Impact of prior statin use on clinical outcomes in COVID-19 patients: data from tertiary referral hospitals during COVID-19 pandemic in Italy.

BACKGROUND: Epidemiological evidence suggests that anti-inflammatory and immunomodulatory properties of statins may reduce the risk of infections and infection-related complications.
OBJECTIVE: We aimed to assess the impact of prior statin use on coronavirus disease (COVID-19) severity and mortality.
METHODS: In this observational multicenter study, consecutive patients hospitalized for COVID-19 were enrolled. In-hospital mortality and severity of COVID-19 assessed with National Early Warning Score (NEWS) were deemed primary and secondary outcomes, respectively. Propensity score (PS) matching was used to obtain balanced cohorts.
RESULTS: Among 842 patients enrolled, 179 (21%) were treated with statins before admission. Statin patients showed more comorbidities and more severe COVID-19 (NEWS 4 [IQR 2-6] vs 3 [IQR 2-5], p < 0.001). Despite having similar rates of intensive care unit admission, noninvasive ventilation, and mechanical ventilation, statin users appeared to show higher mortality rates. After balancing pre-existing relevant clinical conditions that could affect COVID-19 prognosis with PS matching, statin therapy confirmed its association with a more severe disease (NEWS ≥5 61% vs. 48%, p = 0.025) but not with in-hospital mortality (26% vs. 28%, p = 0.185). At univariate logistic regression analysis, statin use was confirmed not to be associated with mortality (OR 0.901; 95% CI: 0.537 to 1.51; p = 0.692) and to be associated with a more severe disease (NEWS≥5 OR 1.7; 95% CI 1.067-2.71; p = 0.026).
CONCLUSIONS: Our results did not confirm the supposed favorable effects of statin therapy on COVID-19 outcomes. Conversely, they suggest that statin use should be considered as a proxy of underlying comorbidities, which indeed expose to increased risks of more severe COVID-19.

Introduction

Coronavirus disease 2019 (COVID-19) is a viral infection caused by severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2), potentially leading to acute respiratory distress syndrome (ARDS) requiring invasive ventilation and intensive care unit (ICU) admission. It has to be underlined though, that some patients may be asymptomatic or have mildly symptomatic COVID-19.1, 2, 3 Despite the exact pathophysiologic mechanisms of COVID-19 remain largely unknown, it has been suggested that, during the response to SARS-CoV-2 infection, the immune dysregulation and the high levels of pro-inflammatory cytokines might represent pivotal causes of tissue injury.4, 5, 6 The severity of COVID-19 seems to be related with older age and comorbidities. In particular, patients with pre-existing cardiovascular disease (CVD) have an elevated risk of adverse outcomes, and, on the other hand, SARS-CoV-2 infection is associated with vascular and arrhythmic complications.10, 11, 12, 7, 8, 9

Traditional cardiovascular (CV) risk factors, such as dyslipidemia, are recognized to have an impact on the immune system,13, 14, 15 and therefore it has been postulated that pre-existing CV risk factors may be related with the immune response to SARS-CoV-2 infection and with COVID-19 severity.

Hydroxymethyl-glutaryl Coenzyme A (HMG-CoA) reductase inhibitors, or statins, which are widely used to prevent and treat CVD because of their lipid-lowering ability, have been proposed to have a role as an add-on treatment for COVID-19 patients. , This role has been suggested not only in light of their proven lipid-lowering ability, but mostly because of their known pleiotropic effects on vascular balance, thrombogenic response, oxidative stress, and inflammation, at different levels. Indeed, some observational studies conducted among outpatients and hospitalized patients with sepsis and/or

Pneumonia, have demonstrated that statin therapy is associated with a reduced risk of pneumonia, a milder disease, and a reduced mortality,21, 22, 23, 24 while others , did not show a beneficial relationship between statin use and clinical outcomes in the same settings. Despite mechanisms of actions and advantages of statins that have been proposed, little is known about their real world clinical impact in COVID-19 patients. Hence, we performed a retrospective study to assess the association of statin therapy at hospital admission with clinical outcomes in COVID-19 patients.

Methods

Study population

The study was approved by the institutional ethics board of the Italian hospitals involved (Luigi Sacco Hospital, Milan; Policlinico Umberto I Hospital, Rome; Spedali Civili Hospital, Brescia; Humanitas Gavazzeni Hospital; Bergamo). From February 23, 2020 to March 31, 2020, 987 consecutive patients presenting to the emergency department (ED) of the hospitals involved were screened. Confirmed cases of COVID-19 were defined with a positive result on a reverse-transcriptase-polymerase-chain-reaction assay performed on a nasopharyngeal swab, in accordance with World Health Organization (WHO) guidelines.

Inclusion criteria for study enrollment were:

age ≥ 18 years;

an in-hospital stay of at least 24 h, defined as ED management and subsequent early discharge or hospital admission;

all patients included in the study had completed their hospital course (discharge or death) at the time of data analysis.

Study design

Patients were divided into 2 groups (statin vs. no-statin group): patients were included in the statin group if they were taking statins for at least 1 month before hospital admission for COVID-19. Data recorded at the time of ED admission/hospitalization included age, sex, medical history, symptoms reported to ED presentation, time from symptom onset, vital signs, laboratory values, arterial blood gas analysis, home medical therapy. Data regarding in-hospital management, medical treatment and clinical outcomes were evaluated during data collection. Chronic kidney disease (CKD) was defined by the presence of an estimated glomerular filtration rate (eGFR) ≤ 60 mL/min/m2, calculated with the CKD-EPI equation. Fever was defined as axillary temperature of at least 37.5 °C. Sepsis and septic shock were defined according to the 2016 Third International Consensus Definition. Myocardial injury was defined in accordance with the fourth universal definition of myocardial infarction (MI) (high sensitivity cardiac troponin [hs-cTn] above the 99th percentile of the upper reference limit). National Early Warning Score (NEWS) was retrospectively assessed to determine the severity of illness and clinical deterioration at the moment of hospital admission. The six parameters included in this scoring system are respiratory rate, oxygen saturation, temperature, systolic blood pressure, heart rate and level of consciousness (Table 1 - data supplement). Patients with moderate to severe disease were defined by a NEWS ≥ 5 while patients with mild disease were defined by a NEWS < 5, in order to establish a group of patients that in real-world multicenter registry may exhibit a more severe disease. The primary outcome was in-hospital mortality. The secondary outcome of interest was the COVID-19 severity at presentation, defined by a NEWS ≥ 5.

Table 1

Balancing check of covariates before and after propensity score matching based on logit model.

	Unmatched or matched	mean		ASMD	t-test
		Statin	No-Statin		t	p
Male	U	0.704	0.593	−0.2293	−2.836	0.005
	M	0.690	0.669	−0.042	−0.376	0.707
Age > 65	U	0.737	0.416	−0.6652	−7.898	<.001
	M	0.731	0.690	−0.091	−0.775	0.439
Obesity	U	0.134	0.0830	−0.1756	−1.846	0.037
	M	0.124	0.117	−0.021	−0.180	0.858
Hypertension	U	0.771	0.365	−0.8644	−10.262	<0.001
	M	0.731	0.697	−0.076	−0.648	0.517
Diabetes	U	0.352	0.116	−0.6550	−6.222	<.001
	M	0.303	0.359	0.0915	0.997	0.319
Smoking	U	0.185	0.0920	−0.2950	−2.964	0.003
	M	0.138	0.124	−0.040	−0.347	0.729
CAD	U	0.413	0.0573	−1.1595	−9.371	<.001
	M	0.284	0.248	−0.077	−0.663	0.507
AF	U	0.168	0.0679	−0.3533	−3.363	<.001
	M	0.159	0.152	−0.019	−0.162	0.872
HF	U	0.112	0.0271	−0.4127	−3.460	<.001
	M	0.0966	0.0966	0.000	0.000	1.000
CKD	U	0.140	0.0558	−0.3235	−3.053	0.003
	M	0.124	0.131	0.020	0.175	0.861
COPD	U	0.0694	0.0838	−0.0556	−0.660	0.510
	M	0.0828	0.103	0.071	0.605	0.546
Cerebrovascular disease	U	0.0271	0.0782	−0.2683	−2.421	0.016
	M	0.0552	0.0621	0.029	0.249	0.804
Malignancy	U	0.112	0.0694	−0.1577	−1.655	0.062
	M	0.0966	0.0552	−0.0897	−1.330	0.185

ASMD = Absolute standardized mean difference; CAD = Coronary artery disease; AF = atrial fibrillation; HF = heart failure; CKD = Chronic kidney disease; COPD = Chronic obstructive pulmonary disease.

Statistical analysis

Continuous variables are expressed as mean ± standard deviation (SD) or median and interquartile range (IQR) if not normally distributed according to D'Agostino-Pearson test. Categorical data are expressed as absolute values and proportions. Student's t-test for independent samples with a confidence interval of 95% was used for continuous variables; otherwise, either logarithmic transformation of variables or nonparametric tests (Mann–Whitney U) were used. A chi-squared test or a Fisher exact test were performed to examine whether there was an association between categorical variables. Univariate linear regression was used to assess correlation between variables. Odds ratio (OR) and 95% confidence interval (CI) were reported. A two tailed P values < 0.05 were considered significant. All statistical analyses were performed using IBM SPSS Statistics (version 26.0).

Propensity score matching

We used the propensity score (PS) method to minimize the effect of potential confounders on selection bias. The PS for an individual was defined as the conditional probability of taking statin given the individual's clinical pre-existing conditions (covariates). To estimate the scores, we created a logistic regression model including twelve relevant covariates potentially related to COVID-19 clinical presentation and outcome. Variables considered for the PS matching were age ≥ 65 years, male gender, obesity, hypertension, diabetes, smoke, coronary artery disease (CAD), atrial fibrillation (AF), heart failure (HF), chronic kidney disease (CKD), chronic obstructive pulmonary disease (COPD), cerebrovascular disease and malignancy. Patients with prior statin therapy use were matched 1:1 to no-statin therapy patients by PS, using the nearest neighbor method with a caliper of 0.1 and no replacement. Absolute standard difference and t-test were applied for balancing check of covariates both before and after matching. For good balancing, t-test for equality of means should be non-significant after matching, and the absolute standard difference should be < 0.1 after matching (Table 1).

Results

A total of 842 patients met the inclusion criteria and were therefore enrolled as study cohort. Propensity score matching (PS) identified 145 patients in each group according to prior statin use.

Baseline and characteristic on admission before and after propensity score matching

Patient demographic and clinical characteristics for the unadjusted and PS matched patients are shown in Table 2 . As many as thirteen covariates, identifying demographic and pre-existing clinical conditions (age, elderly patients [≥65 years], gender, obesity, hypertension, diabetes, dyslipidemia, smoke, CAD, AF, HF, CKD and cerebrovascular disease), were significantly different (p < 0.05) between the two groups before matching. However, all covariates were comparable and well balanced (p > 0.05) between both groups after PS matching. Before PS matching of demographic and pre-existing clinical variables, patients in statin therapy showed lower oxygen saturation, PaO2, PaO2/FiO2 ratio, and a higher NEWS (4 [IQR 2–6) vs. 3 [IQR 2–5] p < 0.001) with a higher incidence of patients on statin therapy presenting moderate/severe disease (as meant as a NEWS≥5) at the moment of hospital admission (58% vs. 44%, p < 0.001). After PS matching, only the presence of moderate/severe disease remained significantly more represented in the group of patients on statin therapy respect to patients in non-statin group (61% vs. 48%, p = 0.025). This secondary outcome remained significantly associated with statin use also to univariate logistic regression (OR 1.7; 95% CI 1.067–2.71; p = 0.026).

Table 2

Demographic and clinical variables by group among unadjusted and propensity-matched cohorts, stratified by statin therapy.

Variables	Overall population (N = 842)	Unadjusted data			Propensity score matched data
		Statin group (N = 179)	No-statin group (N = 663)	P-value	Statin group (N = 145)	No-statin group (N = 145)	P-value
Demographics
Age, years	64 (61–77)	73 (65–81)	61 (49–74)	< .001	71 (64–79)	72 (61–80)	0.707
Age ≥ 65, N (%)		123	276	< .001	106 (73)	100 (69)	0.439
Male gender, N (%)	519 (62)	126 (70)	393 (59)	0.006	100 (69)	97 (67)	0.707
BMI (kg/m2) ≥ 30 kg/m, N (%)	79 (9)	24 (13)	55 (8)	0.037	18 (12)	17 (12)	0.797
Comorbidities, N (%)
Hypertension	380 (45)	138 (77)	242 (37)	< .001	106 (73)	101 (70)	0.517
Diabetes	140 (17)	63 (35)	77 (12)	< .001	44 (30)	52 (36)	0.319
Dyslipidemia	201 (24)	177 (98)	24 (4)	< .001
Smoking	94 (11)	33 (18)	61 (9)	< .001	20 (14)	18 (12)	0.729
CAD	112 (13)	74 (41)	38 (6)	< .001	41 (28)	36 (25)	0.507
Atrial fibrillation	75 (9)	30 (17)	45 (7)	< .001	23 (17)	22 (15)	0.872
Heart failure	38 (5)	20 (11)	18 (3)	< .001	14 (10)	14 (10)	1.000
CKD	62 (7)	25 (14)	37 (6)	< .001	18 (13)	19 (13)	0.861
COPD	61 (7)	15 (8)	46 (7)	0.510	12 (8)	15 (10)	0.546
Cerebrovascular disease	32 (4)	14 (8)	18 (3)	0.001	8 (6)	9 (6)	0.804
Malignancy	66 (8)	20 (11)	46 (7)	0.062	14 (10)	8 (6)	0.185
Statins therapy, N (%)
Atorvastatin		87 (49)		–
Simvastatin		54 (30)		–
Rosuvastatin		29 (16)		–
Other Statins		9 (5)		–
Symptoms on admission, N (%)
Cough	594 (71)	118 (66)	476 (72)	0.126	100 (69)	107 (74)	0.364
Shortness of breath	402 (48)	96 (54)	306 (46)	0.076	76 (52)	74 (51)	0.815
Sore throat	149 (18)	18 (10)	131 (20)	0.003	16 (11)	29 (20)	0.035
Sputum production	39 (5)	10 (6)	29 (4)	0.494	9 (6)	7 (5)	0.608
Myalgia	97 (12)	26 (15)	71 (11)	0.156	22 (15)	20 (14)	0.740
Diarrhea	87 (10)	20 (11)	67 (10)	0.678	18 (12)	11 (8)	0.172
Nausea/Vomiting	39 (5)	12 (7)	27 (4)	0.138	12 (8)	5 (3)	0.081
Symptom onset, days		6 (3–9)	7 (3–10)	0.346	6 (3–8)	7 (3–10)	0.438
Hospital admission
Fever, N (%)	736 (87)	149 (83)	587 (89)	0.058	121 (83)	129 (89)	0.174
Temperature, °C	38 (37.5–38.3)	38 (37.5–34.4)	38 (37.6–38.3)	0.111	38 (37.5–38.4)	38 (37.5–38.2)	0.628
Heart rate, beat x min	38 (75–99)	82 (73–96)	86 (75–99)	0.061	82 (75–95)	85 (74–100)	0.698
Respiratory Rate,min.	20 (18–21)	20 (18–20)	20 (18–21)	0.129	20 (18–20)	20 (20–22)	0.075
Oxygen saturation, %	96 (93–98)	95 (91–97)	96 (93–98)	< .001	95 (91–97)	96 (92–98)	0.137
PaO2/FiO2, mmHg	310 (190–386)	265 (133–338)	324 (214–395)	< .001	274 (149–348)	305 (184–367)	0.082
PaO2, median	78 (67–89)	76 (63–88)	78 (68–90)	0.048	74.5 (62.3–87)	74 (63–86.5)	0.710
MAP, mmHg	97 (90–105)	99 (90–107)	97 (90–105)	0.222	100 (90–110)	95 (87–103)	0.064
NEWS	3 (2–5)	4 (2–6)	3 (2–5)	< .001	4 (2–6)	3 (2–5)	0.054
Moderate/severe disease (NEWS ≥ 5)		104 (58)	291 (44)	< .001	88 (61)	69 (48)	0.025

Continuous variables are reported as median (interquartile range).

BMI=Body mass index; CAD= Coronary artery disease; CKD = Chronic kidney disease; COPD= Chronic obstructive pulmonary disease; PaO2 = oxygen partial pressure at arterial gas analysis; FiO2 = fraction of inspired oxygen; MAP = mean aortic pressure; NEWS = National Early Warning Score.

In-hospital management and outcomes before and after propensity score matching

Data regarding in-hospital management and clinical outcomes are summarized in Table 3 . In the overall population, patients in the statin group were more likely to receive oxygen support (86% vs. 75% p = 0.002) and to develop myocardial injury (20% vs. 9%, p < 0.001) than patients in non-statin group, as well as showing higher all-cause mortality rate (29% vs. 20%, p = 0.006) and a longer in-hospital stay. With regard to laboratory and radiological findings (Table 4 ), in the non-matched population, patients in the statin group showed a higher white blood cell count, lactate dehydrogenase, creatine phosphokinase, creatinine, and hs-cTn, with lower levels of hemoglobin compared with patients in non-statin group patients. Based on radiological findings, pneumonia was diagnosed in the majority of patients (89%) on admission, with a higher incidence among patients in statin therapy (94 vs. 87%; p = 0.013) and also showed worse radiological features. After PS matching, only hemoglobin level remained significantly lower in the statin group respect to no-statin group (13.2; IQR 12–14.4 vs. 13.6; IQR 12.4–15; p = 0.037). Of note, in the statin patient cohort, a significantly lower level of C-reactive protein was noted with respect to the control group (20.2; IQR 8.13–99.7 vs. 36; IQR 11.6–99.7; p = 0.021). Moreover, both groups showed a similar prevalence of pneumonia on admission, while worse radiological features were confirmed after PS matching in the statin group. While mortality rates significantly differed among the two unmatched groups (29% vs. 20%, p = 0.006), after PS matching no significant differences were found (26% vs. 28%, p = 0.185). At univariate logistic regression analysis for mortality, statin use was confirmed not to be associated with the primary outcome (OR 0.901; 95% CI: 0.537 to 1.51; p = 0.692).

Table 3

In-hospital management and outcomes by group among unadjusted and propensity-matched cohorts, stratified by statin therapy.

Variables	Overall population (N = 842)	Unadjusted data			Propensity score matched data
		Statin group (N = 179)	No-statin group (N = 663)	P-value	Statin group (N = 145)	No-statin group (N = 145)	P-value
In-hospital treatment, N (%)
Non-invasive ventilation	286 (34)	66 (37)	220 (33)	0.355	49 (34)	50 (34)	0.902
Oxygen suypport	651 (77)	154 (86)	497 (75)	0.002	122 (84)	114 (79)	0.229
Intubation	42 (5)	6 (3)	36 (5)	0.258	6 (4)	10 (7)	0.305
Antibiotics	371 (44)	84 (47)	287 (43)	0.385	65 (45)	85 (59)	0.019
Corticosteroids	93 (11)	23 (13)	70 (11)	0.386	17 (12)	18 (12)	0.858
Hydroxychloroquine	680 (81)	152 (85)	528 (80)	0.112	121 (83)	120 (83)	0.876
Antiviral therapy	466 (55)	93 (52)	373 (56)	0.304	72 (50)	96 (66)	0.040
Heparin	382 (47)	94 (53)	298 (45)	0.072	70 (48)	63 (43)	0.411
Tocilizumab	126 (15)	24 (13)	102 (15)	0.511	19 (13)	12 (8)	0.185
Outcomes, N (%)
ICU admission	46 (5)	6 (3)	40 (6)	0.162	6 (4)	11 (8)	0.213
ARDS	155 (18)	41 (23)	114 (17)	0.080	24 (17)	32 (22)	0.235
Myocardial Injury	96 (11)	35 (20)	61 (9)	< .001	25 (17)	28 (19)	0.670
Acute kidney injury	26 (3)	5 (3)	21 (3)	0.798	4 (3)	9 (6)	0.157
Septic Shock/Sepsis	19 (2)	5 (3)	14 (2)	0.586	4 (3)	4 (3)	1.000
Death	182 (22)	52 (29)	130 (20)	0.006	38 (26)	41 (28)	0.185
Hospital stay, days	9 (5–15)	11 (6–16)	9 (5–14)	0.026	11 (6–16)	11 (7–16)	0.920

ICU = intensive care unit; ARDS = acute respiratory distress syndrome.

Table 4

Laboratory findings by group among unadjusted and propensity-matched cohorts, stratified by statin therapy.

Variables	Reference range	Unadjusted data		P-value	Propensity score matched data		P-value
		Statin group (N = 179)	No-statin group (N = 663)		Statin group (N = 145)	No-statin group (N = 145)
Laboratory findings
White blood cell count, per 109/L	4.19–9.35	6.4 (4.8–9.53)	5.9 (4.6–7.99)	0.029	6.22 (4.8–9.14)	6.0 (4.97–8.22)	0.678
Lymphocytes, per 109/L	1.13–3.37	0.93 (0.66–1.3)	0.98 (0.7–1.4)	0.183	0.98 (0.695–1.3)	0.98 (0.68–1.36)	0.635
Neutrophils, per 109/L	1.91–6.23	4.69 (3.13–7.3)	4.14 (3–6)	0.013	4.64 (3.17–6.39)	4.4 (3.36–6.39)	0.621
Monocytes, per 109/L	0.29–0.81	0.45 (0.3–0.7)	0.43 (0.3–0.6)	0.124	0.43 (0.3–0.7)	0.46 (0.33–0.62)	0.870
Platelet count, per 109/L	155–360	201 (143–282)	193 (153–252)	0.401	207 (148–277)	196 (154–241)	0.355
Haemoglobin, g/dL	12.0–6.0	13.2 (12–14.4)	13.8 (12.7–14.8)	< .001	13.2 (12–14.4)	13.6 (12.4–15)	0.037
C-Reactive protein, mg/L	<10	20.6 (8.72–67.4)	18.4 (6.01–67.5)	0.303	20.2 (8.13–99.7)	36 (11.6–99.7)	0.021
Lactate dehydrogenase, U/L	125–360	360 (271–492)	310 (235–404)	0.001	352 (261–473)	335 (269–403)	0.328
Creatine phosphokinase, U/L	29–322	134 (73.8–283)	98 (58–181)	0.004	113 (73.8–289)	134 (65–229)	0.156
Creatinine, mg/dL	0.5–0.95	1.04 (0.84–1.4)	0.92 (0.77–1.1)	< .001	1 (0.827–1.33)	1.01 (0.83–1.3)	0.728
High-sensitivity cardiac troponin T, ng/L	<14	31 (13–50)	16 (7–40)	< .001	31 (13–43)	32 (17.5–64)	0.088
D-Dimer, μg/L	<500	806 (356–2901)	918 (490–2228)	0.739	772 (351–3171)	1566 (572–3171)	0.404
Chest X-Ray findings, N (%)
Pneumonia on admission		168 (94)	578 (87)	0.013	137 (95)	129 (89)	0.089
Pulmonary infiltrations		131 (73)	425 (64)	0.023	98 (68)	106 (73)	0.305
Ground-glass opacity		104 (58)	330 (50)	0.048	84 (58)	55 (38)	<.001
Consolidation lesions		113 (63)	313 (47)	< .001	88 (61)	61 (42)	0.002

Statin intensity analysis in propensity score matched population

In-hospital mortality and severity of disease within the balanced cohort of statin users, stratified by statin intensity, are shown in Table 5 . The majority of patients were treated with high intensity (48%) and moderate-intensity statins (39%) respect to low-intensity (13%) (p < 0.05) (Fig. 1 ). At univariate logistic regression, patients using high intensity and moderate intensity statins showed a worse clinical presentation of COVID-19 (NEWS ≥ 5) at hospital presentation respect to patients taking low-intensity statins (OR 3.88; 95% CI: 1.356–11.10 p = 0.011 and OR 2.96; 95% CI 1.022–8.55; p = 0.046, respectively). Of note, these data did not correlate with the in-hospital mortality that remained similar among groups.

Table 5

Multinomial univariate logistic regression of in-hospital death and moderate/severe disease (NEWS ≥ 5) according to statin intensity.

Statin Intensity	Predictor	Estimate	SE	Z	p	OR	95% Confidence Interval
							Lower	Upper
Moderate Intensity vs. Low Intensity	Death	0.357	0.635	0.562	0.574	1.43	0.412	4.96
	NEWS ≥ 5	1.084	0.542	2.00	0.046	2.96	1.022	8.55
High Intensity vs. Low Intensity	Death	0.439	0.621	0.707	0.480	1.55	0.459	5.24
	NEWS ≥ 5	1.357	0.536	2.52	0.011	3.88	1.356	11.10
High Intensity vs. Moderate Intensity	Death	0.0823	0.404	0.203	0.839	1.167	0.773	1.762
	NEWS ≥ 5	0.273	0.376	0.728	0.467	1.314	0.629	2.745

OR = odds ratio; NEWS = National Early Warning Score.

Fig. 1

Schematic representation of statin intensity distribution in the matched cohort of statin users (N = 145).∗p < 0.05 vs. Low-Intensity group.

Discussion

To the best of our knowledge, this is the first study specifically focused on the role of statins in COVID-19 patients. Hereby, we report data demonstrating that patients on prior statin therapy had a worse disease severity at the time of hospital admission for COVID-19 with respect to non-statin users, but nevertheless, statin therapy was not associated with an increased risk of in-hospital death. The proportion of our patients receiving statins (21%) was similar to that reported in other studies. In the statin group, 46% of patients took statins for secondary prevention, whereas 54% took statins for dyslipidemia and primary prevention. The overall mortality rate reported in our cohort is higher than reported in similar series from China , , , but is consistent with other cohorts from Italy and USA.35, 36, 37 Our findings in the overall population confirmed that patients with CVD, and therefore receiving statins, have a higher mortality rate (29%), similar to what reported in other cohorts (Inciardi et al., mortality in cardiac patients: 35.8%). Indeed, statin use underlies the presence of CV risk factors as dyslipidemia or CAD, taking into account that patients with CVD are supposed to exhibit worse outcomes. , This finding can explain why patients with COVID-19 taking domiciliary statin therapy showed an increased in-hospital mortality. This negative relation is further confirmed by the reduction in this mortality rate after balancing pre-existing CV risk factors with PS matching.

The higher COVID-19 severity in the statin group, assessed with NEWS, is not matched with a higher mortality rate in these patients. In our series, COVID-19 severity was evaluated with NEWS to avoid confounding factors related with in-hospital treatment and ICU admission, also because, due to the Italian critical care increasing demand during the COVID-19 outbreak, , we could not rely on ICU admission. Indeed, mechanical ventilation and ICU admission were sometimes reserved to younger patients with less comorbidities that were more likely to recover from severe COVID-19. Indeed, while SOFA score showed its ability to predict the in-hospital mortality in sepsis patients already admitted in ICU, NEWS showed a greater ability to predict the risk of ICU admission among patients evaluated in the ED. For these reasons, in contrast with other similar studies, , we preferred NEWS over SOFA score or other scores useful to track patients’ status during the stay in ICU.

Several studies have evaluated the role of statins as an add-on treatment during infections. In a metanalysis, Tleyeh et al. examined nine cohorts addressing the role of statins in treating bacteremia, pneumonia, and sepsis, and they showed that statin use could be associated with a beneficial effect in treating and preventing various infections, with an adjusted effect estimate of 0.55 (95% confidence interval, 0.36–0.83; I = 76.5%) in favor of statins. Conversely, Yende et al., among 1895 inpatients with community-acquired pneumonia did not found evidence of a protective effect of statin use on meaningful clinical outcomes. Similarly, in a population-based case-control study on 3360 patients, Dublin et al. showed that statin use was not associated with decreased risk of pneumonia among immunocompetent community-dwelling older people. It has been postulated that statins may have beneficial effects in influencing the clinical course of COVID-19 by mitigating the impact of viral infection through their immunomodulatory and anti-inflammatory properties. In an animal model, statins have shown to stabilize MYD88 levels and attenuate myocardial remodeling after a proinflammatory trigger such as hypoxia that is a crucial feature of SARS-CoV-2 infection. This supposed beneficial effect was only partially noticed in our cohort, as patients receiving domiciliary statin therapy showed a lower C-reactive protein level, although a worse PaO2 and PaO2/FiO2 ratio on admission.

Moreover, COVID-19 patients with CV comorbidities exhibit direct cardiac involvement and worse outcomes. , In this setting, COVID-19 patients may theoretically take advantage of statin therapy also for their cardioprotective actions and for the upregulation of Angiotensin-Converting Enzyme (ACE) 2 via epigenetic modifications, that SARS-CoV-2 employs for cellular entry.

Our results did not confirm these supposed favorable effects of statin therapy, even after propensity score matching, so that our different results can mainly be explained by a “healthy user effect” and with indication bias noticed in other observational studies on statin use in similar clinical settings. The higher severity of COVID-19, exhibited in patients on high-intensity statin treatment, could be partially explained with the enhanced severity of underlying CV risk factors and CVD in those patients.

Limitations

Because of the retrospective nature of our study, whether our patients received statins was extracted from our in-hospital medical records, and specific data on the in-hospital drug regimen of statins (continuation vs. discontinuation) are lacking, though generally these drugs were continued during hospitalization, at least in the non-ICU setting. Indeed, precise data on drug administration in the ICU setting are lacking. Another potential limitation is represented by the struggle to assess compliance with statin therapy up to the patient's admission to the hospital. Given the logistical limitations during the COVID-19 outbreak, some laboratory data (i.e. lipid profile) were not collected in all patients. Moreover, our in-hospital based study cannot be considered representative of the overall “statin population” affected by COVID-19. Thus, since this was not a population-based study, it is still possible that the use of statin therapy could be associated with improved outcome in mild disease where patients do not seek hospital care. Moreover, patients who came to the ED but were discharged early (<24 h from admission) were not included. Therefore, the potential beneficial effects of statin therapy in COVID-19 patients treated outside of the hospital setting and its impact on mild disease need to be further investigated.

Conclusions

Our data suggest that statin therapy does not affect in-hospital mortality in COVID-19 patients. Therefore, caution should be warranted in attributing benefits to statin therapy as an adjuvant or independent therapy and a part of the standard care for COVID-19 patients. These effects may instead reflect unmeasured baseline differences between users and non-users, that in our study were limited by using propensity score matching.