravir were excluded and a reason for this is not given. Also excluded were individuals with a prior switch due to treatment failure (HIV-1 RNA≥400 copies/mL), those who have had over one-month break from ART and those with clinically significant comorbidities. This may limit generalizability outside of these groups. Participants with the RT mutation K103N were not excluded. Participants were randomized 1:1 to continue their oral regimen or switch to a 4-week oral lead in phase of daily CR, then proceed to a loading dose and q4w maintenance LA CR, with the same regimens as used in FLAIR. Data for the 48-week primary endpoint have been presented, but the study is ongoing, including an extension phase of the same q4w regimen and a study of the q8w regimen, “ATLAS 2M”.
Median prior duration of ART was 4 years, ranging from 1 to 21 years. The third agent was an NNRTI in 50%. At week 48, 1.6% (5/308 participants) in the LA arm and 1.0% (3/308) in the oral arm had virological nonresponse, with HIV RNA ≥50 copies/mL. The adjusted treatment difference met the definition of non-inferiority. Virological success was seen in 92.5% (285/308) participants in the LA therapy arm, compared with 95.5% (294/308) in the oral therapy arm.
As seen in FLAIR, there was some resistance emerging at failure in the LA therapy arm and further study on this is warranted. To date, we know that two were from Russian and one from a French study site; all had subtype A viruses (two A/A1 in Russia, one AG in France). RNA-based resistance testing at failure showed the RT mutation E138A, E or K, associated with rilpivirine resistance, in all three, with V108I in one. On integrase testing, L74I was seen in two, of whom one also had N155H, associated with a 2.7-fold change in susceptibility to cabotegravir. As in FLAIR, drug levels were below mean for the study population, but within range for most participants who maintained virological suppression. Comparing with baseline DNA (deoxyribonucleic acid) resistance testing (undertaken on stored samples, since all participants had HIV RNA<50 at baseline), E138 mutations were seen in two participants in baseline samples and L74I in two. Data on baseline DNA mutations among those with virological suppression at 48 weeks are not yet available and we should interpret DNA resistance testing with caution since it is not widely used in clinical practice and may include non-replicative viral DNA31 although resistance in viral DNA has been associated with future virological failure in some individuals.32
AEs were similar to those seen in FLAIR, with more drug-related AEs in the LA treatment arm (as would be expected in a study in which participants stable for six months on an oral regimen are randomized to switch) and headache reported by 11% in the LA treatment arm, versus 6% in the oral therapy arm. Only 10 participants in the LA treatment arm and 5 in the oral therapy arm withdrew due to AEs. Again, ISRs occurred and decreased in frequency as the study progressed and 99% were grade 1–2. There were few discontinuations due to ISRs and again those switching to injectable therapy expressed high levels of satisfaction with the treatment.
Participant satisfaction and qualitative data: “it might be painful, but it is better than pills”33
The HIV Treatment Satisfaction Questionnaire (HIVTSQ) is a 10-item validated questionnaire developed to evaluate HIV therapy. It addresses issues such as perceived convenience, flexibility and understanding of treatment as well as whether PLWH would be satisfied to continue their current form of treatment or would recommend it to others. The original status version (HIVTSQs) has since been updated to the new change version (HIVTSQc) that better allows tracking of change in satisfaction, but both are validated for use in clinical trials.34,35 A 12-item HIVTSQ (HIVTSQ-12) has now been created to address the discomfort caused by therapy and its ease of use.36
In LATTE-2, the HIVTSQ was used to assess participant satisfaction with injectable versus ongoing oral treatment. High levels of satisfaction were recorded, with 98% and 99% of the participants in injectable arms reporting that they were satisfied or very satisfied to continue at week 48, compared with 88% in the oral arm. This is despite ISRs, although of course in a preselected population who agreed to randomization to injectable therapy.25
A separately published qualitative study of LATTE-2 participants in the US and Spain provided in-depth interview data from 27 participants (including only two females) and 12 providers.33 Key conclusions were that participants reported convenience of LA injections and benefited from the emotional advantage of reduced risk of inadvertent disclosure and eliminating the daily reminder of living with HIV. Benefits in terms of stigma and discrimination were cited, with reduced concern about travel to countries where laws still discriminate on the basis of HIV status.
However, participants did express concern regarding the increased frequency of clinic visits, with colleagues noticing time off, and many hoped for less frequent injections to be available. Participant views were largely positive, albeit among those choosing to participate in the trial, experiencing virological suppression on LA therapy and then agreeing to participate in a qualitative sub-study.
Providers of injectable therapy were not so selected and had some concerns about the characteristics of PLWH who would most benefit from injectables and the fact that injectable therapy does not completely obviate the need for adherence to a medication schedule. Other concerns included emergent resistance if injections are missed and issues with switching if necessitated by new concomitant medications.
ATLAS and FLAIR have also used the HIVTSQ to determine participant satisfaction with injectable therapy with participants in both studies demonstrating markedly higher levels of satisfaction with LA regimens compared to oral therapy. In those participants who switched from oral to injectable therapy in both studies, the vast majority of responding participants (99% in FLAIR and 97% in ATLAS) preferred injectable therapy.28,29
Drug tolerability
LA injectable therapy is presumed advantageous to oral therapy in part because of better tolerability, higher patient satisfaction and reduced need for daily adherence. Rilpivirine has a favorable safety profile compared to older NRTIs, with lower rates of AEs and discontinuations compared to efavirenz in its licensing studies.12,13 The most frequent AE reported with injectable cabotegravir for both treatment and pre-exposure prophylaxis is mild ISR.25,37,38 Despite LATTE detecting a higher frequency of headaches and depression in participants on oral cabotegravir versus efavirenz, only headaches were reported to be treatment-related and at a frequency of >10%24 with only 5–6% of the patients in LATTE-2 suffering treatment-related headaches.25 Other potential neurocognitive side-effects (depression, memory impairment, asthenia and myalgia, and anxiety) were observed in the cabotegravir group in ATLAS causing treatment discontinuation but were not felt to be drug-related.29 The neurocognitive AEs seen with dolutegravir post-licensing have not, to date, been reported with cabotegravir.39–43
Weight gain has now been reported as a potential complication of INSTI use,.44 To date, pre-exposure prophylaxis (PrEP) studies have found no increase in weight gain with cabotegravir compared to placebo,45 but further data on this are needed from treatment studies.
Drug resistance in in vitro and in vivo studies
Two key aspects to consider are: first, the suitability of CR LA therapy for individuals with pre-existing RAMs or with experience of several ART regimens before moving to long-acting injectables; second, the frequency and nature of resistance emerging on treatment and a consideration of what treatment combinations may be effective after failure.
In the licensing studies for rilpivirine, ECHO and THRIVE,12,13 and similarly in the STAR study,46 treatment-naïve adults with any of 39 NNRTI mutations at baseline were excluded, including K103H/N/S/T, which was appropriate since the comparator arm was an efavirenz-based regimen. Similarly, in the studies of oral dolutegravir and rilpivirine, SWORD-1 and SWORD-2,47 in which individuals who were stable on ART were randomized to switch to the dual therapy or continue triple therapy, exclusion criteria included any previous switch because of virological failure and evidence of major mutations associated with resistance to PI, INSTI, NRTI or NNRTI groups. This limits the generalizability of the data to more treatment-experienced individuals, particularly those with long treatment histories including the first-generation NNRTIs or dual NRTI therapy. The WISARD study, now recruiting, will investigate the efficacy of dolutegravir and rilpivirine dual therapy among individuals with the K103N mutation and should provide useful data for that oral regimen.48 However, we must be cautious in extrapolating results of dolutegravir-based studies to cabotegravir, since they are not identical, particularly in terms of resistance profile. Both LATTE studies also excluded individuals with major RAMs.
In terms of treatment-emergent resistance, we await further data on those experiencing virological failure in ATLAS and FLAIR. We note that in the rilpivirine licensing studies the most frequent emerging rilpivirine-associated RAM was E138K.49 Considering potential treatment after virological failure on CR, individualized regimens would have to be constructed depending on RAMs found and susceptibility to agents with high genetic barrier to resistance.
In vitro studies may indicate potential for the development of resistance to cabotegravir following virological failure on first-generation INSTIs, with novel mutations C56S and G149A occurring on passage of Q148H virus (indicating resistance to raltegravir and elvitegravir) in the presence of cabotegravir.50 In vitro activity of cabotegravir against HIV-1 isolates with mutations affecting raltegravir and elvitegravir appears lower than that of dolutegravir and bictegravir, particularly against raltegravir-resistant isolates with G140S or Q148H.51 Cabotegravir is consistently shown to be less potent than bictegravir and dolutegravir in vitro, with the Q148R/K seen in clinical trials resulting in cross-resistance across the INSTI class.52
Therapeutic potential in differing patient populations
ART-experienced patients or with advanced HIV infection (CD4≤200)
Both LATTE and LATTE-2 excluded treatment-experienced individuals, those with major RAMs and those with active complications from late-stage HIV.24,25 Enrolled participants had relatively high median CD4 counts in both studies, as individuals with baseline CD4 counts<200 cells/µL were excluded. In LATTE, across CR arms there were lower proportions with baseline HIV-1 RNA≥100,000 copies/mL versus <100,000 that achieved virological suppression at week 96, but numbers in each group were small.24 Therefore, the use of injectable CR in ART-experienced individuals or those with low CD4 counts is yet to be evidenced.
LATTE-2 included a sub-study that analyzed paired plasma and cerebrospinal fluid (CSF) taken seven days after an LA CR dose (15 participants receiving cabotegravir q8w and three receiving cabotegravir q4w). CSF cabotegravir concentrations positively correlated with total plasma cabotegravir concentrations. Both cabotegravir and rilpivirine concentrations exceeded their in vitro 50% inhibitory concentration (IC50) for wild-type HIV-1 in all but one patient with a CSF rilpivirine concentration of <1 ng/mL (rilpivirine IC50 0.081 ng/mL). All patients maintained high rates of virological suppression in plasma and CSF with only one patient in the q8w arm having detectable CSF HIV RNA on the SuperLow assay (detects HIV-1 RNA>2 cells/mL) but undetectable on the Abbott real-time assay (HIV-1 RNA<50 cells/mL).53 Thus, cabotegravir and rilpivirine seem to effectively penetrate the CSF and are able to successfully suppress HIV replication in this sanctuary site making it a suitable regimen for those with advanced infection and possible or definite CNS opportunistic infections (OIs).
Individuals with no enteral route
At present only the fusion inhibitor enfuvirtide (T20) and the NRTI zidovudine are available in injectable form and neither are feasible now for maintenance therapy. LA injectables may provide a much-needed option for the few individuals with poor gastrointestinal absorption due to severe illness, swallowing problems or comorbidities although its data on its use in this context will probably only be available post-marketing.
Individuals with suboptimal adherence to oral therapy
The potential benefit to this group is yet to be demonstrated in studies, but the potential to maintain virological suppression where oral therapy has not would of course be beneficial. In some with chaotic lifestyles or addictions, LA injectables may not be the answer. Concerns include missing or delayed injections, causing reduction in blood levels of drug to below those required for virological suppression and leading to resistance that threatens future options. Strategies such as oral CR or other drugs, for example, PIs, to cover this pharmacokinetic “tail” are not yet evidenced but are needed. For those individuals for whom daily oral therapy presents a psychological burden, but who maintain engagement with clinical care, LA injectables could present a solution. However, studies to date have all used an oral lead-in period and starting injectable therapy without this, or in a true ART-naïve population, is not yet evidenced. There is still a knowledge gap in the efficacy of LA therapy in patients with prior treatment-failure or those with treatment breaks as they have been excluded from trials.30
Individuals requiring NRTI-sparing regimens
Despite the appeal of two-drug regimens, not all combinations are equally efficacious or non-inferior to triple-drug combinations, and some may cause use-limiting toxicity.54 CR has the advantage of avoiding long-term toxicity of NRTIs and the toxicity and drug interactions of PIs.55,56 LA CR is a tenofovir disoproxil (TDF)-sparing regimen that reduces pill burden and eliminates the renal and bone risks associated with long-term TDF use. However, the role of tenofovir-sparing regimens with the availability now of tenofovir alafenamide (TAF) is less clear.
Individuals with co-infections and comorbidities
Most participants in LATTE and LATTE-2 had no significant comorbidities. Both studies included a small number of hepatitis C RNA positive individuals, although hepatitis B infection was an exclusion criterion in both because of the tenofovir-free regimens.24,25 Treatment of hepatitis C in individuals on LA CR regimens may involve interactions between cabotegravir and antivirals for hepatitis C, which need to be studied.
Cabotegravir is highly bound to albumin with less than 1% free drug in circulation57 and is primarily eliminated via the predominantly hepatic UGT (uridine 5′-diphosphoglucurnosyltransferase) metabolism pathway (mainly UGT1A1, with a contribution from UGT1A9).58 No dose-adjustment appears to be required in mild to moderate hepatic impairment.57 Two individuals receiving oral cabotegravir in LATTE and LATTE-2 met stopping criteria for liver disease considered possibly drug-related.24,25 Therefore, concern still stands regarding cabotegravir in known severe pre-existing liver disease, viral hepatitis, or those on concomitant medications.
Despite patients with severe renal impairment being excluded from treatment studies, a phase I study showed oral cabotegravir may be administered without dose adjustment in severe renal impairment (creatinine clearance<30 mL/min, not on renal replacement therapy).59 Cabotegravir is also considered to not affect cardiac repolarisation although studies have only been done in healthy subjects receiving oral cabotegravir.60 Data are lacking on the use of rilpivirine in severe renal or hepatic impairment and manufacturers recommend it is used with caution.22
Drug–drug interactions (DDIs)
Known DDIs with oral rilpivirine include proton-pump inhibitors (presumably not a concern in injectable therapy), dexamethasone, rifampicin, phenytoin and carbamazepine.22 In vitro studies found cabotegravir interacts with organic ion transporter (OAT) 1 or OAT3 substrates with a small therapeutic window such as methotrexate;61 however, physiologically based pharmacokinetic (PBPK) models suggest no dose adjustment is required.62 Rifampicin has been demonstrated to induce oral cabotegravir metabolism, significantly decreasing cabotegravir exposure, and this result is expected in injectable LA preparations as well.63,64 Rifampicin is a cornerstone in anti-tuberculous (TB) therapy and therefore CR would currently be contraindicated in those requiring TB treatment. This is a key issue where TB incidence is high and where coinfection is frequent.
Data in females
Trial participants are predominantly male: LATTE and LATTE 2 participants were 96% and 92% male, respectively, and both studies excluded pregnant women.24 Phase III studies have recruited more women: 22% in FLAIR and 33% in ATLAS, although numbers are unlikely to be sufficient to determine any differences in response by sex.28,29
Of 200 participants in the PrEP cabotegravir study HPTN 077,37 66% were female. HPTN 077 showed no difference in proportions completing the regimen, similar numbers of AEs leading to discontinuation, and similar frequency of ISRs between females and males. There were some pharmacokinetic differences, with females, unlike males, consistently achieving target trough concentrations, and in tail-phase kinetics where it is anticipated that the terminal decay rate is 50% slower in females. A healthy volunteer study of LA rilpivirine has demonstrated that females have lower peak rilpivirine concentrations in both serum and genital fluids.18 More data on the pharmacokinetics of injectable CR in females are needed from treatment trials to address the knowledge gaps in dosing, safety, efficacy and tolerability.
There is no interaction between cabotegravir and levonorgestrel or ethinyl oestradiol-containing oral contraceptives in healthy adult women65 nor was a change in cabotegravir concentrations detected with any form of hormonal contraception in women in the HPTN 077 study.66 To date, we are not aware of any data on interactions between LA CR and depot contraceptives.
There are no studies of LA CR in pregnant women. Increased activity of UGT1A1 and UGT1A9 during pregnancy may lead to increased cabotegravir clearance, although the effect on drug concentration is unclear.67 Considering other INSTIs, there are proven changes in raltegravir pharmacokinetics in pregnancy prompting an increase in the recommended dose compared to non-pregnant females;68 however, no dose adjustment is required for dolutegravir. Raltegravir has been favored in international pregnancy guidelines in women with high baseline VL, requiring treatment intensification, or presenting in late pregnancy.69,70 There is some evidence that INSTIs contribute to greater likelihood of achieving undetectable HIV RNA at delivery.71,72
Concern regarding teratogenicity of dolutegravir has prompted recommendations to avoid it for women considering conception and during the first trimester.69,70 Given the lack of safety data in pregnant women and the long t1/2 of LA therapy, it cannot be recommended in those situations at present.
Children and adolescents
There are restrictions on the use of INSTIs and rilpivirine in the pediatric population due to lack of data. There is one in silico PBPK dose prediction study that has provided dosing recommendations of LA CR in children and adolescents weighing 15–70 kg.73 No dose prediction studies have been undertaken in children weighing less than 15 kg. A pharmacokinetic and safety study of LA CR in virologically suppressed adolescents aged 12–18, MOCHA, is currently in progress.74 Of importance will be the acceptability of frequent injections in this group. This is particularly pertinent in younger children, in whom future studies may be required.
Role in low- and middle-income countries (LMIC)
The vast majority of study sites in HIV treatment studies of LA therapy are based in high-income countries (HIC) in predominantly white populations. This leaves large knowledge gaps of its efficacy and safety in those of other ethnic backgrounds. Drug interactions discussed earlier are among the challenges in the rollout of LA CR in countries with a high incidence of TB.
Determinants of drug acceptability and adherence vary across the globe and in different patient populations.75–77 Factors such as beliefs about ART, stigma, social support or depressive symptoms are important determinants of adherence78 and strategies to address them should be relevant to the local context. Where HIV is still highly stigmatized, injectable therapy may allow PLWH more easily to conceal treatments from others, reducing risk of inadvertent disclosure.
To date, health care professionals have delivered LA ART.33 This will be a challenge in clinics with a large number of PLWH where injectables will require more clinical time and in services covering wide geographical areas. Strategies involving decentralized services or non-health care workers administering injections may help. Requirement of cold chain and storage at 2–8°C may also affect LA CR distribution in these settings.79
Outstanding questions and future work on cabotegravir/rilpivirine
While we now have 48-week data from the first phase III clinical trials, there are ongoing trials yet to report and follow-up data on the FLAIR and ATLAS studies will give valuable information on durability of the regimen and resistance emerging on treatment. Key information will come from the ATLAS-2M study, evaluating the efficacy of the q8w regimen, which may provide practical, economic and tolerability benefit over q4w.80 In addition, the MOCHA study in adolescents has potential to provide data for much-needed easier adherence74 and the phase III study NCT03635788, enrolling participants with a history of difficulty adhering to oral treatment regimens should help define the role of IM LA therapy in this population.81 Importantly, there are outstanding knowledge gaps in the use of injectable CR for HIV treatment in females and its use in pregnancy cannot be recommended at present.
Real-world data will be essential in defining the groups of individuals most likely to benefit from LA therapy; with those with previous NNRTI resistance, those with frequent non-attendance at the clinic and those with previous adherence difficulties are key populations who may stand to benefit. Further data on the “tail” after a missed injection and advice on how to manage this are needed as well as is data on the safety of therapy without the oral lead-in. Pharmacokinetics and drug interactions will be key among those with OIs, or who develop OIs while on therapy, since switching from LA regimens presents challenges. We await further data on whether the neuropsychiatric SE of dolutegravir and the weight gain potentially attributable to INSTIs are seen with cabotegravir.
In conclusion, we proceed with caution into this new era of HIV therapy, which could lift the burden of daily oral therapy for many people living with HIV, but which must be supported by robust safety and durability data as well as real-world cohorts.
Disclosure
CLvH has received conference scholarship from Viiv and has taken part in an advisory board for Viiv. She has received travel grants from Janssen and speaker fees from Gilead. CF reports no conflicts of interest in this work.
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