3.1 Phase 1 Studies

CSL112 has been studied in two Phase 1 trials, a single-dose study (SAD, NCT01129661) and a multiple-ascending-dose trial (MAD, NCT01281774) (Table 1) [29, 30]. Because CSL112 is a reconstituted drug that potentiates a physiologic mechanism such as CEC, it can be challenging to differentiate the PK and PD drug effects from the native HDL levels and function. Therefore, to evaluate the net effect of CSL112, PK and PD parameters were adjusted for baseline levels (i.e., before CSL112 administration). The PK parameters evaluated were apoA-I (via immuno-nephelometric method run on a Roche Modular P analyzer [31]) and PC (via choline oxidase- DAOS [N-ethyl-N-(2-hydroxy-3-sulfopropyl)-3,5-dimethoxyaniline] method using the Wako Phospholipids C assay [32]), the two main components of the drug, using previously validated assays. There was no indication of assay interference with CSL112 [29]. On the other hand, the PD effect was assessed by quantifying ex vivo cholesterol efflux (i.e., total CEC) and plasma lipids level variations.

Table 1 Main PK/PD and safety findings of CSL112 Phase 1 studies

The SAD study was an adaptive, double-blinded trial that randomized 58 volunteers (3:1 ratio) to CSL112 (5, 15, 40, 70, 105, 135 mg/kg) or placebo [30]. The MAD study was an adaptive, unblinded trial that randomized 36 volunteers (3:1 ratio) to CSL112 (3.4 g/once a week, 6.8 g/once a week, and 3.4 g/twice a week) or placebo. The dosing strategies and regimens employed were derived from PK modeling of the previous SAD study. The minor influence of body weight on the clearance of apoA-I and PC led to the decision to test fixed doses. Furthermore, simulations from the SAD study and evidence from other clinical studies containing apoA-I products supported the once/twice weekly administration, as it would result in minimal accumulation of apoA-I and PC [33, 34]. The goal was to reach an exposure above 500 mg/h/dL for the baseline‐corrected apoA‐I AUC0–last and above ~ 30 mg/dL for the baseline‐corrected apoA‐I Cmax, which appeared to be sufficient to obtain a ~ 10% increase in CEC [30]. Several clinical studies have shown that a higher CEC is associated with lower adverse cardiovascular outcomes. Every standard deviation increase of CEC is potentially associated with a 20% risk reduction [35].

3.1.1 Pharmacokinetics

After the CSL112 infusion, there was a rapid increase in apoA-I and PC. Apolipoprotein A-I (ApoA-I) maximal concentration (Cmax) increased proportionally to the CSL112 dose in the SAD (Cmax [mean ± SD] from 0.17 ± 0.06 g/L for the 5 mg/kg dose and to 2.81 ± 0.45 g/L in the 135 mg/kg dose) and MAD (Cmax [mean ± SD] from 0.66 ± 0.07 g/L in the first dose of the 3.4 g/1week group to 1.63 ± 0.38 g/L in the first dose of 6.8 g weekly group) studies. Furthermore, drug exposure was dose proportional (AUC0–last [mean ± SD] 197 ± 192 mg h/dL in the 5 mg/kg group to 11993 ± 4055 mg h/dL in the 135 mg/kg group) [30].

In both studies, regardless of the dose, peak plasma concentration was reached at the end of the infusion (time to Cmax [Tmax] ~ 2 h), followed by a diphasic decline. Moreover, apoA-I levels remained 3-fold above the baseline for ≥ 3 days and ≥ 5 days per dose > 70 mg/kg. The MAD study showed no evidence of drug accumulation in the once/week regimen (3.4 or 6.8 g/1-week). However, the bi-weekly administration (3.4 g/2-week) was associated with some degree of apoA-I accumulation. Similar accumulation patterns were found with PC. The apoA-I and PC ratio of AUC (RAUC) for the 3.4g/2-week group, between the last and the first dose, was ~ 2 [29].

In the MAD study, mean apoA-I half-life (t½) was highly variable in the 3.4 g dose groups (19.3 h after the first infusion of 3.4 g/2-week to 92.8 h at the last infusion of the 3.4 g/1-week group). In contrast, less variability was found in the 6.8 g/1-week group (from 39.7 to 60.8 h). These differences in t½ findings could be the consequence of endogenous apoA-I level fluctuations, sex imbalance between groups, and the small sample size of the studies. A previous radiolabeled HDL study reported an apoA-I t½ between 64.8 to 84 h [36].

Phosphatidylcholine half-life had broad variability (after the administration of all doses), again, possibly as a consequence of the limited collection of these data. Ultimately, the mean steady-state volume of distribution for apoA-I varied from 5.6 to 9.7 L, suggesting the movement of a small quantity of drug out of the plasma.

3.1.2 Pharmacodynamics

CSL112 infusion caused an increase of total CEC by ≤ 192 ± 40%. The relationship between drug administration and effect is supported by the correlation between the CEC area under the effect time curve (AUEC) and apoA-I AUC. Cholesterol efflux capacity peaked at 2 h from the infusion and returned to baseline by 72 h. The ABCA1-dependent efflux capacity increased ≤ 630 ± 421%. No saturation of AUEC for cholesterol efflux was found with the apoA-I exposure tested [30].

Pre-β1-HDL (i.e., very small HDL [HDL-VS]) increased by ≤ 3596 ± 941%, with peaks at 2 h, except for 135 mg/kg dose, which occurred at 8 h. Very small HDL levels increased accordingly to ascending CSL112 doses, with a linear relationship between apoA-I AUC0–24 and HDL-VS AUEC0–24. In particular, each group noted some degree of HDL-VS accumulation in the MAD study. Overall, there was a good correlation between HDL-VS levels and ABCA1-mediated efflux (r2 = 0.54), which was expected as apoA-I stimulates this pathway of cholesterol reabsorption.

Total cholesterol (TC) in plasma increased in a dose-dependent manner, presenting a clear time lag with CSL112 administration, which peaked between 4 and 24 h following the infusion. Total cholesterol elevation was driven by a rapid and sustained elevation in HDL-C (up to 81 ± 16.5%, with a peak of HDL-C within 24–48 h remaining elevated up to more than 72 h) with no change in non-HDL cholesterol. There was a consistent linear relationship between HDL-C AUEC0–72 and apoA-I exposure (AUC0–72). High-density lipoprotein cholesterol concentration progressively increased before each infusion, suggesting an accumulation during the study.

The rapid increase in HDL-C, seen at 2 h, was mainly due to unesterified cholesterol (HDL-UC) accumulating into HDL particles. High-density lipoprotein cholesterol peaked around 2–4 h from the beginning of the infusion and remained elevated for 48 or more hours. In contrast, HDL-esterified cholesterol (HDL-EC) peaked at 24 h and remained elevated for 72 h or more. The data suggest that cholesterol is rapidly displaced from cells to HDL particles (in the form of HDL UC) and subsequently undergoes a process of esterification (HDL EC).

Ultimately, CSL112 did not appear to increase proatherogenic lipids, as no relevant changes in lipid markers such as apolipoprotein B (apoB, primary apolipoprotein of LDL-C and other particles) and triglycerides occurred.

3.1.3 Safety

In Phase 1 studies, the most frequently reported AEs were vessel puncture site hematoma (n = 18), headache (n = 13), and infusion-site hematoma (n = 11). Overall, there were no deaths or serious adverse events (SAEs) during the SAD and MAD studies, and no AEs were directly related to treatment with CSL112 [36]. In contrast to CSL111, there was no evidence of hepatic toxicity assessed by liver enzymes or bilirubin levels. Furthermore, there were no significant changes in clinical or laboratory data in subjects to whom CSL112 was administered. In particular, no evidence of viral transmission or apoA-I–specific autoantibodies was found.

3.1.4 Special Populations3.1.4.1 Volunteer with Moderate Renal Impairment

Although most apoA-I catabolism occurs in the liver, a small amount undergoes renal clearance [37,38,39]. However, previous Phase 1 trials included only volunteers with normal renal function. Therefore, a Phase 1 double-blind, placebo-controlled SAD study was conducted to assess CSL112 safety and PK/PD profile in volunteers with moderate chronic kidney disease (CKD, estimated glomerular filtration rate [eGFR] 30–60 mL/min/1.73 m2) compared to those without CKD [38, 39]. Patients were classified according to baseline renal function (16 with moderate CKD and 16 without CKD) into 4 cohorts and randomized (3:1 ratio) to 2 or 6 g of CSL112 or placebo [39].

ApolipoproteinA-I and PC plasma concentration-time profiles were similar between groups, with a dose-dependent increase in Cmax for apoA-I and independently from the baseline renal functional status of the patients, suggesting no difference in CSL112 exposure according to baseline renal function. Plasma clearance of apoA-I seems unaffected by lower eGFR, with an excreted fraction in urine during the first 48 h < 1% across all doses and renal function.

Sucrose, a sugar compound, is a main component of CSL112 and is excreted by the kidney. After the CSL112 infusion, a dose-dependent increase of sucrose was noted in both plasma and urine. Concentration-time profiles indicated that volunteers with moderate CKD have a slower elimination when compared to those without CKD. However, the 2 and 6 g groups excreted sucrose almost entirely within 24–48 h, respectively.

After the infusion of CSL112 at 6 g, regardless of the baseline renal function, there was an intense dose-dependent 4-fold elevation of ABCA1-dependent, a 2-fold elevation of ABCA1-independent CEC, and an increase in pre-β-HDL levels. Moreover, both groups presented similar AUEC0–24 in terms of cholesterol efflux. Total cholesterol and HDL-C increased in a dose-dependent way in both groups, with 2 h peak of HDL UC followed by 24 h peak of HDL EC. CSL112 was not associated with changes in other lipid components or inflammation parameters [38].

CSL112 exhibits a similar safety and tolerability profile in patients with or without CKD. Nevertheless, 2 of 6 subjects with moderate CKD who received the 6 g dose presented a slight (1.5× upper limit of normal [ULN]) and transient (< 24 h) increase in total bilirubin.

3.1.4.2 Japanese Volunteers

The early CSL112 Phase 1 trials were performed mostly in White males (97.2%), with a different incidence of CAD, post-MI AEs, and lipoprotein metabolisms compared to other ethnic groups. Therefore, a CSL112 Phase 1 study was conducted on 34 Japanese volunteers to evaluate the PK/PD profiles and safety of different CSL112 doses (2, 4, and 6 g single dose) compared to placebo in oriental races (Table 1) [40]. Furthermore, they randomized White subjects to either 6 g or placebo (one administration only) to compare the two populations (6 g in Japanese vs 6 g in White).

Apolipoprotein A-I levels in the Japanese population increased in a non-linear and dose-dependent way, peaking at 2 h and decreasing in a biphasic fashion. Of note, they remained above the baseline for 72 h (in the 2 and 4 g groups) and 144 h (in the 6 g group). Apolipoprotein A-I mean baseline-corrected AUC0–72 went from 840 mg h/dL in the 2 g cohort to 6490 mg/h/dL in the 6 g cohort, highlighting a dose-dependent exposure of CSL112. Overall, Japanese volunteers experience a similar PK profile compared to White subjects. The geometric mean ratios (Japanese:White) for plasma apoA-I AUC0–72 and Cmax were 1.08 and 0.945, respectively.

The total cholesterol efflux increase and the ABCA1-dependent cholesterol efflux increase in Japanese and White subjects were similar (total CEC: 2.74-fold vs 2.92-fold and ABCA1-dependent CEC: 7.29-fold vs 8.36-fold, respectively), together with pre-β1-HDL, and HDL-C levels. No main alterations in non-HDL-C, apoB, LDL-C, or triglycerides occurred in any group. Ultimately, there was a similar safety profile between Japanese and Whites, except for the presentation of 3 hypersensitivity cases (i.e., a non-serious rash) that resolved without treatment, but only one was assessed as being related to the study treatment. Two cases of non-clinically relevant electrocardiogram changes were observed.

3.2 Phase 2 Studies

Three Phase 2 studies, including a Phase 2b study, have been conducted with CSL112 (Table 2) to assess the safety and PK/PD profile in patients with stable CAD or post-MI.

Table 2 Main PK/PD and safety findings of CSL112 Phase 2 studies3.2.1 Patients with Stable CAD

Tricoci et al, conducted a single ascending, double-blinded, placebo-controlled trial in patients with stable CAD [21]. A total of 45 patients were randomized first into three dose groups and second to either CSL112 (1.7 g [n = 7], 3.4 g [n = 12], and 6.8 g [n = 14]) or placebo (n = 11) (3:1 ratio). Randomization was stratified for normal (eGFR 90 mL/min/1.73 m2) or mild (eGFR between 60 and 90 mL/min/1.73 m2). All patients were on dual antiplatelet therapy (DAPT, i.e., aspirin plus clopidogrel or prasugrel), but patients on anticoagulant therapy were excluded. There were no serious study-drug-related adverse but mild adverse events, including infusion-site-related AE and vessel puncture-site hematoma. There were no differences in the rate of AEs between patients with normal compared with mild renal dysfunction. Furthermore, no impairment of hepatic function was observed. Still, a slight increase of serum creatinine was seen in all groups (including placebo), probably because blood sampling was performed during fasting. No seroconversion to any virus or production of anti-CSL112/apoA-I autoantibodies was reported.

Pharmacokinetic and PD profiles were similar to Phase 1 trials. Apolipoprotein A-I levels reached the maximal concentration at 2 h, and Cmax and AUC increased in a dose dependent manner (Table 2). CSL112 induced a fast dose-dependent increase in CEC (up to 3.1-fold higher than placebo).

Total cholesterol and HDL-C increased dose dependently after the infusion of CSL112, with a peak observed at 8 h, without further changes in other lipids biomarkers.

3.2.2 AEGIS-I Trial

The ApoA-I Event Reducing in Ischemic Syndromes I (AEGIS-I) trial was a Phase 2b multicenter, double-blind, placebo-controlled, dose-ranging randomized trial, conducted in 1258 patients with a recent MI (within 7 days from randomization), with either normal (n = 578) or mildly (n = 680) impaired renal function (Table 2) [41]. Co-primary endpoints were renal or hepatic toxicity at 29 days’ follow-up. Renal toxicity was defined as an increase ≥ 1.5× in serum creatinine from baseline or new-onset requirement for renal replacement therapy, with a non-inferiority margin of ≤ 5%. Hepatic toxicity was defined as a >3 ULN increase of alanine transaminase (ALT) or total bilirubin, with a non-inferiority margin of ≤ 4%. Key secondary endpoints included bleeding and MACE (composite of CV death, nonfatal MI, ischemic stroke, or hospitalization for unstable angina) at 1 year. After stratification by baseline renal function, patients were randomized (1:1:1 ratio) to either low-dose CSL112 (2 g of apoA-I/week), high-dose CSL112 (6 g of apoA-I/week), or placebo for 4 weeks. Between 92 and 95% of the patients were on DAPT and 8%–10% on anticoagulants. At a median follow-up of 7.5 months, CSL112 was not inferior compared to placebo in terms of hepatic (CSL112 2 g vs placebo: 1 vs 0%, 95% CI [− 0.1 to 2.5]; pnoninferiority = 0.12 and CSL112 6 g vs placebo: 0.5 vs 0%, 95% CI [− 0.5 to 1.7]; pnoninferiority = 0.50) or renal toxicity (CSL112 2 g: 0 vs 0.2%, 95% CI [− 1.4 to 0.7]; pnoninferiority = 0.50 and CSL112 6 g: 0.7 vs 0.2%, 95% CI [− 0.7 to 1.9]; pnoninferiority = 0.62). At 12 months, there were no significant differences in MACE between CSL112 and placebo groups, CSL112 2 g and placebo (6.4 vs 5.5%, HR 1.18; 95% CI [0.67–2.05]; p = 0.57) or high dose CSL112 6 g and placebo (5.7 vs 5.5%, HR 1.02; 95% CI [0.57–1.80]; p = 0.97). There were no significant differences in MACE components between CSL112 2 or 6 g and placebo, except for cardiovascular death (CSL112 6 g: 1% vs placebo: 0%; p = 0.0477). Moreover, there were no differences in bleeding events, SAEs, drug hypersensitivity, and infusion site reactions. A dose-dependent increase in apoA-I concentration, total CEC, and ABCA1-dependent CEC (2.51-fold in 2 g dose and 1.78-fold in 6 g dose) were observed (Table 2).

ApoA-I Event Reducing in Ischemic Syndromes I trial represents the largest trial conducted so far assessing the safety of CSL112 in patients with an MI in the past 7 days. Overall, safety outcomes were reassuring, suggesting no renal and hepatic toxicity without signals of other SAEs. Both doses of CSL112 were associated with a significant increase in CEC. As a Phase 2b trial, the analyses of clinical events were underpowered and not adjusted for multiple comparisons. Therefore, clinical outcomes should be evaluated cautiously and considered hypothesis generating. In particular, in the difference in cardiovascular death between CSL112 6 g dose and placebo, there was a low rate of events with no clustering of deaths in proximity to the CSL112 infusion, and indeterminant causes of death were inputted as cardiovascular death.

Preliminary data from ongoing AEGIS-I ex vivo sub-studies have suggested that CSL112 infusion promotes hepatocytes cholesterol uptake and apoA-I exchange rate (i.e., biomarker of HDL functionality) compared to placebo [42, 43].

3.2.3 AEGIS-I Trial PK/PD Sub-Study

A small cohort of patients (n = 63) of the AEGIS-I trial underwent PK/PD profile analysis and several biomarker assessments. Overall, the results confirmed the previous PK/PD findings (Table 2). The ApoA-I exposure was 3- to 4-fold higher in the 6 g group versus the 2 g group after the first dose and 3-fold higher after the last doses. The fact that there were slightly higher levels after the last doses compared to the first doses suggests a slight degree of accumulation. Phosphatidylcholine showed a similar PK profile but a shorter half-life, with an exposure 3-fold higher in the 6 g group than in the 2 g group. There were no substantial differences in apoA-I and PC PK profiles among patients with normal, mild, or moderately reduced renal function (Fig. 3) [44]. The exposure-response relationship after CSL112 infusion was analyzed in the AEGIS I PK/PD sub-study [44]. A 2-fold increase in total CEC and a 3-fold increase in ABCA1-dependent CEC with respect to baseline was observed at 2 h in the 2 g dose group. At the same time, a 3-fold increase in total CEC and a 6-fold increase in ABCA1-dependent CEC with respect to baseline occurred in the 6 g dose group.

Fig. 3

Changes in apolipoprotein A-I and phosphatidylcholine following CSL112 infusion. Presented are mean ± standard deviation of baseline-corrected plasma concentration-time profiles for apolipoprotein A-I (apoA-I) (A) and phosphatidylcholine (PC) (B). Total study population: 63 (placebo [n = 18], 2 g CSL112 [n = 24], 6 g CSL112 [n = 21]). Normal renal function: 36 patients; Mild renal impairment: 26; Moderate renal impairment: Reproduced with permission from Gibson et al. [44]

The 2-h time point (end of infusion) represents the Tmax R (i.e., time to reach maximal response) for ABCA1-dependent and ABCA1-independent CEC in the 2 g and the 6 g CSL112 doses. In the 6 g group, ABCA1-dependent and ABCA1-independent CEC returned to baseline after 48 h. However, in the 2 g group, ABCA1-dependent CEC returned to baseline after 12 h and ABCA1-independent CEC after 24 h, suggesting an exposure-response relationship between CEC and CSL112 dose.

There was a strong correlation between CSL112 dose and ABCA1-independent CEC AUEC0–24 (R2=0.800) and total CEC AUEC0–24 (R2=0.757). Notably, the Rmax (maximal response) of ABCA1-independent CEC was dose proportional, while it appeared to be saturated for ABCA1-dependent and total CEC. The cause of the saturation was deemed to be assay saturation, noted in samples collected in 2 and 6 g groups at 2 h. Ultimately, there was a positive linear relationship between the increasing CSL112 dose-dependent apoA-I exposure and the total, ABCA1-dependent, and ABCA1-independent CEC response, consistent after the first and last infusion (Fig. 4) [44].

Fig. 4

Correlation between apolipoprotein A-I and CEC exposure following infusion of CSL112. Presented are the linear relationships between pre-dose-corrected apolipoprotein. A-I (apoA-I) exposure, area under the curve in the first 24 h post-infusion (AUC0–24), and pre-dose-corrected cholesterol efflux capacity (CEC), area under the effect curve in the first 24 h (AUEC0–24): total (A), ABCA1-dependent (B), and ABCA1-independent CEC (C), following the first and last infusions of CSL112. Reproduced with permission from Gibson et al. [44]

High-density lipoprotein cholesterol peaked between 2 to 6 h, returning to baseline after 48 h in the 2 g group and 96 h in the 6 g group (Fig. 5). There was a transient 24-h increase in total cholesterol without an increase in atherogenic lipids or lipoproteins. Among the inflammatory, metabolic, and cardiac biomarkers evaluated, there were no significant differences between CSL112 and placebo. The authors claimed that the observed variability in the evaluated biomarkers could potentially be related to the post-MI condition rather than to a CSL112 effect.

Fig. 5

Elevations in cholesterol efflux capacity following CSL112 infusion. Presented are mean ± standard deviation baseline- (first infusion) and pre-dose-corrected (last infusion) total (A), ABCA1-dependent (B), and ABCA1-independent (C) cholesterol efflux capacity. Total study population: 63 (placebo [n = 18], 2 g CSL112 group [n = 24], 6 g CSL112 [n = 21]). Normal renal function: 36 patients; mild renal impairment: 26 patients; moderate renal impairment: 1 patient. Reproduced with permission from Gibson et al. [44]

3.2.4 CSL112-2001 Trial

The CSL112-2001 trial (A Study of CSL112 in Adults With Moderate Renal Impairment and Acute Myocardial Infarction) was a double-blinded, placebo-controlled, parallel group randomized trial that included 83 post-MI patients (within 7 days of the index event) with moderate CKD (eGFR between 45 and 60 mL/min/1.73 m2) and diabetes (Table 2) [45]. Patients were randomized to CSL112 6 g or placebo (2:1 ratio), stratified according to the CKD stage (i.e., 3a and 3b stage). The co-primary safety endpoint was renal SAE (composite of acute renal failure or renal, cortical, or papillary necrosis) and treatment-emergent acute kidney injury (AKI, sustained increase of creatinine ≥ 0.3 mg/dL from baseline). Key secondary endpoints included changes in hepatic status (> 3 ULN increase of ALT or total bilirubin). There were no differences between CSL112 6 g and placebo in AKI events (4.0 vs 14.3%, 95% CI [−0.277 to −0.025]; p = 0.180), but there was a lower rate of renal SAEs in the CSL112 group compared to placebo (1.9 vs 14.3%, 95% CI [− 0.296 to − 0.005]; p = 0.048). There were no differences between groups in hepatic status and bleeding events. In this cohort of patients with moderate CKD, CSL112 6 g was associated with similar apoA-I and CEC to the one observed in post-MI patients with normal renal function or mild CKD.

3.3 Pooled Data Analysis

Data from the Phase 1 and 2 trials have been combined in 3 different pooled data analyses to increase the study's sample size and assess the PK/PD profiles among different sub-groups [20, 40, 46].

In 2018, Gille et al. [20] performed a pooled analysis of the results from previous Phase 1 and 2 trials, including healthy volunteers and patients with stable CAD, to compare PK/PD profiles between them. A total of 137 patients were included (Phase 1 SAD, n = 57; Phase 1 MAD, n = 36; and Phase 2a, n = 44). Patients with stable CAD exhibited an impaired HDL function compared to healthy individuals, characterized by a significantly lower ABCA1-mediated CEC at baseline (p < 0.0001) despite slightly higher apoA-I levels. However, CSL112 infusion overcame the baseline HDL dysfunction in patients with CAD, and no differences were observed in apoA-I PK or pre-β1-HDL (p = 0.500) or CEC (p = 0.100). These findings suggest that the disease processes that reduce the efflux activity of endogenous apoA-I have a negligible effect on infused CSL112. When CEC was analyzed based on tertiles of apoA-I–normalized CEC (i.e., level of HDL function), there were no differences in the elevation in CEC (p = 0.100).

In 2020, Zheng et al. [46] performed a pharmacometrics analysis pooling data from previous Phase 1 (n = 4) and 2 (n = 3) clinical trials (including White and Japanese healthy volunteers, stable CAD, post-MI, and post-MI patients with moderate CKD) to characterize the population PK and exposure-response models evaluated as total and ABCA1-dependent CEC, and to assess the influence of covariates in this relationships. Overall, the models did not identify any covariate that had a clinically relevant effect. In particular, neither the body weight, sex, nor the ethnic group interfered with the desired CEC elevation associated with a 6 g dose of CSL112.

In the previously mentioned Phase 1 study performed by Zheng et al. [40], the authors performed a cross-study comparison to compare PK parameters of apoA-I across five completed CSL112 clinical trials, including healthy volunteers, stable CAD, and post-MI patients [20, 21, 29, 30, 41]. Overall, CSL112 exposure and CEC enhancement were similar in Japanese and non-Japanese subjects, which further confirmed the consistent PK/PD profiles of CSL112. The infusion of 6 g CSL112 resulted in similar median elevations of apoA-I in Japanese and White subjects and post-MI patients (2.08-, 2.33-, and 2.08-fold increase), total CEC (2.74-, 2.92- and 2.55-fold increase), and ABCA1-dependent CEC (7.29-, 8.36-, and 3.84-fold increase).

3.4 Further Investigations3.4.1 Effects on Platelet Inhibition

In a previous study with CSL111 (predecessor compound), infusion in patients with type 2 diabetes without concomitant antiplatelet therapy, was associated with a significant reduction in the ex vivo platelet aggregation in response to multiple agonists. This effect persisted in washed platelets [47]. Moreover, in vitro studies in platelets from healthy individuals revealed that the inhibitory effects of CSL111 on platelet function were time- and dose-dependent and resulted in a widespread attenuation of platelet function and a significant reduction in thrombus formation under flow. The proposed mechanism of action was reducing cholesterol content in platelet membranes.

In a dedicated study with CSL112, platelet reactivity and bleeding risk were assessed in patients (n = 44) with stable CAD receiving dual antiplatelet therapy (i.e., aspirin plus clopidogrel [n = 37] or prasugrel [n = 7]) in a single ascending dose placebo-controlled randomized trial, comparing CSL112 infusion (1.7, 3.4, or 6.8 g dose) versus placebo [48]. Platelet aggregation was assessed by means of light transmission aggregometry using arachidonic acid, adenosine diphosphate, and collagen as agonists, at baseline and up to 48 h post-dosing. Compared to placebo, CSL112 had no meaningful time- or dose-dependent effects on maximum platelet aggregation in response to any agonist, regardless of the dose or renal function subgroup. There were no significant changes in coagulation parameters, and no differences in bleeding events were observed.

3.4.2 Interaction with Lipid-Lowering Therapies

Lipid-lowering therapies (i.e., statins and proprotein convertase subtilisin/kexin type 9 [PCSK9] inhibitor) are a cornerstone in preventing recurrent events in post-MI patients. In animal models, high doses of rHDL are associated with a transient increase of hepatic enzymes. In an animal model, Beyerle et al. [49] performed a toxicity evaluation of the combination of different CSL112 doses with alirocumab (a PCSK9 inhibitor) and/or atorvastatin (a statin). Although high-dose CSL112 was associated with a non-significant elevation of liver enzymes, there was limited evidence of hepatic toxicity with the co-administration of CSL112 with alirocumab and/or atorvastatin assessed by means of liver enzymes and histology. Co-administration of the study drugs had minimal effect on their respective exposure levels and total cholesterol and HDL-C levels. To date, no dedicated investigations in humans on drug-drug interaction are available.