Optimal Maintenance Strategy for Patients with Improved Left Ventricular Function Following Sacubitril/Valsartan Therapy

Minjung Bak; Yoonjee Park; Heayoung Shin; David Hong; Darae Kim; Jeong Hoon Yang; Eun-Seok Jeon; Jin-Oh Choi

doi:10.20944/preprints202507.0633.v1

Submitted:

07 July 2025

Posted:

08 July 2025

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Abstract

Background and Objectives Optimal pharmacological treatment following left ventricular ejection fraction (LVEF) improvement remains largely unknown. This study compared the clinical outcomes of patients with improved heart failure (HF) based on the maintenance of sacubitril/valsartan (S/V) or transition to a renin-angiotensin-system blocker (RASB). Material and Method A total of 354 patients with recovered LVEF ≥ 40% after S/V treatment from a single center were retrospectively analyzed. Patients were categorized into three groups: those who continued S/V (n=294), those who switched to RASB (n=47), and those who discontinued both S/V and RASB (n=13). The primary endpoint was HF relapse, defined as a two-fold increase in baseline serum N-terminal-pro hormone B-type natriuretic peptide (NT-proBNP) concentration exceeding 400 pg/dL. Secondary endpoints included the ratio and difference between baseline and peak NT-proBNP levels. Result Baseline clinical characteristics were well balanced among groups. Over a median follow-up of 399 [252-589] days, HF relapse occurred more frequently in patients who discontinued both S/V and RASB compared to those who maintained either treatment (53.8% vs. 16.3% vs. 10.6%; p=0.001). NT-proBNP levels also showed a more pronounced increase in this group. However, there were no significant differences in primary or secondary outcomes between the S/V and RASB groups. Conclusion Our findings suggest that replacing S/V with another RASB does not worsen outcomes in patients with improved HF, whereas discontinuation of both therapies is associated with a significantly higher risk of HF relapse. A prospective trial is warranted to confirm the safety and effectiveness of this approach in maintaining remission.

Keywords:

HF

;

heart failure

;

EF

;

ejection fraction

;

S/V

;

sacubitril/valsartan

;

NT-proBNP

;

N-terminal-pro hormone B-type natriuretic peptide

Subject:

Medicine and Pharmacology - Clinical Medicine

Introduction

Medical treatment for heart failure (HF) with reduced ejection fraction (HFrEF) has been well established.[1] As a result of advanced management, a significant portion of HFrEF patients recover left ventricular ejection fraction (LVEF), sometimes to nearly normal levels. LVEF improvement and reverse remodeling after treatment with sacubitril/valsartan (S/V) has been reported across a wide range from 17.6% to 82.8%, with varied populations and definitions of endpoints.[2,3,4]

The prognosis and optimal pharmacological treatment after improved LVEF are of interest.[5,6] Complete withdrawal of HF medication has been identified as detrimental.[3] In the only randomized trial to date, “Withdrawal of pharmacological treatment for heart failure in patients with recovered dilated cardiomyopathy (TRED-HF)”, 40% of patients with dilated cardiomyopathy with improved LVEF ≥ 50% and NT-proBNP < 250 ng/L relapsed to HF within six months after discontinuation of all HF medication in a step-wise manner.[3]

Few studies have compared optimal HF medications including S/V and a tapered regimen for patients with HF with improved EF (HFimpEF). A recent study reported LVEF deterioration and increased clinical events within 12 months after tapered dose or change to renin-angiotensin-system blocker (RASB).[2] However, that was a small retrospective analysis of 77 patients, and the baseline characteristics between the maintenance group and the tapering group were not sufficient. Additionally, the possibility of compliance issues due to socioeconomic factors cannot be excluded.

Therefore, we aimed to investigate whether withdrawal of S/V with or without replacement with RASB while maintaining other guideline-recommended HF medication is associated with HF relapse.

Material and Methods

Study Population

This was a single-center retrospective cohort study. Inclusion criteria were patients older than 18 years with HFrEF who were treated with S/V between February 2017 and December 2021 from Samsung Medical Center (Seoul, Korea). Exclusion criteria comprised off-label prescription, non-recovery of LVEF ≥ 40%, and lack of echocardiography since starting S/V (Figure 1). Among 410 patients with improved LVEF ≥ 40% at least once after initiation of S/V, those on dialysis, those who underwent left ventricular assist device (LVAD) implantation or heart transplantation, and those with a short follow-up duration (< 30 days) or without serial NT-proBNP measurements were excluded.

All boards waived the requirement for informed consent as patients were retrospectively enrolled and data were collected after being anonymized. Our study was conducted in accordance with the Declaration of Helsinki and Institutional Review Board (IRB) approval was obtained (IRB No. 2020-08-082). Neither patients nor the public were involved in any aspect of this study, including its design, conduct, reporting, or dissemination plans.

Figure 1. This is a figure Study flowchart.HFrEF = heart failure with reduced ejection fraction (<40%); S/V = sacubitril/valsartan; LVEF = left ventricular ejection fraction; LVAD = left ventricular assist device; HT = heart transplantation; NT-proBNP = N-terminal-pro hormone B-type natriuretic peptide; RASB = renin-angiotensin-system blocker.

Definitions and Outcomes

Patients were divided into three groups according to the use of S/V and RASB after improvement of LVEF (Group A; S/V maintenance, Group B; Change to RASB, Group C; Neither S/V nor RASB, Figure 1). Patient’s clinical characteristics, medical history, and laboratory and echocardiographic data were collected from electronic medical records from the time of first improved LVEF ≥ 40% for group A and for time to S/V discontinuation in groups B and C (Figure 2). Serum NT-proBNP levels were collected at three points: baseline, peak, and final levels. Peak levels were defined as the first value that met the primary endpoint or the highest value during follow-up, as appropriate. Final values were collected at the most recent follow-up.

The primary endpoint was HF relapse, defined as a two-fold increase in baseline NT-proBNP concentration exceeding 400 pg/dL. Secondary endpoints were peak NT-proBNP level, the difference between baseline and peak NT-proBNP, hospitalization for HF, and heart transplantation or death.

Figure 2. This is a figure Study endpoints.HF = heart failure; NT-proBNP = N-terminal-pro hormone B-type natriuretic peptide; S/V = sacubitril/valsartan; LVEF = left ventricular ejection fraction; RASB = renin-angiotensin-system blocker.

Statistical Analysis

Categorical variables are expressed as percent (frequency) and continuous variables as mean ± standard deviation (SD). Comparison of continuous variables between groups used one-way ANOVA with Tukey's HSD post hoc analysis or the Kruskal-Wallis H test with Dunn test post hoc analysis. Categorical variables were compared by Chi-square tests with Bonferroni’s correction. The Kaplan-Meier method and log-rank test were used for time-to-event analysis. Clinical outcomes were compared between groups using a Cox proportional hazards regression model to calculate hazard ratio (HR) and 95% confidence interval (CI). Adjusted HRs and 95% CIs were obtained by Cox regression based on age, estimated glomerular filtration rate (GFR), final S/V dose, duration of S/V and sodium-glucose cotransporter-2 (SGLT-2) inhibitor use. Paired t-test and Wilcoxon test were used for paired continuous variable comparison between baseline and follow-up. McNemar test was used for paired categorical variable comparison between baseline and follow-up.

Statistical significance was considered at a p value <0.05. Statistical analysis was performed using R Statistical Software (version 4.1.0; R Foundation for Statistical Computing, Vienna, Austria).

Results

Baseline Characteristics

Among 1,040 patients with HFrEF treated with S/V, 410 (39.4%) achieved recovery of LVEF ≥ 40% (Figure 1). Among the finally enrolled 354 patients, 294 (83.1%) were maintained on S/V and 60 (16.9%) patients were either switched to other RASBs (47, 13.3%) or taken off the medication (13, 3.7%).

Baseline clinical characteristics and echocardiographic and medical treatment of the study population are shown in figure 1. The study population was predominantly male (N=256, 72.3%), and most patients experienced tolerable symptoms of New York Heart Association Fc I or II (44.9% and 49.7%, respectively). The most common cause of HF was dilated cardiomyopathy (48.6%), followed by ischemic heart disease (31.9%). Clinical characteristics were well balanced between group A and B, while group C had shorter stature and lower weight compared to the other groups. Echocardiographic parameters showed that group C had a smaller LV chamber diameter and a higher LVEF at baseline compared to groups A and B. Other than a lower sodium level in group C, there was no difference in baseline laboratory values including NT-proBNP between the three groups. Group A had been receiving the highest dose of S/V over the longest period before this study, while the dose and duration of S/V were similar in groups B and C. The prescription rate of sodium-glucose cotransporter-2 inhibitors was significantly lower in group B than in the other two groups. Prescription of beta blocker or spironolactone was noted in 91.0% and 80.8%, respectively, of the total study population.

Reasons for discontinuation of S/V in groups B and C were recovered LVEF, orthostatic hypotension, other intolerance, and chronic renal disease in that decremental order (Supplementary Table 1). The reason for S/V discontinuation did not differ statistically between these two groups, but there were more patients with orthostatic hypotension and intolerance to S/V in group B, while the majority of group C stopped S/V mainly because of LVEF recovery. In Group B, most patients were switched from S/V to valsartan, candesartan, or losartan.

HF Relapse

The mean follow-up duration was 399.0 [252.0 – 589.0] days in the study population, without difference between groups. The incidence of HF relapse based on NT-proBNP levels was significantly higher in group C compared to A and B (53.8% vs. 16.3% vs. 10.6%, p=0.001; Table 1).

Table 1. Baseline characteristics.

	Total (n=354)	A (n=294)	B (n=47)	C (n=13)	p-value	Post-hoc
Male	256 (72.3%)	212 (72.1%)	37 (78.7%)	7 (53.8%)	0.203
Age, yr	63.0 [51.0 - 72.0]	62.5 [51.0 - 72.0]	64.0 [43.5 - 68.0]	68.0 [57.0 - 76.0]	0.179
Height, cm	166.0 [158.0 - 172.0]	166.0 [158.0 - 172.0]	169.0 [159.0 - 174.5]	157.5 [148.0 - 167.0]	0.018	A=B>C
Weight, kg	69.9 [59.9 - 79.0]	69.9 [60.3 - 79.0]	72.5 [60.0 - 86.2]	56.0 [50.5 - 69.0]	0.009	A=B>C
BSA, kg/m2	1.8 ± 0.2	1.8 ± 0.2	1.8 ± 0.3	1.6 ± 0.2	0.009	A=B>C
NYHA Fc					0.136
I	159 (44.9%)	138 (46.9%)	20 (42.6%)	1 (7.7%)
II	176 (49.7%)	142 (48.0%)	24 (51.1%)	10 (76.9%)
III	18 (5.1%)	13 (4.4%)	3 (6.4%)	2 (15.4%)
Heart failure etiology
Dilated cardiomyopathy	172 (48.6%)	148 (50.3%)	21 (44.7%)	3 (23.1%)	0.133
Ischemic heart failure	113 (31.9%)	96 (32.7%)	14 (29.8%)	3 (23.1%)	0.694
New onset heart failure	116 (32.8%)	96 (32.7%)	16 (34.0%)	4 (30.8%)	0.975
Comorbidities
Hypertension	162 (45.8%)	140 (47.6%)	18 (38.3%)	4 (30.8%)	0.266
Previous coronary revascularization	112 (31.6%)	94 (32.0%)	15 (31.9%)	3 (23.1%)	0.791
Diabetes mellitus	115 (32.5%)	93 (31.6%)	15 (31.9%)	7 (53.8%)	0.249
Previous myocardial infarction	52 (14.7%)	44 (15.0%)	7 (14.9%)	1 (7.7%)	0.758
Coronary artery disease	99 (28.0%)	85 (28.9%)	11 (23.4%)	3 (23.1%)	0.667
Atrial fibrillation/flutter	86 (24.3%)	70 (23.8%)	11 (23.4%)	5 (38.5%)	0.486
Echocardiography
LV end-diastolic dimension, mm	55.5 [51.3 - 58.9]	55.6 [52.0 - 59.3]	55.7 [51.6 - 57.6]	47.1 [43.6 - 48.3]	<0.001	A=B>C
LVEF, %	47.0 [43.0 - 55.0]	46.4 [42.6 - 53.7]	48.3 [44.5 - 57.3]	55.0 [47.3 - 58.0]	0.022	A=B<C
Laboratory finding
Hemoglobin, g/dL	13.7 [12.1 - 15.0]	13.7 [12.3 - 15.0]	13.6 [12.0 - 14.9]	11.5 [10.6 - 13.7]	0.055
Sodium, mmol/L	140.0 [138.0 - 141.0]	140.0 [138.0 - 141.0]	140.0 [138.5 - 141.0]	138.0 [134.0 - 140.0]	0.022	A=B>C
NT-proBNP, pg/dL	230.0 [87.3 - 536.0]	233.5 [92.9 - 525.0]	214.0 [54.6 - 584.5]	265.0 [106.0 - 1215.0]	0.603
Baseline treatment
S/V dose, mg	200.0 [100.0-400.0]	200.0 [100.0-400.0]	100.0 [100.0-200.0]	100.0 [100.0-100.0]	<0.001	A>B=C
S/V duration before enrollment, days	436.0 [210.0-660.0]	486.5 [290.5-700.0]	120.0 [64.5-306.5]	219.0 [126.0-297.0]	<0.001	A>B=C
Beta blocker	322 (91.0%)	270 (91.8%)	42 (89.4%)	10 (76.9%)	0.171
Spironolactone	286 (80.8%)	235 (79.9%)	42 (89.4%)	9 (69.2%)	0.175
SGLT-2 inhibitor	132 (37.3%)	119 (40.5%)	9 (19.1%)	4 (30.8%)	0.017	A=C>B
Loop diuretics	151 (42.7%)	124 (42.2%)	20 (42.6%)	7 (53.8%)	0.707
Previous CRT	22 (6.2%)	18 (6.1%)	2 (4.3%)	2 (15.4%)	0.335
Previous ICD	28 (7.9%)	26 (8.8%)	1 (2.1%)	1 (7.7%)	0.285

In the Cox regression analysis, the HR for HF relapse in group C was at least four times higher than that of group A (HR_adj C to A 2.285, 95% CI [1.478 - 3.532], p<0.001) or group B (HR_adj C to B 4.723, 95% CI [1.322 - 16.87], p=0.017). There was no significant difference in HF relapse rates between group A and group B (HR_adj B to A 0.701, 95% CI [0.252 - 1.948], p=0.495) (Figure 3). The HR was calculated after adjusting for baseline variables—age, eGFR, final S/V dose, duration of S/V treatment, and SGLT-2 inhibitor usage—which were significantly different and clinically meaningful.

ACEI = angiotensin-converting enzyme inhibitor; ARB = angiotensin II receptor blocker; BSA = body surface area; BUN = blood urea nitrogen; CRT = cardiac resynchronization therapy; DCMP = dilated cardiomyopathy; EF = ejection fraction; GFR = glomerular filtration rate; ICD = implantable cardioverter-defibrillator; LV = left ventricle/ventricular; LAVI = left atrial volume index; NYHA Fc = New York Heart Association functional class; RV = right ventricle/ventricular; SGLT-2 inhibitor = sodium-glucose cotransporter-2; S/V = sacubitril/valsartan

Data are presented as mean ± standard deviation, median [25th percentile – 75th percentile], or n (%).

The values in bold indicate statistical significance (p<0.05).

Figure 3. This is a figure Cumulative incidence of primary endpoint up to 20 months.SV = sacubitril/valsartan; RASB = renin-angiotensin-system blocker.*Adjusted for age, estimated GFR, S/V final dose, duration of S/V, and SGLT-2 inhibitor(A=S/V group; B=RASB group; C=group without RASB).

Secondary Endpoints

When examining peak and base NT-proBNP levels, no significant difference was observed in group A and group B. However, group C showed a significant increase in NT-proBNP levels compared to baseline (p=0.002; Table 2). Peak and follow-up levels of serum NT-proBNP were also higher in group C (Table 2). The differences between baseline and follow up NT-proBNP levels are depicted in Figure 4. While similar at baseline, there was an eventual difference between groups. Group C had higher NT-proBNP levels compared to group A (p=0.021) and B (p=0.014) at follow-up. A comparison of baseline and follow-up NT-proBNP levels revealed that Group B exhibited no statistically significant change (p=0.134), whereas Group A showed a significant decrease (p<0.001) and Group C demonstrated a significant increase (p=0.040).

Figure 4. This is a figure Baseline and follow-up Log NT-proBNP values. (A=S/V group; B=RASB group; C=group without Clinical events of hospitalization for HF, heart transplantation, and mortality occurred in only a small number of patients, and there were no significant differences among the three groups (Table 3). Among the five patients who died, there were no cases of cardiac death.

Table 2. Primary and secondary endpoints.

	A (n=294)	B (n=47)	C (n=13)	p-value	Post hoc
Primary endpoint^*	48 (16.3%)	5 (10.6%)	7 (53.8%)	0.001	A=B<C
Ratio of NT-proBNP (Peak/Base)	1.09 [0.79 - 1.80]	1.10 [0.89 - 1.75]	2.52 [1.90 - 5.66]	0.002	A=B<C
Change in log (Peak - Base)	0.04 [-0.10 - 0.26]	0.04 [-0.05 - 0.24]	0.40 [0.28 - 0.75]	0.002	A=B<C
Baseline NT-proBNP	233.5 [92.9 - 525.0]	214.0 [54.6 - 584.5]	265.0 [106.0 - 1215.0]	0.603
Peak NT-proBNP	259.5 [103.0 - 676.0]	246.0 [100.0 - 610.8]	888.0 [560.0 - 2305.0]	0.014	A=B<C
Follow-up NT-proBNP	188.0 [61.7 - 463.0]	163.0 [54.0 - 376.5]	568.0 [210.0 - 992.0]	0.031	A=B<C
Baseline Log NT-proBNP	2.4 [2.0 - 2.7]	2.3 [1.7 - 2.8]	2.4 [2.0 - 3.1]	0.603
Peak Log NT-proBNP	2.4 [2.0 - 2.8]	2.4 [2.0 - 2.8]	2.9 [2.7 - 3.4]	0.014	A=B<C
Follow-up Log NT-proBNP	2.3 [1.8 - 2.7]	2.2 [1.7 - 2.6]	2.8 [2.3 - 3.0]	0.031	A=B<C

Units for all NT-proBNP levels, pg/dL. NT-proBNP - N-terminal-pro hormone B-type natriuretic peptide. ^*Primary endpoint was HF relapse defined as a two-fold increase in baseline NT-proBNP concentration to greater than 400 pg/dL. Ratio of NT-proBNP=Peak NT-proBNP / Base NT-proBNP. Data are presented as median [25th percentile – 75th percentile] or n (%). The values in bold indicate statistical significance (p<0.05).

Table 3. Clinical outcomes.

N(%) or mean ± SD	Total (N=354)	A (N=294)	B (N=47)	C (N=13)	p-value
Follow-up duration, days	399 [252 - 589]	397 [241 - 596]	440 [332 - 574]	300 [273 - 340]	0.062
Hospitalization for heart failure	3 (0.8%)	3 (1.0%)	0 (0.0%)	0 (0.0%)	0.734
Heart transplantation	1 (0.3%)	1 (0.3%)	0 (0.0%)	0 (0.0%)	0.903
Mortality	5 (1.4%)	4 (1.4%)	0 (0.0%)	1 (7.7%)	0.113

Data are presented as median [25th percentile – 75th percentile] or n (%). The values in bold indicate statistical significance (p<0.05).

Change During Follow-Up Period

In the follow-up data of the three groups with medication change after LVEF improvement, several changes compared to baseline were observed. First, all groups showed a numerical increase in both systolic and diastolic blood pressure. However, only in group C was the increase in diastolic blood pressure significant (diastolic blood pressure 60.5 mmHg to 69.2 mmHg). Heart rate showed no significant difference between baseline and follow-up in either the A or B group, but a significant increase was observed in the C group (heart rate 73.5 bpm to 94.0 bpm). Second, the LV end-diastolic dimension decreased significantly in both group A and group B compared to baseline but showed no notable difference in group C. The LV dimension and LV mass index decreased significantly in both group A and group B compared to baseline, whereas they increased but not significantly in group C. LVEF significantly improved in group A compared to baseline (LVEF 46.6% to 51.6%), increased in group B but without statistical significance (LVEF 48.3% to 56.0%), and decreased in group C (LVEF 55.0% to 51.1%). Third, no significant changes in laboratory results were observed from baseline through follow-up (Table 4).

In the overall cohort, the prescription rate of β-blockers significantly decreased from 91% to 59.6%, while that of SGLT-2 inhibitors significantly increased from 37.3% to 48.3%. In group A, β-blocker use declined, whereas SGLT-2 inhibitor prescription significantly increased, with no notable change in spironolactone use. In group B, β-blocker and spironolactone prescriptions significantly decreased, while SGLT-2 inhibitor use significantly increased. In group C, β-blocker use showed a numerical decrease without statistical significance, and SGLT-2 inhibitor use also increased numerically but was not statistically significant. (Table 5).

Table 4. Vital signs, echocardiography, and laboratory result changes during follow-up.

	Total (n=354)	A (n=294)	B (n=47)	C (n=13)	p-value	Post hoc
Vital signs at baseline (n=351)
Systolic blood pressure, mmHg	113.0 [102.0 - 127.0]	113.0 [102.0 - 128.0]	113.0 [104.0 - 126.0]	104.5 [96.5 - 123.0]	0.456
Diastolic blood pressure, mmHg	63.2 ± 14.6	63.4 ± 14.9	62.8 ± 13.9	60.5 ± 8.9	0.772
Heat rate (bpm)	74.0 [67.0 - 83.0]	74.0 [66.0 - 83.0]	78.0 [71.0 - 84.0]	73.5 [71.0 - 83.0]	0.168
Vital signs at follow-up (n=297)
Systolic blood pressure, mmHg	116.0 [104.0 - 131.0]	116.0 [104.5 - 130.0]	118.0 [106.0 - 134.0]	106.0 [101.0 - 132.0]	0.702
Diastolic blood pressure, mmHg	66.0 ± 14.9	66.0 ± 14.9	65.3 ± 14.5	69.2 ± 17.2*	0.699
Heart rate (bpm)	75.0 [67.0 - 85.0]	74.0 [65.0 - 83.0]	78.0 [70.0 - 84.0]	94.0 [82.0 - 100.0]	0.001	A=B<C
Echocardiography at baseline (n=354)
LV end-diastolic dimension, mm	55.5 [51.3 - 58.9]	55.6 [52.0 - 59.3]	55.7 [51.6 - 57.6]	47.1 [43.6 - 48.3]	<0.001	A=B>C
LV end-systolic dimension, mm	38.6 [33.2 - 43.2]	38.8 [34.2 - 43.3]	37.2 [32.9 - 43.5]	30.1 [29.4 - 32.1]	0.001	A=B>C
LV mass index, g/m²	106.7 [92.1 - 125.0]	107.2 [92.1 - 126.1]	103.8 [93.4 - 121.9]	95.1 [86.1 - 118.1]	0.632
LVEF, %	47.0 [43.0 - 55.0]	46.4 [42.6 - 53.7]	48.3 [44.5 - 57.3]	55.0 [47.3 - 58.0]	0.022	A=B<C
LAVI, mL/m²	36.9 [29.1 - 48.5]	36.8 [28.9 - 48.9]	37.4 [31.6 - 43.7]	46.5 [37.8 - 53.1]	0.413
E/e'	10.0 [7.8 - 13.3]	9.8 [ 7.6 - 13.6]	9.8 [ 7.6 - 13.6]	11.9 [ 7.0 - 15.0]	0.881
RV systolic pressure, mmHg	26.4 [23.3 - 30.0]	26.4 [23.4 - 29.2]	26.4 [23.4 - 29.2]	26.2 [25.5 - 33.1]	0.676
Echocardiography atfollow-up (n=297)
LV end-diastolic dimension, mm	54.0 [50.0 - 57.5]*	54.2 [50.3 - 58.0]*	53.4 [50.4 - 57.0]*	48.3 [46.3 - 52.1]	0.047	A=B>C
LV end-systolic dimension, mm	36.0 [32.2 - 41.2]*	36.8 [33.0 - 41.3]*	34.0 [31.9 - 40.6]*	31.0 [28.9 - 35.9]	0.090
LV mass index, g/m2	99.2 [85.2 - 115.9]*	99.4 [84.8 - 117.5]*	98.8 [87.4 - 113.2]*	89.6 [87.7 - 107.7]	0.786
LVEF, %	52.5 [45.4 - 58.1]*	51.6 [44.9 - 58.0]*	56.0 [48.6 - 59.0]	51.1 [51.0 - 58.5]	0.085
LAVI, mL/m2	36.2 [27.9 - 46.6]	35.8 [27.9 - 45.6]	37.5 [28.8 - 47.8]	34.5 [20.3 - 58.6]	0.868
E/e'	9.7 [7.3 - 13.5]	9.8 [ 7.4 - 13.5]	8.2 [ 6.8 - 11.2]	9.7 [ 7.8 - 17.2]	0.483
RV systolic pressure, mmHg	25.7 [22.9 - 31.5]	25.4 [22.9 - 31.4]	28.6 [24.3 - 31.5]	23.0 [20.6 - 31.5]	0.370
Laboratory at baseline
Hemoglobin, g/dL (n=311)	13.7 [12.1 - 15.0]	13.7 [12.3 - 15.0]	13.6 [12.0 - 14.9]	11.5 [10.6 - 13.7]	0.055
BUN, mg/dL (n=347)	17.1 [13.3 - 21.8]	17.2 [13.2 - 21.5]	16.3 [13.4 - 21.4]	25.0 [14.2 - 45.1]	0.174
Creatinine, mg/dL (n=346)	0.9 [0.8 - 1.1]	0.9 [0.8 - 1.1]	1.0 [0.8 - 1.2]	1.1 [0.8 - 1.7]	0.550
eGFR, mL/min/1.73㎡ (n=346)	81.8 [60.3 - 96.4]	82.4 [60.7 - 96.8]	81.4 [66.2 - 93.2]	70.5 [40.5 - 89.8]	0.347
Sodium, mmol/L (n=345)	140.0 [138.0 - 141.0]	140.0 [138.0 - 141.0]	140.0 [138.5 - 141.0]	138.0 [134.0 - 140.0]	0.022	A=B>C
Potassium, mg/dL (n=345)	4.4 [4.1 - 4.8]	4.4 [4.1 - 4.8]	4.4 [4.1 - 4.8]	4.4 [4.2 - 4.9]	0.953
Laboratory atfollow-up
Hemoglobin, g/dL (n=321)	13.8 [12.5 - 14.7]	13.9 [12.5 - 14.9]	13.1 [12.5 - 14.4]	11.8 [10.4 - 14.6]	0.050
BUN, mg/dL (n=353)	17.0 [13.2 - 22.2]	16.8 [13.2 - 22.2]	17.6 [13.8 - 21.8]	18.1 [12.8 - 23.3]	0.958
Creatinine, mg/dL (n=353)	1.0 [0.8 - 1.1]	0.9 [ 0.8 - 1.1]	1.0 [ 0.9 - 1.1]	0.9 [ 0.6 - 1.1]	0.690
eGFR, mL/min/1.73㎡ (n=353)	81.0 [62.1 - 93.7]	81.0 [60.9 - 94.0]	81.4 [63.7 - 91.8]	76.9 [61.1 - 97.2]	0.966
Sodium, mmol/L (n=353)	140.0 [138.0 - 141.0]	140.0 [138.0 - 141.0]	140.0 [138.0 - 141.0]	139.0 [137.0 - 141.0]	0.318
Potassium, mg/dL (n=353)	4.5 [4.2 - 4.8]	4.5 [4.2 - 4.8]	4.5 [4.0 - 4.8]	4.5 [4.4 - 5.3]	0.242

BUN, blood urea nitrogen; EF, ejection fraction; eGFR, estimated glomerular filtration rate; LAVI, left atrial volume index; LV, left ventricle/ventricular; RV, right ventricle/ventricular. Data are presented as mean ± standard deviation, median [25th percentile – 75th percentile], or n (%). The values in bold indicate statistical significance (p<0.05). *p<0.05 compared to baseline.

Table 5. Medication changes during follow-up.

	Total (n=354)	A (n=294)	B (n=47)	C (n=13)	p-value
Medication at baseline
Beta blocker	322 (91.0%)	270 (91.8%)	42 (89.4%)	10 (76.9%)	0.171
Spironolactone	286 (80.8%)	235 (79.9%)	42 (89.4%)	9 (69.2%)	0.175
SGLT-2 inhibitor	132 (37.3%)	119 (40.5%)	9 (19.1%)	4 (30.8%)	0.017
Medication at follow-up
Beta blocker	211 (59.6%)*	176 (59.9%)*	30 (63.8%)*	5 (38.5%)	0.250
Spironolactone	274 (77.4%)	231 (78.6%)	34 (72.3%)*	9 (69.2%)	0.493
SGLT-2 inhibitor	171 (48.3%)*	149 (50.7%)*	16 (34.0%)*	6 (46.2%)	0.105

ACEI, angiotensin-converting enzyme inhibitor; ARB, angiotensin II receptor blocker; CRT, cardiac resynchronization therapy; ICD, implantable cardioverter-defibrillator. Data are presented as n (%). *p<0.05 compared to baseline.

Discussion

The main finding of this study is the significantly increased incidence of HF relapse, defined as a two-fold increase of serum NT-proBNP level to higher than 400 pg/dl, in patients with HF with S/V discontinuation after LVEF improvement (group C), the change was not different between patients who maintained S/V or changed to another RASB (groups A and B). The difference between peak and baseline log NT-proBNP levels showed an interval increase in group C in contrast to an interval decrease in groups A and B.

Cardiac Function Recovery in the S/V Era

The reported proportion range of patients who achieve recovery of LVEF is various according to studies.[2,5,6,7,8] This variability could be due to the variable LVEF of enrolled patients, definition of recovered HF, and/or prescribed medication. From our cohort of all patients with HFrEF treated with S/V, 39.4% (n=410 of 1,040) experienced a recovery of LVEF ≥ 40%. Recovery of cardiac function is an important indicator in the treatment of HF, as it is associated with improved prognosis.[9] Although previous studies have confirmed that the use of S/V leads to better outcomes compared to other RASBs, data on the rate of LVEF improvement remain limited.[10,11] However, the current study is limited by its retrospective design, and further confirmation through prospective studies with large numbers of patients is necessary.

Maintain Strategy in HFimpEF

There are scarce data on outcomes after tapering HF medication in HFimpEF. The well-known TRED-HF trial resulted in 40% relapse of HF six months after withdrawing all HF medication including angiotensin-converting enzyme inhibitor and angiotensin II receptor blocker, beta blocker, mineralocorticoid receptor antagonist, and loop diuretics.[3] Other studies that investigated the effect of tapering an HF medication other than RASB all reported clinical deterioration.[12,13,14] In one of these studies, the effect of the tapering medication itself was also tested by protocol-specified withdrawal after double-blinded, randomized treatment with empagliflozin versus placebo. The result was exacerbated HF after withdrawal from empagliflozin but not from placebo.[12]

S/V reduces NT-proBNP levels in HF with various ranges of LVEF.[15,16,17] Limited data have reported S/V to be associated with a greater NT-proBNP reduction compared to other RASBs in HF patients.[17,18] However, the benefit of maintaining S/V in patients with HFimpEF has not been investigated. A retrospective analysis by Chang et al. reported a decreased LVEF and increased composite outcome of cardiovascular death and hospitalization for HF over 18 months in a group with tapered dose of S/V or replacement with RASB compared to a group with the same maintenance dose of S/V but with other HF medications such as beta blockers and MRA in patients with LVEF recovery ≥ 50% after treatment with S/V.[2] However, patients with recovered LVEF were not the primary group of analysis and the number of subjects was small. Therefore, to the best of our knowledge, we are the first to report that clinical outcomes are comparable between patients maintaining S/V and those switching to RASB after successful improvement of LVEF in patients with HFrEF, while the outcomes are worse in those who discontinued S/V and did not start an RASB.

The clinical conditions associated with the primary endpoint were various. A recent analysis of the TRED-HF trial reported that lower heart rate was associated with a lower risk of relapse in patients withdrawn from HF medication.[19] In this study, the C group exhibited a higher relapse rate and a significantly higher heart rate at follow-up compared to the other groups (94.0 [82.0 - 100.0] bpm in group C). This heart rate was notably higher than the values reported in TRED-HF (86.1 ± 11.8 bpm). These findings suggest that discontinuing S/V may affect hemodynamics by triggering an increase in sympathetic tone and reactivation of the renin-angiotensin system. It is also noteworthy that the primary outcomes in group C, the medication discontinuation group, occurred predominantly within six months, similar to the TRED-HF study.

Chang et al. reported increased LVEF and less deterioration over six months in the group who maintained S/V compared to the tapered group (LVEF 56.4±5.3% vs. 45.0±12.8%, p<0.001; ΔLVEF 1.2±5.1% vs. -9.3±12.0%, p<0.001).[2] In contrast, our study showed improvements in LV dimensions and LVEF in both the A and B groups. The discrepancy between our findings and those of Chang et al. may be attributed to differences in reimbursement policies between the two countries, which may have influenced patient selection in the tapering group of Chang et al.'s study, resulting in a patient population with lower economic status, differing from ours.

HFimpEF patients are known to have substantially lower incidence of cardiovascular events and hospitalizations compared to patients with HFrEF and HF with preserved EF.[5] The TRED-HF trial reported no events within the initial six month study period.[3] Chang et al. reported more frequent hospitalization for HF and cardiovascular death in the tapered group than the maintenance group (23.1% vs. 5.9%, HR 0.22, p=0.035).[2] Although our study had a longer observation period of 13 months, the clinical event rates were too low to discriminate between groups. A long-term study is needed to determine whether tapering S/V will result in increased cardiovascular events.

Interpretation of the Primary Endpoint

For those who met the primary endpoint, the clinical conditions associated with NT-proBNP increase are shown in Supplementary Table 2. Among patients with elevated NT-proBNP levels, the majority (35%) did not exhibit any distinct clinical symptoms. Approximately 20% of patients who met the primary endpoint exhibited signs indicative of cardiac function deterioration, such as tachyarrhythmia, acute cardiovascular events, or progressive LV failure. Cases that could have demonstrated false increase in NT-proBNP, such as infection, renal dysfunction, and anemia, accounted for 25% of the study population.

Limitations

This study needs to be interpreted with caution due to several limitations. First, due to its retrospective design, baseline time points had to be different between groups who maintained or discontinued S/V. However, the average time difference between LVEF improvement and S/V discontinuation in groups B and C was only three days, hindering conclusion of baseline differences. Second, this was a small single-center study with a short observation period of approximately one year. Since this study was conducted at a referral center, there is a possibility that patients with relatively greater severity were included. Third, follow-up echocardiographic data were not available in all patients. The absence of these data may impose limitations on the interpretation of the results. Fourth, the prescription rate of SGLT-2 inhibitors is lower than that of other medications, as they have been officially recognized as a treatment for heart failure only since 2021, with insurance coverage in Korea beginning after 2024. However, due to these changes, the prescription of SGLT-2 inhibitors increased during follow-up compared to baseline.

Despite these limitations, the lack of differences in clinical outcomes and hemodynamics between the group that continued S/V and the group that switched to other RASBs in patients with improved HF is a novel finding not observed in previous studies. To confirm this result, studies with larger numbers of participants and prospective design are needed. In line with this necessity, we are currently conducting a prospectively designed study (NCT04803175) to overcome this limitation.

Conclusion

In a retrospective analysis from a single tertiary hospital, replacing S/V with another RASB did not result in worse outcomes in HF patients with improved LVEF ≥ 40% and resolved the symptoms. A prospective trial is needed to determine whether S/V replacement with other RASBs is safe and effective in maintaining remission after improvement of LVEF in HFrEF patients.

Abbreviations and Acronyms

HFimpEF	heart failure with improved ejection fraction
HFrEF	heart failure with reduced ejection fraction
LVEF	left ventricular ejection fraction
NT-proBNP	N-terminal-pro hormone B-type natriuretic peptide
RASB	renin-angiotensin-system blockers
S/V	sacubitril/valsartan

Supplementary Materials

The following supporting information can be downloaded at the website of this paper posted on Preprints.org. Supplementary Table 1. Characteristics of the patients who discontinued S/V. Supplementary Table 2. Clinical conditions of patients who achieved the primary endpoint

Data Availability Statement

Due to patient confidentiality and ethical restrictions, the data are not publicly available. However, de-identified data may be shared upon reasonable request and with approval from the Institutional Review Board.

Acknowledgements

We would like to express our gratitude to Mr. Ju-Hyun Kyung and Mrs. Cho-ja Han for their contributions to the Medical Research Fund of Samsung Medical Center.

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