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. 2021 Apr 28;16(4):e0250815. doi: 10.1371/journal.pone.0250815

Hypertension as a sequela in patients of SARS-CoV-2 infection

Ganxiao Chen 1,, Xun Li 2,, Zuojiong Gong 2, Hao Xia 1, Yao Wang 2, Xuefen Wang 3, Yan Huang 1, Hector Barajas-Martinez 4, Dan Hu 1,*
Editor: Bhagwan Dass5
PMCID: PMC8081193  PMID: 33909683

Abstract

Background

COVID-19 is a respiratory infectious disease caused by SARS-CoV-2, and cardiovascular damage is commonly observed in affected patients. We sought to investigate the effect of SARS-CoV-2 infection on cardiac injury and hypertension during the current coronavirus pandemic.

Study design and methods

The clinical data of 366 hospitalized COVID-19-confirmed patients were analyzed. The clinical signs and laboratory findings were extracted from electronic medical records. Two independent, experienced clinicians reviewed and analyzed the data.

Results

Cardiac injury was found in 11.19% (30/268) of enrolled patients. 93.33% (28/30) of cardiac injury cases were in the severe group. The laboratory findings indicated that white blood cells, neutrophils, procalcitonin, C-reactive protein, lactate, and lactic dehydrogenase were positively associated with cardiac injury marker. Compared with healthy controls, the 190 patients without prior hypertension have higher AngⅡ level, of which 16 (8.42%) patients had a rise in blood pressure to the diagnostic criteria of hypertension during hospitalization, with a significantly increased level of the cTnI, procalcitonin, angiotensin-II (AngⅡ) than those normal blood pressure ones. Multivariate analysis indicated that elevated age, cTnI, the history of hypertension, and diabetes were independent predictors for illness severity. The predictive model, based on the four parameters and gender, has a good ability to identify the clinical severity of COVID-19 in hospitalized patients (area under the curve: 0.932, sensitivity: 98.67%, specificity: 75.68%).

Conclusion

Hypertension, sometimes accompanied by elevated cTnI, may occur in COVID-19 patients and become a sequela. Enhancing Ang II signaling, driven by SARS-CoV-2 infection, might play an important role in the renin-angiotensin system, and consequently lead to the development of hypertension in COVID-19.

Introduction

In December 2019, an acute respiratory infectious disease known as "coronavirus disease 2019 (COVID-19)" caused by a novel coronavirus occurred in Wuhan, China [1, 2]. Whole-genome sequencing and systematic analysis showed that this novel. Coronavirus is a distinct clade from beta coronavirus associated with human severe acute respiratory syndrome (SARS) and Middle East respiratory syndrome (MERS) [3], and was now officially named "SARS-CoV-2" by World Health Organization. Both SARS-CoV and SARS-CoV-2 have been identified to use the angiotensin converting enzyme II (ACE2) receptor as the portal of entry into the affected cell [4, 5]. ACE2, a membrane-bound aminopeptidase, is highly expressed in the heart and lung [6, 7]. Although the main clinical features of COVID-19 are dominated by respiratory symptoms, many patients with severe cardiovascular damage have been reported by our team and others [8, 9]. Besides, patients with underlying cardiovascular diseases might have an increased risk of death [8]. So, understanding the damage to the cardiovascular system caused by SARS-CoV-2 and the underlying mechanisms is of great importance so that these patients can be treated timely, and the mortality can be reduced. In this retrospective cohort study, the clinical data of hospitalized COVID-19-confirmed patients were analyzed to explore the consequences of SARS-CoV-2 infection on the cardiovascular system.

Materials and methods

Study setting and population

There were 366 COVID-19-confirmed patients enrolled in this study, who were hospitalized in the Department of Infectious Diseases, Renmin Hospital of Wuhan University, from February 1 to May 1, 2020. Clinical severity was defined for all enrolled COVID-19 patients according to the guidelines of the National Health Commission of China, including four types as mild, moderate, severe, and critical types [10]. We divided the patients into the non-severe group (mild and moderate types) and the severe group (severe and critical type). Mild type is defined as mild clinical symptoms and no pneumonia manifestation found in imaging. Moderate cases refer to those who present with fever and respiratory tract symptoms, etc. And have pneumonia manifestations found in imaging. Patients considered severe had one of the following three conditions: respiratory distress and respiratory rate higher than 30 times per minute; fingertip blood oxygen saturation less than 93% at rest; partial arterial oxygen pressure (PaO2) / fraction of inspiration oxygen (FiO2) less than 300mmHg. Patients in critical type met one of the following criteria: respiratory failure, requiring mechanical ventilation; shock; multiple organ failure, requiring intensive care management. This study was reviewed and approved by the Medical Ethical Committee of Renmin Hospital of Wuhan University. All participants provided written informed consent and agreed to use their medical records for research purposes.

Data collection

The clinical signs and laboratory findings were extracted from electronic medical records (Donghua Hospital Information System). Two independent, experienced clinicians reviewed and abstracted the data. The recorded information includes demographic data, potential comorbidities, symptoms, signs, laboratory test results. The serum level of hypersensitive troponin I (cTnI) exceeding >40 pg/mL was considered cardiac injury [11]. Blood pressures were obtained three fixed times in the morning using standard measurement. History of hypertension was defined as brachial blood pressure ≥ 140/90 mmHg or self-reported hypertension medication use before hospitalization. For patients without prior hypertension, elevated blood pressure was defined as blood pressure ≥ 140/90 mmHg more than 3 times during hospitalization.

The processes of patient screening

The screening process for evaluating the effect of SARS-CoV-2 on the cardiovascular system is shown in Fig 1. Serum level of cardiac troponin I (cTnI) was tested in 276 of the 366 patients during hospitalization, among which 8 patients had a history of chronic heart disease (including ischemic heart disease, arrhythmia, valvular disease, and heart failure) and were therefore excluded. Thus, 268 patients were enrolled to evaluate the effect of SARS-CoV-2 on cardiac injury. Of the 366 patients, 278 had complete blood pressure data. Among these, 88 patients had a history of hypertension before hospitalization and were excluded; therefore, 190 patients were grouped to evaluate the effect of SARS-CoV-2 on blood pressure. Among all 366 subjects, 194 subjects had data available on serum level of cTnI and complete blood pressure data. After the exclusion of the case with a history of chronic heart disease, 186 cases were included to evaluate the association between cTnI, blood pressure, and clinical severity of COVID-19.

Fig 1. The flow diagram of patient screening.

Fig 1

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Chronic heart disease includes ischemic heart disease, arrhythmia, valvular disease, and heart failure.

Statistical analysis

Student’s t-test or the Mann-Whitney test was used to compare the mean of continuous variables, Fisher’s exact test was used with limited data, the χ2 test was used to compare the proportion of categorical variables. Spearman correlation analysis was used to analyze the correlation between variables. The logistic regression model was used to determine factors associated with the clinical severity of COVID-19, and the analysis of receiver operating characteristic (ROC) curves was constructed according to standard procedures. The Youden index, defined as (sensitivity + specificity)– 1, was used to derive a reasonable cut-off value. Calibration of the risk prediction model, comparing the observed and predicted probability, was performed via a visual calibration plot in the R program. A P-value of < 0.05 was considered statistically significant. Statistical analysis was carried out using SPSS software version 21.0 and R version 3.0.

Results

The effect of SARS-CoV-2 on cardiac injury

The results showed that the median age of patients with or without cardiac injury was 74 y/o and 49 y/o with statistical significance (median [interquartile range]: 74 [73–86] vs. 49 [40–66] y/o, p < 0.001). Males were dominant in the cardiac injury group (86.67%). The cardiac injury was found in 11.19% (30/268) of patients, but 93.33% (28/30) of them were in the severe group. The proportion of cardiac injury was significantly lower in the non-severe group (1.75% vs. 18.18%, p < 0.001). Moreover, 66.67% (20/30) of cardiac injury patients in the severe group eventually died. The most frequent symptom of patients was fever, followed by cough, fatigue, dyspnea, and chest stuffiness. The incidences of cough, dyspnea, and chest stuffiness were significantly different between the patients with or without cardiac injury (93.33% vs. 68.91%, p = 0.005; 93.33% vs. 38.66%, p < 0.001; 86.67% vs. 36.97%, p < 0.001; respectively). Hypertension was the most frequent comorbidity, while the incidence of diabetes was significantly different between the two groups (33.33% vs. 14.29%, p = 0.017; Table 1). The laboratory findings indicated that the patients who suffered from cardiac injury had a higher level of white blood cells, neutrophils, monocytes, procalcitonin, C-reactive protein, lactate, and lactic dehydrogenase compared with the patients without cardiac injury (median [interquartile range]: 9.67 [5.62–13.73] vs. 5.93 [4.45–7.06] cells/L, p < 0.001; 5.52 [3.83–11.62] vs. 3.72 [2.95–5.47] cells/L, p < 0.001; 0.62 [0.42–0.76] vs. 0.44 [0.25–0.69] cells/L, p = 0.037; 630 [47.00–2750.00] vs. 60 [32.00–121.00] pg/mL, p < 0.001; 81.10 [14.20–142.80] vs. 41.40 [5.00–74.40] mg/L, p < 0.001; 2.10 [1.95–3.05] vs. 1.70 [1.15–2.00] mmol/L, p<0.001; 428 [325.00–765.00] vs. 275 [218.00–375.00] U/L, p < 0.001; respectively). Correlation analysis showed that white blood cells, neutrophils procalcitonin, C-reactive protein, lactate and lactic dehydrogenase were significantly associated with cTnI, the r values were 0.515 [95% CI, 0.394–0.632], 0.486 [95% CI, 0.358–0.591], 0.477 [95% CI, 0.352–0.581], 0.459 [95% CI, 0.338–0.566], 0.424 [95% CI, 0.273–0.559] and 0.438 [95% CI, 0.291–0.561], respectively (Table 2).

Table 1. Clinical characteristics of COVID-19 patients with or without cardiac injury.

Total Cardiac injury
(n = 268) Non-injury (n = 238) Injury
(n = 30)
Age (y/o), Median (IQR) 53 (42–69) 49 (40–66) 74 (73–86)*§
Gender (n, %)
    Male 144 (53.7) 118 (49.58) 26 (86.67)*£
    Female 124 (46.3) 120 (50.42) 4 (13.33)*£
Clinical categories (n, %)
    Non-severe 114 (42.54) 112 (47.06) 2 (6.67)*£
    Severe 154 (57.46) 126 (52.94) 28 (93.33)*£
Symptoms (n, %)
    Fever 224 (83.58) 196 (82.35) 28 (93.33)£
    Cough 192 (71.64) 164 (68.91) 28 (93.33)*£
    Dyspnea 120 (44.78) 92 (38.66) 28 (93.33)*£
    Chest stuffiness 114 (42.54) 88 (36.97) 26 (86.67)*£
    Fatigue 148 (55.22) 130 (54.62) 18 (60.00)£
    Muscle soreness 54 (20.15) 48 (20.17) 6 (20.00)£
Comorbidities (n, %)
    Hypertension 94 (35.07) 80 (33.61) 14 (46.67)£
    Diabetes 44 (16.42) 34 (14.29) 10 (33.33)*#
    Chronic lung diseases 10 (3.73) 8 (3.36) 2 (6.67)#
    Chronic kidney diseases 4 (1.49) 2 (0.84) 2 (6.67)
    Gastrointestinal diseases 2 (0.75) 2 (0.84) 0 (0)
    Malignant tumor 4(1.49) 0 (0) 4 (13.33)
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Student’s t-test, χ2 test, and Fisher’s exact tests were used to compare the age, gender, clinical category, symptoms, and comorbidities between the two groups (§ Two-Sample T-test, £ Pearson’s chi-square test, # continuous correction Chi-square test, Fisher’s exact test).

*P < 0.05 is considered statistically significant.

Table 2. The laboratory findings of COVID-19 patients with or without cardiac injury.

Laboratory findings Non-cardiac injury Cardiac injury Normal r values P-values
(median, IQR) (median, IQR) range
cTnI (pg/mL) 7.5 (6.00–16.50) 162 (68.20–757.50)* 0–40 1.000 < 0.001
White blood cells (×109 cells/L) 5.93 (4.45–7.06) 9.67 (5.62–13.73)* 3.5–9.5 0.515 < 0.001
Neutrophils (×109 cells/L) 3.72 (2.95–5.47) 5.52 (3.83–11.62)* 1.8–6.3 0.486 < 0.001
Lymphocytes (×109 cells/L) 1.01 (0.59–1.25) 0.67 (0.48–1.39)* 1.1–3.2 -0.230 0.001
Monocytes (×109 cells/L) 0.44 (0.25–0.69) 0.62 (0.42–0.76)* 0.1–0.6 0.127 0.080
Procalcitonin (pg/mL) 60 (32.00–121.00) 630 (47.00–2750.00)* 0–100 0.477 < 0.001
C-reactive protein (mg/L) 41.40 (5.00–74.40) 81.10 (14.20–142.80)* 0–10 0.459 < 0.001
Lactate (mmol/L) 1.70 (1.15–2.00) 2.10 (1.95–3.05)* 0.5–1.5 0.424 < 0.001
Lactic dehydrogenase (U/L) 275 (218.00–375.00) 428 (325.00–765.00)* 120–250 0.438 < 0.001
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The Mann-Whitney test was used to compare the differences between non-cardiac injury and cardiac injury groups

*P <0.05 is considered statistically significant. Spearman correlation analysis was used to analyze the correlation between the cTnI and other laboratory findings.

The effect of SARS-CoV-2 on blood pressure

Of the 190 qualified patients, 16 (8.42%) patients had a rise in blood pressure during hospitalization, among which 6 patients were male, and 10 patients were female. As shown in Table 3, no significant differences were found when comparing the baseline demographics, including age, gender, clinical category, symptoms, and comorbidities between patients with or without elevated blood pressure. Compared with the patients without elevated blood pressure, the level of cTnI and procalcitonin in the 16 patients rose significantly (median [interquartile range]: 22.00 [18.20–30.00] vs. 3.86 [2.49–5.15], p < 0.001; 82 [53–430] vs. 49 [28–73], p = 0.023; Table 4). Elevated systolic blood pressure was observed in most of the patients, while diastolic blood pressure was in the normal range. The median values of blood pressure and plasma cTnI levels changes of the 16 patients are shown in Fig 2A. Systolic blood pressure and cTnI levels had a similar trend with the treatment time. In addition, the blood pressure, cTnI, and white blood cells were continuously monitored in one index case (Fig 2B). With effective treatment, the patient’s condition improved with regards to symptoms and as evident on chest CT. Meanwhile, the systolic blood pressure and white blood cells reverted to the normal range, and the concentrations of cTnI were also gradually decreased. Among the 190 patients without prior hypertension, the serum levels of components in the renin-angiotensin system, including adrenocorticotrophic hormone, renin, angiotensin Ⅱ (Ang Ⅱ), and aldosterone, were detected in 28 patients. Comparison with healthy controls showed that AngⅡ were significantly elevated in both the normal and elevated blood pressure groups (median [interquartile range]: 137.12 [123.63–161.67] vs. 87.90 [48.23–107.39] pg/mL, p < 0.001; 169.25 [142.17–186.98] vs. 87.90 [48.23–107.39] pg/mL, p < 0.001; respectively; Table 5). When comparing the RAS between the normal and elevated blood pressure groups, Ang Ⅱ levels were significantly higher in the latter group (median [interquartile range]: 169.25 [142.17–186.98] vs. 137.12 [123.63–161.67] pg/mL, p = 0.020; Table 6).

Table 3. Clinical characteristics of COVID-19 patients without prior hypertension.

Total Blood pressure
(n = 190) Normal Elevated
(n = 16)
(n = 174)
Age (y/o), Median (IQR) 54 (39–63) 53 (39–63) 60 (42–70)§
Gender (n, %)
    Male 78 (41.05) 72 (41.38) 6 (37.50)£
    Female 112 (58.95) 102 (58.62) 10 (62.50)£
Clinical categories (n, %)
    Non-severe 116 (61.05) 108 (62.07) 8 (50.00)£
    Severe 74 (38.95) 66 (37.93) 8 (50.00)£
Symptoms (n, %)
    Fever 156 (82.11) 142 (81.61) 14 (87.50)#
    Cough  132 (69.47) 120 (68.97) 12 (75.00)#
    Dyspnea 70 (36.84) 64 (36.78) 6 (37.50)£
    Chest stuffiness  68 (35.79) 62 (35.63) 6 (37.50)£
    Fatigue 96 (50.53) 88 (50.57) 8 (50.00)£
    Muscle soreness 36 (18.95) 34 (19.54) 2 (12.50)#
Comorbidities (n, %)
    Diabetes  28 (14.74) 26 (14.94) 2 (12.50)#
    Chronic lung diseases  6 (3.16) 6 (3.45) 0 (0)
    Gastrointestinal diseases  4 (2.11) 4 (2.30) 0 (0)
    Thyroid disease  2 (1.05) 2 (1.15) 0 (0)
    Prostate disease  2 (1.05) 2 (1.15) 0 (0)
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Student’s t-test, χ2 test, and Fisher’s exact tests were used to compare the age, gender, clinical category, symptoms, and comorbidities between the two groups (§ Two-Sample T-test, £ Pearson’s chi-square test, # continuous correction Chi-square test). No significant differences were found.

Table 4. The laboratory findings of patients with or without elevated blood pressure.

Laboratory findings Normal blood pressure Elevated blood pressure Normal range
(median, IQR) (median, IQR)
cTnI (pg/mL) 3.86 (2.49–5.15) 22.00 (18.20–30.00)* 0–40.00
White blood cells (×109cells/L) 5.24 (3.87–7.00) 4.86 (3.96–6.60) 3.50–9.50
Neutrophils (×109cells/L) 3.14 (2.48–4.96) 3.64 (3.06–4.94) 1.80–6.30
Lymphocytes (×109cells/L) 1.13 (0.76–1.56) 0.93 (0.57–1.23)* 1.10–3.20
Monocytes (×109cells/L) 0.44 (0.33–0.56) 0.55 (0.25–0.61) 0.10–0.60
Hemoglobin (g/L) 128 (118–136) 118(107–137) 115–150
Procalcitonin (pg/mL) 49 (28–73) 82 (53–430)* 0–100
C-reactive protein (mg/L) 20.00 (2.40–44.50) 7.80 (3.51–33.20) 0–10.00
Lactic dehydrogenase (U/L) 259 (206–313) 259 (208–289) 120–250
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The Mann-Whitney test was used to compare the differences between non-hypertension and hypertension groups

*P <0.05 is considered statistically significant.

Fig 2.

Fig 2

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A. The systolic blood pressure and cTnI change of patients with elevated blood pressure. B. The systolic blood pressure, cTnI, white blood cells, and chest computed tomography changes of one patient with elevated blood pressure. Late follow-up: The 4th week after discharge from the hospital.

Table 5. The renin-angiotensin system in subjects with and without COVID-19.

Laboratory findings Healthy control Normal blood pressure Elevated blood pressure
(median, IQR) (median, IQR) (median, IQR)
Adrenocorticotrophic hormone (pg/mL) 31.92 (21.6–39.67) 27.55 (21.12–39.56)§ 33.03 (19.42–40.89)§
Renin (pg/mL) 5.31 (3.21–8.75) 6.35 (3.34–7.83) 5.86 (4.41–6.76)
Angiotensin Ⅱ (pg/mL) 87.90 (48.23–107.39) 137.12. (123.63–161.67)* 169.25 (142.17–186.98)*
Aldosterone (pg/mL) 150.05 (129.32–164.32) 159.62 (119.16–169.30) 141.54 (118.63–154.83)
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The normal and elevated blood pressure groups were compared with the healthy control group, respectively, by Student’s t test or the Mann-Whitney test (§ Two-Sample T-test, Mann Whitney U test/Wilcoxon Sum Rank test).

*P <0.05 is considered statistically significant.

Table 6. The renin-angiotensin system in subjects with and without elevated blood pressure.

Laboratory findings Total Normal blood pressure Elevated blood pressure
(median, IQR) (median, IQR) (median, IQR)
Adrenocorticotrophic hormone (pg/mL) 30.56 (20.99–40.54) 27.55 (21.12–39.56) 33.03 (19.42–40.89)
Renin (pg/mL) 6.01 (4.15–7.46) 6.35 (3.34–7.83) 5.86 (4.41–6.76)
Angiotensin α (pg/mL) 153.67 (129.17–175.98) 137.12. (123.63–161.67) 169.25 (142.17–186.98)*
Aldosterone (pg/mL) 142.11 (119.16–163.28) 159.62 (119.16–169.30) 141.54 (118.63–154.83)
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Student’s t test was used to compare the differences between normal and elevated blood pressure groups

*P <0.05 is considered statistically significant.

The association between cardiac injury, blood pressure, and clinical severity of COVID-19

Results of demographic and laboratory findings between the severe and non-severe group, based on guidelines of the National Health Commission of China, are shown in Table 7. Patients in the severe group were significantly older, with a greater proportion of males (median [interquartile range]: 66 [57–76] vs. 42 [33–51] y/o, p < 0.001; 60.00% vs. 40.54%, p = 0.009; respectively). In addition, the cTnI, white blood cells, neutrophils, procalcitonin, C-reactive protein, and lactic dehydrogenase of the severe group were significantly higher than those of the non-severe group (median [interquartile range]: 7.00 [5.78–27.00] vs. 5.68 [4.62–6.45] pg/mL, p < 0.001; 5.98 [4.60–10.00] vs. 5.07 [3.65–6.00] ×109cells/mL, p = 0.004; 3.85 [3.02–8.27] vs. 2.67 [2.15–3.92] ×109 cells/mL, p < 0.001; 67.50 [32.00–288.00] vs. 36.00 [23.00–57.00] pg/mL, p = 0.005; 48.55 [7.40–81.50] vs. 6.20 [0.50–28.00] pg/mL, p <0.001; 316.00 [235.00–454.00] vs. 233.50 [187.50–292.00], p < 0.001; respectively). In contrast, patients in the severe group had a significantly lower level of lymphocytes median [interquartile range]: 0.78 [0.48–1.29] vs. 1.27 [0.96–1.73], ×109 cells/mL, p < 0.001). Further univariate analysis revealed that the age, sex, cTnI, white blood cells, neutrophils, lymphocytes, C-reactive protein, lactic dehydrogenase, and history of hypertension and diabetes were significantly associated with the clinical severity of COVID-19. In the multivariate analysis, the age, cTnI and history of hypertension and diabetes remained significant independent predictors (OR = 1.11, 95% CI: 1.07–1.16, p < 0.001; OR = 1.08, 95% CI: 1.01–1.15, p = 0.018; OR = 7.19, 95% CI: 2.55–20.31, p < 0.001; OR = 4.28, 95% CI: 1.41–12.97, p = 0.010; Table 8). The receiver operating characteristic curve of the four independent predictors and gender for clinical severity of COVID-19 is shown in Fig 3A (AUC: 0.932, sensitivity: 98.67%, specificity: 75.68%). The calibration indicated that the model was well-calibrated (Fig 3B).

Table 7. Clinical characteristics of severe and non-severe COVID-19 patients.

Clinical Severity Normal range
Non-severe Severe
(n = 111, 59.68%) (n = 75, 40.32%)
Age (y/o), Median (IQR) 42 (33–51) 66 (57–76)*§ -
Gender (n, %)
    Male 45 (40.54) 45 (60.00)*£ -
    Female 66 (59.46) 30 (40.00)*£ -
Clinical categories (n, %)
    Elevated blood pressure 6 (5.41) 10 (13.33)£ -
    Hypertension 15 (13.51) 20 (26.67)*£ -
    Diabetes 7 (6.31) 21 (28.00)*£ -
    Chronic lung diseases 7 (6.31) 10 (13.33)£ -
    Chronic kidney diseases 2 (1.8) 2 (2.67)# -
    Gastrointestinal diseases 2 (1.8) 1 (1.33)# -
    Malignant tumor 2 (1.8) 0 (0) -
Laboratory findings
    cTnI (pg/mL) 5.68 (4.62–6.45) 7.00 (5.78–27.00)* 0–40.00
    White blood cells (×109cells/L) 5.07 (3.65–6.00) 5.98 (4.60–10.00)* 3.50–9.50
    Neutrophils (×109cells/L) 2.67 (2.15–3.92) 3.85 (3.02–8.27)* 1.80–6.30
    Lymphocytes (×109cells/L) 1.27 (0.96–1.73) 0.78 (0.48–1.29)* 1.10–3.20
    Monocytes (×109cells/L) 0.42 (0.34–0.54) 0.44 (0.29–0.69) 0.10–0.60
    Procalcitonin (pg/mL) 36.00 (23.00–57.00) 67.50 (32.00–288.00)* 0–100.00
    C-reactive protein (mg/L) 6.20 (0.50–28.00) 48.55 (7.40–81.50)* 0–10.00
    Lactic dehydrogenase (U/L) 233.50 (187.50–292.00) 316.00 (235.00–454.00)* 120–250
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Student’s t test, Mann-Whitney test, χ2 test and Fisher’s exact tests were used to compare the age, gender, and clinical category between the two groups (§ Two-Sample T-test, Mann Whitney U test/Wilcoxon Sum Rank test, £ Pearson’s chi-square test, # continuous correction Chi-square test).

*P <0.05 is considered statistically significant.

Table 8. Univariate and multivariate analysis for clinical severity of COVID-19.

Odds ratio 95% CI P-value
Univariate analysis
    Age (years) 1.12 1.09–1.15 <0.001*
    Male (%) 2.20 1.21–4.00 0.010*
    cTnI (pg/mL) 1.13 1.05 - 1.22 0.002*
    White blood cells (×109cells/L) 1.39 1.13 - 1.70 0.002*
    Neutrophils (×109cells/L) 1.50 1.19–1.90 0.001*
    Lymphocytes (×109cells/L) 0.23 0.10–0.54 0.001*
    Procalcitonin (pg/mL) 1.01 1.00–1.01 0.069
    C-reactive protein (mg/L) 1.02 1.01–1.04 0.002*
    Lactic dehydrogenase (U/L) 1.01 1.00–1.01 0.001*
    Hypertension (%) 2.489 1.185–5.226 0.016*
    Diabetes (%) 5.78 2.31–14.45 <0.001*
Multivariate analysis
    Age (years) 1.11 1.07–1.16 <0.001*
    Male (%) 1.38 0.57–3.37 0.479
    CTnI (pg/mL) 1.08 1.01–1.15 0.018*
    Hypertension (%) 7.19 2.55–20.31 <0.001*
    Diabetes (%) 4.28 1.41–12.97 0.010*
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The logistic regression model was used to determine factors associated with the clinical severity of COVID-19 according to Table 7

*P <0.05 is considered statistically significant.

Fig 3.

Fig 3

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A. ROC curves of the age, cTnI, gender, and the presence of hypertension and diabetes for the identification of the severity of COVID-19. B. The calibration plot for the comparison of the predicted and actual probability. The X-axis and Y-axis represent the model-predicted and actual probability of MAE, respectively. The red line: perfect prediction. The black line: predictive performance of the model after bootstrapping (B = 1000 repetitions).

Discussion

SARS-CoV-2 has been identified as a single-stranded enveloped 39 RNA virus belonging to the beta-coronavirus genus of the coronaviridae family [3]. These coronaviruses have a three-dimensional spike protein structure protein, which can closely bind the human ACE2 receptor. Therefore, the cells with ACE2 expression may act as target cells and be susceptible to SARS-CoV-2 infection [12]. ACE2 is a membrane-bound aminopeptidase with a vital role in the cardiovascular system [13, 14]. It is, therefore, reasonable to speculate that SARS-CoV-2 will act on the heart and blood vessels, with resultant changes in the cardiovascular system.

Serum cardiac troponin assays have been proposed as the recommended marker of cardiac injury in COVID-19 patients [15]. Huang and colleagues find that cTnI is increased substantially in 12.20% (5/41) Wuhan COVID-19 patients, in whom the diagnosis of the virus-related cardiac injury is made [8]. Another previous research also reported that patients with cardiac injury had higher levels of leukocyte counts, C-reactive protein, procalcitonin [16]. In this retrospective study, older patients with diabetes are more likely to suffer from cardiac injury. Our further analysis shows that the level of white blood cells, neutrophils, procalcitonin, C-reactive protein, lactate, and lactic dehydrogenase were positively associated with cardiac injury. Besides, the cardiac injury occurred mostly in severe patients. Consequently, we hypothesize that the severe type of COVID-19 characterized by acute inflammation response might be more prone to cardiac injury, especially in patients with preexisting cardiovascular disease. Chronic myocardial injury, acute nonischemic injury, and acute myocardial infarction have all been proposed as causes of cTnI elevation in COVID-19 patients [17]. One case study suggested that direct myopericardial involvement may be a complication of COVID-19 infection [18].

Understanding of the pathogenesis and complications of COVID-19 is still limited. Due to the lack of viral load quantification results in the literature, it is unclear whether the cardiac injury is directly related to viral load. The recent literature review has shown that although cTnI concentration is only marginally increased in all patients with COVID-19, (values above the 99th percentile upper reference limit in only 8–12% of positive patients), they are significantly increased in patients with severe disease [19]. Our study further suggests that cardiac injury is an independent risk factor for severe COVID-19 and in combination with age and other statistically significant comorbidities can be used to construct a logistic regression model of COVID-19 severity in hospitalized patients.

Sixteen patients without prior hypertension had a rise in blood pressure during hospitalization, and higher systolic blood pressure was observed in most of the patients. Except for lymphocytes and procalcitonin, no significant differences are found in patients with and without elevated blood pressure. This suggests that abnormal blood pressure may be caused independently of the inflammatory response. The RAS plays a critical role in the cardiovascular system, which includes a classical RAS axis (ACE-Ang II-AT1R pathway) and a non-classical RAS axis (ACE2-Ang 1-7-MasR-based pathway), counter-balancing role of the two axes regulates cardiovascular physiology and disease [20, 21]. ACE2 cleaves Ang II into the Ang 1–7, thus limiting substrate availability in the adverse ACE/Ang II/AT1 receptor axis [22, 23]. Keidar and colleagues found that ACE2 antihypertensive properties may be due to the degradation of angiotensin II [24]. In this study, the laboratory results of RAS show that Ang II level is elevated in the majority of patients without prior hypertension. Compared with normal blood pressure and healthy control groups, Ang Ⅱ levels were significantly higher in elevated blood pressure groups. A possible mechanism may be the binding of SARS-CoV-2 to ACE2 thereby inhibiting degradation of angiotensin II leading to elevated blood pressure. Another hypothesis is that over activation of the RAS system promotes inflammatory response and cytokine storm, which stimulates the NADH/NADPH oxidase system and triggers cell contraction and vasoconstriction, which then leads to COVID-19 related lung injury. Though the underlying mechanism remains to be elucidated, it is becoming evident that RAS plays a major role in hypertension and COVID-19 infection, as observed in our study. It has been noticed that recombinant human ACE2 is considered as a treatment for patients with COVID-19 (ClinicalTrials.gov ID: NCT04287686). This finding probably shades important implications for future treatment strategies. A recent long-term observational follow-up study of patients with COVID-19 reported nearly one-eighth of patients without previous renal dysfunction developed a reduction in glomerular filtration rate at follow-up. In addition, COVID-19 survivors suffer from relatively higher levels of depression, anxiety, and somatic symptoms (including fatigue or muscle weakness). Severe cases are more susceptible to the development of reduced pulmonary diffusion capacities [25]. Multiple above factors are capable of inducing hypertension in nonhypertensive patients. In addition, the median ages of these patients were 66.5 y/o. It seems that SARS-CoV-2 infection is just a trigger, and age plays a more important role.

On the other hand, sixteen patients with elevated blood pressure show significantly higher levels of cTnI than those normal blood pressure patients. Several studies have demonstrated Ang II direct or indirect effects on cardiomyocytes, some of which were related to pro-inflammatory and pro-hypertrophic responses [26]. Especially when the balance between the ACE and ACE2 was disrupted in COVID-19 patients, the increase in Ang II actions could lead to myocardial inflammation, oxidative stress, and myocyte apoptosis. This hypothesis explains why elevated blood pressure could occur in parallel with mild cardiac injury of COVID-19 patients.

Study strength and limitations

In the present study, we propose that hypertension is probably a sequela of SARS-CoV-2 infection. Although a number of studies of COVID-19 have been reported, there are few reports about the sequela of the disease likely due to lack of long-term clinical follow-up, which also applies to our present research. Next, it is difficult to analyze whether the blood pressure of COVID-19 patients with preexisting hypertension is further increased. Consequently, many patients could not be incorporated in the analysis because of the history of hypertension, which results in a relatively low sample size. Besides, the present study uncovered rising Ang II as one possible mechanism that might result in hypertension in COVID-19. However, due to a lack of detection about ACE2 levels and other components, therefore, we cannot gain a comprehensive view of virus-induced imbalance of the RAS pathway.

Conclusion

In summary, SARS-CoV-2 may impair cardiomyocytes by systemic acute inflammation response, and the cTnI is correlated with the severity of the infection. Accompanied by mild elevation in cTnI, spontaneous hypertension may occur in patients during hospitalization, and could become a sequela of SARS-CoV-2 infection, which may be associated with markedly elevated Ang II levels.

Acknowledgments

We gratefully acknowledge contributions from all enrolled patients and related medical staff.

Abbreviations

ACE2

angiotensin converting enzyme II

Ang II

Angiotensin II

AT1R

Angiotensin II type-1 receptor

COVID-19

coronavirus disease 2019

cTnI

cardiac troponin I

MERS

middle east respiratory syndrome

RAS

renin-angiotensin system

SARS

severe acute respiratory syndrome

Data Availability

Data cannot be shared publicly because of the contents including information that could compromise research participant privacy/consent. Data are available from the Renmin Hospital of Wuhan University Ethics Committee (contact via whdxrmyy@126.com) for researchers who meet the criteria for access to confidential data.

Funding Statement

The current work was supported by the National Natural Science Foundation Project of China (Grant No. 81670304, D.H.).

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Decision Letter 0

Bhagwan Dass

17 Mar 2021

PONE-D-21-02635

Hypertension as a sequela in patients of SARS-CoV-2 infection

PLOS ONE

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Reviewer #1: The article is written in a clear manner, however it is unclear at what points the authors use parametric statistics and when they use non-parametric statistics- in this regard they offer no justification for their respective uses. There are only a few minor grammatical errors and only one instance where there is a reference to a paper but no reference number or citation was supplied in the main test. Most importantly, the authors suggest that cardiac injury results from secondary bacterial injury, which based on the design of the trial and that no supporting evidence is provided to this effect (ie any form of analysis of culture data), this represents a jump in logic that I do not believe is justifiable. The authors appear to make this supposition based on elevated procalcitonin levels alone- there are published studies that have shown a small subset of patients with severe to critical illness will actually have elevated procalcitonin levels without secondary bacterial co-infection. The confounding effect notwithstanding, this represents a conclusion which is not substantiated by the trial presented here. Moreover, given the confounding effect of hydroxychloroquine, which was the practice at the time of the study, the authors should make note of whether or not HCQ was used in any of these patients, which may actually provide an additional, interesting variable for their analysis. In the section for processes of patient screening, an appendix would be helpful to list what "chronic heart diseases" they considered for exclusion. In the results section, the wording is at times confusing, though technically correct- further revision of this section may help in further iterations of the submission, but do not in themselves constitute grounds for rejection. The very last sentence of the discussion section is too strong of an assertion, perhaps a softer wording of the assertion would be better received. Lastly, the study limitations section does a poor job of discussing the study limitations- heavy revision is advised here- in fact, this section does not discuss any limitations at all and appears to be only a continuation of either the discussion section or the introduction of the conclusions section.

Reviewer #2: The study was well planned, conducted, analyzed, and presented. The title is captivating and engaging. The introduction is appropriate and discussion is well written and thorough. The subject matter and idea is novel and well thought-out. The clinical point is very interesting and relevant and the paper should be published pending revisions.

The English and syntax of the paper needs a lot of work. The conclusion that bacterial superinfection may be a cause of the cardiac damage needs further evidence from the literature. Please, see attached file.

Reviewer #3: This manuscript seeks to address hypertension as a sequalae of COVID-19 disease. Though the clinical association is important, especially as we see more long haul COVID (PASC) in the world population, the manuscript attempts to relate multiple causation for hypertension, including secondary bacterial infection and mycocardial injury during concurrent SARS-CoV-2 infection. The role of ACE2 and the RAS symptom and their relationship to SARS-CoV-2 infectivity and also their role in hypertension would be a more relevant topic to discuss in this manuscript.

Major issues for this manuscript include disorganized data that appears to suggest causation of multiple factors, independently, related to COVID-19 disease severity. It is suggested that the manuscript focus on direct hypertension risk factors associated with the SARS-CoV-2 infection and not broad measurements of cTnl and procalcitonin levels we may be unrelated to the development of chronic hypertension.

Minor issues of this manuscript include various typographical and grammatical errors. There is also need to expand definitions of mild and moderate severity of disease as well. Please include the National Health Commission of China clinical severity scale and criteria to clarify this in the results section.

**********

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Attachment

Submitted filename: PONE-D-21-02635_reviewer.pdf

Click here for additional data file. (1.5MB, pdf)
PLoS One. 2021 Apr 28;16(4):e0250815. doi: 10.1371/journal.pone.0250815.r002

Author response to Decision Letter 0

10 Apr 2021

Response to Reviewers

Hypertension as a sequela in patients of SARS-CoV-2 infection (PONE-D-21-02635)

We are grateful to reviewers and editors for the comments and have made every effort to modify the manuscript accordingly or to address the concerns. Table 1-7 are replaced with the modified ones. Please see our specific responses below.

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Answer: Thanks for this suggestion sincerely. The manuscript has been revised according to the PLOS ONE's style requirements.

2. We suggest you thoroughly copyedit your manuscript for language usage, spelling, and grammar. If you do not know anyone who can help you do this, you may wish to consider employing a professional scientific editing service. Whilst you may use any professional scientific editing service of your choice, PLOS has partnered with both American Journal Experts (AJE) and Editage to provide discounted services to PLOS authors. Both organizations have experience helping authors meet PLOS guidelines and can provide language editing, translation, manuscript formatting, and figure formatting to ensure your manuscript meets our submission guidelines. To take advantage of our partnership with AJE, visit the AJE website (http://learn.aje.com/plos/) for a 15% discount off AJE services. To take advantage of our partnership with Editage, visit the Editage website (www.editage.com) and enter referral code PLOSEDIT for a 15% discount off Editage services. If the PLOS editorial team finds any language issues in text that either AJE or Editage has edited, the service provider will re-edit the text for free.

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• A clean copy of the edited manuscript (uploaded as the new *manuscript* file)

Answer: We are grateful for the visionary suggestion. We have toned down this manuscript.

3. Please provide additional details regarding participant consent. In the ethics statement in the Methods and online submission information, please ensure that you have specified (1) whether consent was informed and (2) what type you obtained (for instance, written or verbal, and if verbal, how it was documented and witnessed). If your study included minors, state whether you obtained consent from parents or guardians. If the need for consent was waived by the ethics committee, please include this information.

If you are reporting a retrospective study of medical records or archived samples, please ensure that you have discussed whether all data were fully anonymized before you accessed them and/or whether the IRB or ethics committee waived the requirement for informed consent. If patients provided informed written consent to have data from their medical records used in research, please include this information.

Answer: We greatly appreciate your constructive comment. We have included the ethics statement information in Line 115 - 116 Page 4 as “All participants provided written informed consent and agreed to use their medical record for research purpose.”

manuscript:

"The current work was supported by the National Natural Science Foundation

Project of China (Grant No. 81670304 – D.H.)."

We note that you have provided funding information that is not currently declared in your Funding Statement. However, funding information should not appear in the Acknowledgments section or other areas of your manuscript. We will only publish funding information present in the Funding Statement section of the online submission form.

Please remove any funding-related text from the manuscript and let us know how you would like to update your Funding Statement. Currently, your Funding Statement reads as follows:

"No - The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript."

Please include your amended statements within your cover letter; we will change the online submission form on your behalf.

Answer: Thank you for your correction. We have removed any funding-related text from the manuscript and updated our Funding Statement section of the online submission form.

5. We note that you have indicated that data from this study are available upon request. PLOS only allows data to be available upon request if there are legal or ethical restrictions on sharing data publicly. For information on unacceptable data access restrictions, please see http://journals.plos.org/plosone/s/data-availability#loc-unacceptable-data-access-restrictions.

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We will update your Data Availability statement on your behalf to reflect the information you provide.

Answer: We re-make the Data Availability statement as suggested in Line 458 - 462 Page 15 as “Data cannot be shared publicly because of the contents including information that could compromise research participant privacy/consent. Data are available from the Renmin Hospital of Wuhan University Ethics Committee (contact via whdxrmyy@126.com) for researchers who meet the criteria for access to confidential data.”

Reviewer #1:

1.The article is written in a clear manner, however it is unclear at what points the authors use parametric statistics and when they use non-parametric statistics- in this regard they offer no justification for their respective uses.

Answer: The reviewer’s comment is well taken. We have added different symbols represent different test methods in Tables 1 - 7.

2.There are only a few minor grammatical errors and only one instance where there is a reference to a paper but no reference number or citation was supplied in the main test.

Answer: We appreciate the reviewer’s valuable comments. The manuscript has been checked thoroughly again and some grammar errors were corrected. Besides, the reference number has been rearranged in some parts of the manuscript.

3.Most importantly, the authors suggest that cardiac injury results from secondary bacterial injury, which based on the design of the trial and that no supporting evidence is provided to this effect (ie any form of analysis of culture data), this represents a jump in logic that I do not believe is justifiable. The authors appear to make this supposition based on elevated procalcitonin levels alone- there are published studies that have shown a small subset of patients with severe to critical illness will actually have elevated procalcitonin levels without secondary bacterial co-infection. The confounding effect notwithstanding, this represents a conclusion which is not substantiated by the trial presented here.

Answer: Thank you a lot for your important comment again. We agree with the reviewer and have revised the manuscript accordingly as follows.

First, we agree that it is not rigorous enough to draw the conclusion that cardiac injury results from secondary bacterial injury and decide to remove it. we have adjusted the discussion about cardiac injury in Line 245 - 252 Page 11 as “In this study, older patients with diabetes are more likely to suffer from cardiac injury. Our further analysis shows that the level of white blood cells, neutrophils, procalcitonin, C-reactive protein, lactate, and lactic dehydrogenase were positively associated with cardiac injury. Besides, cardiac injury occurred mostly in severe patients. Consequently, we hypothesize that severe type of COVID-19 characterized by acute inflammation response might be more prone to cardiac injury, especially in patients with preexisting cardiovascular disease. ”

Besides, according to your suggestion, we have rearranged our data of renin-angiotensin system (RAS). These results, integrated into Table. 5A&B, suggesting that Ang Ⅱ levels were significantly higher in the elevated blood pressure group. Thus, we discuss in Line 300-308 Page13 as “On the other hand, sixteen patients with elevated blood pressure show significantly higher levels of cTnI than those normal blood pressure patients. Several studies have demonstrated Ang II direct or indirect effects on cardiomyocytes, some of which were related to pro-inflammatory and pro-hypertrophic responses. Especially when the balance between the ACE and ACE2 was disrupted in COVID-19 patients, the increase in Ang II actions could lead to myocardial inflammation, oxidative stress, and myocyte apoptosis. This hypothesis explains why elevated blood pressure could occur in parallel with mild cardiac injury of COVID-19 patients. ”

Finally, we resummarize our conclusions in the Abstract part (Line 57 - 60 Page 2) as “Hypertension, sometimes accompanied by elevated cTnI, may occur in COVID-19 patients and become a sequela. Enhancing Ang II signaling, driven by SARS-CoV-2 infection, might play an important role in renin-angiotensin system and consequently lead to the development of hypertension in COVID-19”

4.Moreover, given the confounding effect of hydroxychloroquine, which was the practice at the time of the study, the authors should make note of whether or not HCQ was used in any of these patients, which may actually provide an additional, interesting variable for their analysis.

Thanks for this suggestion sincerely. We have checked carefully and rearranged each patients’ clinical and self-reported data in this study, and all subjects had no medical history of hydroxychloroquine.

5.In the section for processes of patient screening, an appendix would be helpful to list what "chronic heart diseases" they considered for exclusion. In the results section, the wording is at times confusing, though technically correct- further revision of this section may help in further iterations of the submission, but do not in themselves constitute grounds for rejection.

Answer: We are grateful for the visionary suggestion. We have redefined "chronic heart diseases" in the Method part (Line 119 - 120 Page 5) and Figure legends part (Line 452-453 Page 21), as “Chronic heart disease includes ischemic heart disease, arrhythmia, valvular disease, and heart failure.”

6.The very last sentence of the discussion section is too strong of an assertion, perhaps a softer wording of the assertion would be better received. Lastly, the study limitations section does a poor job of discussing the study limitations- heavy revision is advised here- in fact, this section does not discuss any limitations at all and appears to be only a continuation of either the discussion section or the introduction of the conclusions section.

Answer: Thanks for this suggestion sincerely. We have adjusted the last sentence of the discussion section in Line 300 - 308 Page13, as “On the other hand, sixteen patients with elevated blood pressure show significantly higher levels of cTnI than those normal blood pressure patients. Several studies have demonstrated Ang II direct or indirect effects on cardiomyocytes, some of which were related to pro-inflammatory and pro-hypertrophic responses. Especially when the balance between the ACE and ACE2 was disrupted in COVID-19 patients, the increase in Ang II actions could lead to myocardial inflammation, oxidative stress, and myocyte apoptosis. This hypothesis explains why elevated blood pressure could occur in parallel with mild cardiac injury of COVID-19 patients.

We have re-written the part of study limitations in Line 309 - 320 Page 14 as “In the present study, we propose that hypertension is probably a sequela of SARS-CoV-2 infection. Although several studies of COVID-19 have been reported, there are few reports about the sequela of the disease likely due to lack of long-term clinical follow-up, which also applies to our present research. Next, it is difficult to analyze whether the blood pressure of COVID-19 patients with preexisting hypertension is further increased. Consequently, many patients could not be incorporated in the analysis because of history of hypertension, which results in a relatively low sample size. Besides, the present study uncovered rising Ang II as one possible mechanism that might result in hypertension in COVID-19. However, due to a lack of detection about ACE2 levels and other components, therefore, we cannot gain a comprehensive view of the virus-induced imbalance of RAS pathway. ”

Reviewer #2: The study was well planned, conducted, analyzed, and presented. The title is captivating and engaging. The introduction is appropriate and discussion is well written and thorough. The subject matter and idea is novel and well thought-out. The clinical point is very interesting and relevant and the paper should be published pending revisions.

The English and syntax of the paper needs a lot of work. The conclusion that bacterial superinfection may be a cause of the cardiac damage needs further evidence from the literature. Please, see attached file.

Answer: We are grateful for the visionary suggestion. We agree with the reviewer and have revised the manuscript accordingly as follows.

First, we agree that it is not rigorous enough to draw the conclusion that cardiac injury results from secondary bacterial injury and decide to remove it. we have adjusted the discussion about cardiac injury in Line 245 - 252 Page11 as “In this study, older patients with diabetes are more likely to suffer from cardiac injury. Our further analysis shows that the level of white blood cells, neutrophils, procalcitonin, C-reactive protein, lactate, and lactic dehydrogenase were positively associated with cardiac injury. Besides, cardiac injury occurred mostly in severe patients. Consequently, we hypothesize that severe type of COVID-19 characterized by acute inflammation response might be more prone to cardiac injury, especially in patients with preexisting cardiovascular disease. ”

Besides, according to your suggestion, we have rearranged our data of renin-angiotensin system (RAS). These results, integrated into Table. 5A&B, suggesting that Ang Ⅱ levels were significantly higher in the elevated blood pressure group. Thus, we discuss in Line 300 - 308 Page13 as “On the other hand, sixteen patients with elevated blood pressure show significantly higher levels of cTnI than those normal blood pressure patients. Several studies have demonstrated Ang II direct or indirect effects on cardiomyocytes, some of which were related to pro-inflammatory and pro-hypertrophic responses. Especially when the balance between the ACE and ACE2 was disrupted in COVID-19 patients, the increase in Ang II actions could lead to myocardial inflammation, oxidative stress, and myocyte apoptosis. This hypothesis explains why elevated blood pressure could occur in parallel with mild cardiac injury of COVID-19 patients. ”

Finally, we resummarize our conclusions in the Abstract part (Line 57 - 60 Page 2) as “Hypertension, sometimes accompanied by elevated cTnI, may occur in COVID-19 patients and become a sequela. Enhancing Ang II signaling, driven by SARS-CoV-2 infection, might play an important role in renin-angiotensin system and consequently lead to the development of hypertension in COVID-19”

Reviewer #3: This manuscript seeks to address hypertension as a sequalae of COVID-19 disease. Though the clinical association is important, especially as we see more long haul COVID (PASC) in the world population, the manuscript attempts to relate multiple causation for hypertension, including secondary bacterial infection and mycocardial injury during concurrent SARS-CoV-2 infection. The role of ACE2 and the RAS symptom and their relationship to SARS-CoV-2 infectivity and also their role in hypertension would be a more relevant topic to discuss in this manuscript.

Major issues for this manuscript include disorganized data that appears to suggest causation of multiple factors, independently, related to COVID-19 disease severity. It is suggested that the manuscript focus on direct hypertension risk factors associated with the SARS-CoV-2 infection and not broad measurements of cTnl and procalcitonin levels may be unrelated to the development of chronic hypertension.

Answer: We greatly appreciate your constructive comment. According to your suggestion, we have rearranged our data of renin-angiotensin system (RAS). These results, integrated into Table. 5A&B, suggesting that the increase in Ang II actions may direct or indirect effects on cardiomyocytes.

Thus, we discuss in Line 300 - 308 Page13 as “On the other hand, sixteen patients with elevated blood pressure show significantly higher levels of cTnI than those normal blood pressure patients. Several studies have demonstrated Ang II direct or indirect effects on cardiomyocytes, some of which were related to pro-inflammatory and pro-hypertrophic responses. Especially when the balance between the ACE and ACE2 was disrupted in COVID-19 patients, the increase in Ang II actions could lead to myocardial inflammation, oxidative stress, and myocyte apoptosis. This hypothesis explains why elevated blood pressure could occur in parallel with mild cardiac injury of COVID-19 patients. ”

Besides, we resummarize our conclusions in the Abstract part (Line 57 - 60 Page 2) as “Hypertension, sometimes accompanied by elevated cTnI, may occur in COVID-19 patients and become a sequela. Enhancing Ang II signaling, driven by SARS-CoV-2 infection, might play an important role in renin-angiotensin system and consequently lead to the development of hypertension in COVID-19”

Minor issues of this manuscript include various typographical and grammatical errors. There is also need to expand definitions of mild and moderate severity of disease as well. Please include the National Health Commission of China clinical severity scale and criteria to clarify this in the results section.

Answer: Thank you for your correction. According to your suggestion, we have defined mild and moderate severity of disease in the Method part (Line 90 - 93 Page 4) as “Mild type is defined as mild clinical symptoms and no pneumonia manifestation found in imaging. Moderate cases refer to those who present with fever and respiratory tract symptoms, etc. And have pneumonia manifestations found in imaging.”

Besides, in the Result part (Line 207 Page 9), the division criteria have been supplemented, as “Results of demographic and laboratory findings between the severe and non-severe group, based on guidelines of the National Health Commission of China, are shown in Table 6.”

Attachment

Submitted filename: Response to reviewers - ver1.docx

Click here for additional data file. (25.2KB, docx)

Decision Letter 1

Bhagwan Dass

15 Apr 2021

Hypertension as a sequela in patients of SARS-CoV-2 infection

PONE-D-21-02635R1

Dear Dr. Hu,

We’re pleased to inform you that your manuscript has been judged scientifically suitable for publication and will be formally accepted for publication once it meets all outstanding technical requirements.

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Bhagwan Dass, MD

Academic Editor

PLOS ONE

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Reviewers' comments:

Acceptance letter

Bhagwan Dass

19 Apr 2021

PONE-D-21-02635R1

Hypertension as a sequela in patients of SARS-CoV-2 infection

Dear Dr. Hu:

I'm pleased to inform you that your manuscript has been deemed suitable for publication in PLOS ONE. Congratulations! Your manuscript is now with our production department.

If your institution or institutions have a press office, please let them know about your upcoming paper now to help maximize its impact. If they'll be preparing press materials, please inform our press team within the next 48 hours. Your manuscript will remain under strict press embargo until 2 pm Eastern Time on the date of publication. For more information please contact onepress@plos.org.

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on behalf of

Dr. Bhagwan Dass

Academic Editor

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Associated Data

    This section collects any data citations, data availability statements, or supplementary materials included in this article.

    Supplementary Materials

    Attachment

    Submitted filename: PONE-D-21-02635_reviewer.pdf

    Click here for additional data file. (1.5MB, pdf)
    Attachment

    Submitted filename: Response to reviewers - ver1.docx

    Click here for additional data file. (25.2KB, docx)

    Data Availability Statement

    Data cannot be shared publicly because of the contents including information that could compromise research participant privacy/consent. Data are available from the Renmin Hospital of Wuhan University Ethics Committee (contact via whdxrmyy@126.com) for researchers who meet the criteria for access to confidential data.

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