Clinical features and predictors of masked uncontrolled hypertension from the Korean Ambulatory Blood Pressure Monitoring Registry

Hyun-Jin Kim; Jeong-Hun Shin; Yonggu Lee; Ju Han Kim; Sun Ho Hwang; Woo Shik Kim; Sungha Park; Sang Jae Rhee; Eun Mi Lee; Sang Hyun Ihm; Wook Bum Pyun; Jinho Shin

doi:10.3904/kjim.2020.650

Kim, Shin, Lee, Kim, Hwang, Kim, Park, Rhee, Lee, Ihm, Pyun, and Shin: Clinical features and predictors of masked uncontrolled hypertension from the Korean Ambulatory Blood Pressure Monitoring Registry

Original Article

Cardiology

The Korean Journal of Internal Medicine 2021;36(5):1102-1114.

Published online: June 18, 2021

DOI: https://doi.org/10.3904/kjim.2020.650

Clinical features and predictors of masked uncontrolled hypertension from the Korean Ambulatory Blood Pressure Monitoring Registry

Hyun-Jin Kim^1,^*, Jeong-Hun Shin^1,^*, Yonggu Lee¹, Ju Han Kim², Sun Ho Hwang³, Woo Shik Kim⁴, Sungha Park⁵, Sang Jae Rhee⁶, Eun Mi Lee⁷, Sang Hyun Ihm⁸, Wook Bum Pyun⁹, Jinho Shin¹

¹Division of Cardiology, Department of Internal Medicine, Hanyang University College of Medicine, Seoul, Korea

²Chonnam National University Hospital, Gwangju, Korea

³Gwangju Veterans Hospital, Gwangju, Korea

⁴Kyung Hee University Medical Center, Seoul, Korea

⁵Severance Cardiovascular Hospital, Yonsei University College of Medicine, Seoul, Korea

⁶Wonkwang University Hospital, Iksan, Korea

⁷Wonkwang University Sanbon Hospital, Gunpo, Korea

⁸College of Medicine, The Catholic University of Korea, Seoul, Korea

⁹Ewha Womans University Seoul Hospital, Seoul, Korea

Correspondence to: Jinho Shin, M.D., Division of Cardiology, Department of Internal Medicine, Hanyang University Medical Center, 222-1 Wangsimni-ro, Seongdong-gu, Seoul 04763, Korea, Tel: +82-2-2290-8308, Fax: +82-2-2299-0278, E-mail: jhs2003@hanyang.ac.kr

^*These authors contributed equally to this work.

Received December 7, 2020 Revised February 8, 2021 Accepted March 22, 2021

This is an Open Access article distributed under the terms of the Creative Commons Attribution Non-Commercial License (http://creativecommons.org/licenses/by-nc/4.0/) which permits unrestricted noncommercial use, distribution, and reproduction in any medium, provided the original work is properly cited.

Abstract

Background/Aims

The clinical characteristics of patients with masked uncontrolled hypertension (MUCH) have been poorly defined, and few studies have investigated the clinical predictors of MUCH. We investigated the demographic, clinical, and blood pressure (BP) characteristics of patients with MUCH and proposed a prediction model for MUCH in patients with hypertension.

Methods

We analyzed 1,986 subjects who were enrolled in the Korean Ambulatory Blood Pressure Monitoring (Kor-ABP) Registry and taking antihypertensive drugs, and classified them into the controlled hypertension (n = 465) and MUCH (n = 389) groups. MUCH was defined as the presence of a 24-hour ambulatory mean systolic BP ≥ 130 mmHg and/or diastolic BP ≥ 80 mmHg in patients treated with antihypertensive drugs, having normal office BP.

Results

Patients in the MUCH group had significantly worse metabolic profiles and higher office BP, and took significantly fewer antihypertensive drugs compared to those in the controlled hypertension group. Multivariate logistic regression analyses identified high office systolic BP and diastolic BP, prior stroke, dyslipidemia, left ventricular hypertrophy (LVH, ≥ 116 g/m² for men, and ≥ 96 g/m² for women), high heart rate (≥ 75 beats/min), and single antihypertensive drug use as independent predictors of MUCH. A prediction model using these predictors showed a high diagnostic accuracy (C-index of 0.839) and goodness-of-fit for the presence of MUCH.

Conclusions

MUCH is associated with a high-normal increase in office BP and underuse of antihypertensive drugs, as well as dyslipidemia, prior stroke, and LVH, which could underscore achieving optimal BP control. The proposed model accurately predicts MUCH in patients with controlled office BP.

Keywords: Masked uncontrolled hypertension; Blood pressure monitoring, ambulatory; Blood pressure

INTRODUCTION

Masked hypertension (MH) is defined as the presence of normal office blood pressure (BP) but high out-of-office BP, as determined by 24-hour ambulatory blood pressure monitoring (ABPM) or home BP monitoring [1]. As MH could also refer to those individuals not taking antihypertensive drugs, high out-of-office BP with normal office BP in patients on antihypertensive therapies, which was first described 10 years ago, was later renamed as masked uncontrolled hypertension (MUCH) [2]. MH is known to increase the risk of cardiovascular diseases as it is often undetected and untreated [3]. Previous studies on MH included patients with MUCH and did not distinguish cardiovascular risks between patients receiving antihypertensive therapies and those not receiving antihypertensive therapies [4–6]. Other studies previously reported significantly higher cardiovascular risk in patients with MUCH than in those with controlled hypertension [7–9]. The prognostic value of MUCH is not yet clear, but it is inseparable from MH in terms of increased cardiovascular risk. In outpatient department settings, where office BP remains the main BP assessment tool, no effective indicator has been widely used to detect MUCH, and therefore, it is difficult to suspect in daily practice. It is desirable to recognize clinical features strongly related to the presence of MUCH and to utilize these features as an effective screening tool for MUCH that can be easily availed in the outpatient setting. In this study, we investigated the clinical characteristics of MUCH and identified significant predictors for the presence of MUCH, using which we developed a prediction model for MUCH in patients who were treated with antihypertensive drugs.

METHODS

Study design and setting

Cross-sectional study data were obtained from the nationwide Korean ABPM (Kor-ABP) Registry for Evaluation of the Prognostic Threshold in Hypertension, organized by the Korean Society of Hypertension. This prospective multicenter cohort included patients who underwent 24-hour ABPM to evaluate high BP. The Kor-ABP registry involved outpatient clinics in 27 tertiary and secondary hospitals between August 2009 and December 2016 [10]. Treatment and drug administration were performed at the discretion of physicians for patients with hypertension, and all investigators were cardiologists who were experts on hypertension and clinical cardiology. Among the initially enrolled 5,965 patients who had undergone 24-hour ABPM, 5,404 patients had valid 24-hour ABPM data. Of these, 1,986 patients were treated with antihypertensive drugs. A total of 1,132 patients with elevated office BP (systolic blood pressure [SBP] ≥ 140 mmHg and/or diastolic blood pressure [DBP] ≥ 90 mmHg) were excluded. Therefore, 854 patients treated with antihypertensive drugs with normal office BP (SBP < 140 mmHg and/or DBP < 90 mmHg) were included in the final analysis, and we classified the patients into groups according to BP characteristics obtained from 24-hour ABPM as the MUCH and controlled hypertension groups (Fig. 1).

The study protocol complied with the Declaration of Helsinki, and was reviewed and approved by the Institutional Review Board of each center, including Hanyang University Seoul Hospital (HYUH IRB No. 2009-R-12). Written informed consent was obtained from all participants.

Data collection

Data were collected using a web-based electronic data capture system that included electronic case report forms from the Kor-ABP registry database. The following demographic and clinical characteristics were extracted: sex, age, body mass index (BMI), waist circumference (WC), extent of exercise, smoking status, alcohol intake, and traditional cardiovascular risk factors, including a history of hypertension, diabetes, dyslipidemia, stroke, myocardial infarction (MI), heart failure, and malignancy. Family history of hypertension, diabetes, and cardiovascular death was also obtained, along with data on antihypertensive drugs.

The following laboratory data were extracted: hemoglobin, triglyceride, total cholesterol, high-density lipoprotein cholesterol, low-density lipoprotein cholesterol (LDL-C), estimated glomerular filtration rate (mL/min/1.73 m²), hemoglobin A1c, and fasting glucose. Left ventricular ejection fraction and left ventricular mass index (LVMI) were extracted from M-mode echocardiographic estimation data. Left ventricular hypertrophy (LVH) was defined as LVMI ≥ 116 g/m² for men and ≥ 96 g/m² for women.

ABPM data and definition of groups

A raw ABPM dataset was considered valid only if it contained at least 20 valid recordings from while awake and seven valid recordings from during sleep, after excluding unmeasured recordings and recordings with extreme BP (SBP ≥ 350 or < 60 mmHg; DBP ≥ 250 or < 30 mmHg) [11]. Office BP was measured using a UA-767 monitor (A&D Co., Ltd., Tokyo, Japan), which had passed the European Hypertension Society protocol at all institutions. Office BP was determined as the mean BP of two measurements taken at 1 minute intervals with a 5-minute rest before the first measurement [12].

MUCH was defined as the presence of 24-hour ambulatory mean SBP of ≥ 130 mmHg and/or DBP of ≥ 80 mmHg in patients treated with antihypertensive drugs with normal office BP (SBP of < 140 mmHg and/or DBP of < 90 mmHg), according to the international guideline criteria for MH [1,13]. Controlled hypertension was defined as 24-hour ambulatory mean SBP/DBP of < 130/80 mmHg and office SBP/DBP of < 140/90 mmHg in patients receiving an antihypertensive drug.

Statistical analyses

The study population with normal office BP was divided into two groups according to the presence of high 24-hour ABPM (controlled hypertension or MUCH). Continuous variables such as age, BMI, and WC, and categorical variables such as sex and number of antihypertensive drugs in the two groups were compared using Student’s t test and chi-square test, respectively. Fisher’s exact test was used for non-parametric analyses.

Because 8% of the data in the original dataset was missing (Supplementary Fig. 1), we performed multiple imputations using a bootstrap expectation-maximization algorithm. Five possible imputed datasets were created, and the average value of the five imputed values was adopted as the missing values for the continuous variables. The most frequent value of the five imputed values was adopted for the categorical variables.

Univariate logistic regression analyses were used to evaluate the association between clinical factors and MUCH. To recognize the non-linearity of the associations with continuous variables (e.g., age, LVMI, heart rate [HR], BMI, and WC) and determine the optimal cut-off points for the variables, restrictive cubic spline fits were used in the univariate logistic regression analyses. A multivariate logistic regression model was developed to identify significant predictors of MUCH in patients with controlled office BP. All available potential confounders including age, sex, BMI, WC, exercise < 3 times/week, current alcohol intake or smoking, diabetes and dyslipidemia, history of stroke, MI or malignancy, family history of hypertension, diabetes or cardiovascular death, type and number of antihypertensive drugs, office SBP, office DBP, HR, and LDL-C levels were entered into the multivariate model as covariates to avoid prejudice. The multivariate model was reduced using a backward variable selection process to minimize overfitting of biases and to find the best-fit model (cut-off criteria, p < 0.05).

A prediction scoring system for MUCH was produced using the coefficients of significant predictors from the best-fit model. The largest among the coefficients of predictors was set as the integer 10, the maximum point in the nomogram, and the other coefficients were rescaled relative to the maximum point. The total score was calculated as the sum of the points assigned to all significant predictors included in the best-fit model, as previously described [14]. Receiver operating characteristic (ROC) curve analysis was conducted using the linear predictors derived from the best-fit model to evaluate the performance of the prediction scoring system for MUCH. Sensitivity, specificity, positive predictive value (PPV), and negative predictive value (NPV) were calculated at an optimal cut-off point derived from Youden’s J-index. The goodness of fit between the predicted probability and the observed incidence of MUCH was evaluated using the Hosmer-Lemeshow test. The observed incidence of MUCH was calculated at every score interval of 1 for the Hosmer-Lemershow test.

We conducted internal validation and calibration of the best-fit model using bootstrap resampling [15]. We validated the full logistic regression model with all covariates using 1,000 bootstrap resamples. In each bootstrap dataset, the full model with all covariates was reduced to a bootstrap model using a backward selection process, and optimism was estimated using the C-indexes of the best-fit and bootstrap models [16]. The number of absolute errors between the predicted probability and the actual probability of MUCH in the best-fit model was also estimated through a calibration procedure using the same 1000 bootstrap re-samples.

All statistical analyses were performed using the statistical software R3.6.1, Rstudio1.2.1, and its packages including “descry,” “rms,” “Amelia,” “tableone,” “coin,” “ROCR,” and “pROC.” Statistical significance was set at p < 0.05.

RESULTS

Baseline characteristics

Among the 1,986 patients treated with antihypertensive drugs, 854 had normal office BP. Among the patients with apparently normal office BP, 45.6% were classified into the MUCH group (n = 389) and 54.4% were classified into the controlled hypertension group (n = 465). Comparisons between baseline characteristics of the controlled hypertension and MUCH groups are presented in Table 1. Patients in the MUCH group were more frequently alcohol drinkers and presented with poorer metabolic profiles, including higher obesity indexes and serum cholesterol levels, compared with those in the controlled hypertension group. Office SBP and DBP were higher, and a history of stroke was slightly more common in the MUCH group than in the controlled hypertension group. In addition, the MUCH group took significantly fewer antihypertensive drugs than the controlled hypertension group, and the number of patients taking a single antihypertensive drug was significantly higher in the MUCH group than in the controlled hypertension group.

Prevalence of MUCH according to BP

The higher the office SBP and DBP, the higher the prevalence of MUCH (Fig. 2). However, when the office SBP was ≥ 130 mmHg, the prevalence of MUCH was similarly high at all DBP levels. The prevalence of MUCH did not differ according to the number of antihypertensive drugs; however, when the SBP was ≥ 130 mmHg, the prevalence of MUCH decreased with the increasing number of antihypertensive drugs.

Predictors for MUCH

The prevalence of MUCH and odds ratios (OR) with 95% confidence intervals (CI) for the presence of MUCH from univariate logistic regression analyses are presented according to various clinical factors in Table 2. An office SBP of 120 to 129 mmHg or 130 to 139 mmHg, office DBP of 80 to 84 mmHg or 85 to 89 mmHg, single antihypertensive drugs, history of stroke, HR ≥ 75 beats/min, BMI ≥ 25 kg/m², central obesity, LVH, male sex, and current alcohol intake were associated with the presence of MUCH (Table 2). In the multivariate logistic regression analysis, the best-fit model obtained after the backward variable selection process showed that office SBP, office DBP, stroke, dyslipidemia, LVH, HR ≥ 75 beats/minute, and the number of antihypertensive drugs used were significantly associated with the presence of MUCH (Table 3). In particular, the high-normal office SBP (130 to 139 mmHg) and DBP (85 to 89 mmHg) were most strongly associated with the presence of MUCH. The use of a smaller number of antihypertensive drugs was also associated with the presence of MUCH, when compared to the use of three drugs or more.

We also analyzed the association between the types of antihypertensive drugs and the presence of MUCH, using logistic regression models among patients taking a single antihypertensive drug (Supplementary Table 1). There was no significant difference in the occurrence of MUCH among the five antihypertensive drug groups (angiotensin-converting enzyme inhibitors, angiotensin II receptor blockers, calcium channel blockers, diuretics, and beta-blockers). The first multivariate model, including office SBP, office DBP, stroke, LVH, dyslipidemia, and HR ≥ 75 beats/minute as covariates (multivariate model 1), showed that no antihypertensive drugs were associated with the occurrence of MUCH. In addition, multivariate model 2, which excluded variables that could influence drug choice, also showed that there was no difference among antihypertensive drugs.

Prediction model for MUCH

Using the predictors included in the best-fit model derived from the multivariate logistic regression analysis, we developed a scoring system to predict MUCH in patients with apparently controlled office BP (Fig. 3 and Supplementary Table 2). The maximum point was set to 10 with an office SBP of 130 to 139 mmHg so that the scoring system could be more easily comprehended and utilized. Subsequently, the total score ranged from 0 to 26. In the ROC curve analysis, the scoring system showed good diagnostic performance for MUCH, yielding a C-index of 0.839 (95% CI, 0.813 to 0.866), sensitivity of 0.792, specificity of 0.776, PPV of 0.748, and NPV of 0.817 at a cut-off value of 9.6 points (Fig. 4A). The observed frequencies of MUCH increased gradually with the total score and were in close agreement with the probabilities predicted using the scoring system (Hosmer-Lemeshow goodness-of-fit test, p = 0.999) (Fig. 4B and Supplementary Table 3). An internal validation test using 1000 bootstrap samples showed that the C-index of the scoring system had only a small optimism value (0.020), and calibration between the observed and predicted probability of MUCH estimated using the same bootstrap resamples produced values of 0.031 for the mean absolute error and 0.062 for the 0.9th quantile absolute error (Supplementary Fig. 2).

DISCUSSION

In this study, we found that more than half of the patients on antihypertensive drugs who appeared to have controlled office BP actually had MUCH. Suboptimal office SBP and DBP levels, as well as underuse of antihypertensive drugs, increased HR, dyslipidemia, previous stroke, and LVH were strongly associated with an increased risk of MUCH. The proposed model employing these clinical predictors showed high accuracy for predicting the presence of MUCH in an outpatient clinic setting.

Guidelines for the management of hypertension [13,17,18] emphasize the importance of 24-hour ABPM, making it important for the diagnosis of white-coat hypertension and MH. MUCH, which is defined by normal office BP and elevated out-of-office BP in patients receiving treatment for hypertension [2,9], can also be detected using 24-hour ABPM. Recent studies using meta-analyses, including prospective cohort studies, have shown that patients with MUCH face increased risks of cardiovascular events and all-cause death (hazard ratio, 1.80; 95% CI, 1.57 to 2.06) compared with patients with controlled hypertension [9]. In addition, because of the high incidence of cardiovascular events and predictable cardiac events in MH [19], it is important to know its clinical features and predictors in patients receiving hypertension treatment, especially in the MUCH subtype.

Our results underline the importance of the so-called high-normal office BP, which can be defined as an office SBP of 130 to 139 mmHg or DBP of 85 to 89 mmHg. The prevalence of MUCH increased 15-fold and 3-fold in patients with high-normal office SBP and DBP, respectively. A previous study using the Spanish Society of Hypertension ABPM registry data reported the prevalence of MUCH as 31.1% among patients with treated and controlled office BP (< 140/90 mmHg) [1]. The researchers in the Spanish registry study showed that the presence of MUCH was also associated with high-normal office SBP and DBP, similar to our results.

Whether high-risk characteristics correlate with MUCH remains controversial. However, several studies have indicated that the risk profile of MH patients is in line with the risk profile of patients with MUCH. Metabolic disorders, including central obesity, hypertension, diabetes, and dyslipidemia, also increase the risk of MH [20–22]. Our results confirmed that patients with MUCH have more metabolic disturbances than patients with controlled hypertension. BMI ≥ 25 kg/m² and WC were significantly associated with MUCH, and dyslipidemia was an independent relevant factor for MUCH in our study. In addition, a history of stroke was an independent risk factor for MUCH. MH has been associated with a higher risk of stroke [5], but the mechanism by which a history of stroke increases the risk of MH has yet to be determined. Moreover, one of the markers of target organ damage, LVH, was associated with MUCH in our study. Therefore, it seems reasonable to perform ABPM in individuals with these metabolically high-risk characteristics or target organ damage, such as LVH.

Previous studies have demonstrated that patients with excessive alcohol intake have an increased incidence of MH [23,24]. Ishikawa et al. [23] reported that regular alcohol consumption increased the risk of MUCH by 1.76-fold in patients with stable hypertension. Our study supports previous findings that patients with MUCH were significantly more likely to be alcohol drinkers, with a 1.63-fold increased risk of MUCH compared to patients with controlled hypertension on univariate logistic regression analyses. Although current alcohol intake was not an independent risk factor for MUCH, in patients with high-normal BP or other metabolic risks, alcohol consumption may be considered and assessed as a factor affecting MUCH, regardless of the controlled-BP status.

In this study, we proposed a prediction model for MUCH that appeared to provide high diagnostic accuracy and goodness of fit for clinicians to identify patients with MUCH in outpatient settings using several easily available clinical features. The internal validation and calibration results obtained using the bootstrap resampling technique also showed sufficient reliability and validity of the model. It may be difficult for clinicians to notice the presence of MUCH in regular outpatients on antihypertensive drugs, since the condition is asymptomatic and, to date, office BP remains the main BP measurement tool and lacks any widely known clinical clues suggestive of MUCH. As MUCH is highly prevalent in patients with apparently controlled BP and is known to result in worse clinical outcomes [9], clinicians should be mindful of identifying MUCH in those patients with the predictors for MUCH. Although sufficient external validations are required, the proposed prediction model may be useful in providing clinical cues for clinicians to prescribe ABPM in regular outpatients on antihypertensive drugs who satisfy some of the predictors.

Furthermore, the strong association between high-normal office BP and the lower number of antihypertensive drugs in the prediction model could provide the valuable insight that suboptimal office BP control through the underuse of antihypertensive drugs plays an important role in the development of MUCH. The significant interaction between the number of antihypertensive drugs and office SBP on the lower risk of MUCH may also underscore the role of suboptimal antihypertensive therapy in the development of MUCH. Although sub-analysis was performed according to the type of single antihypertensive drug used to evaluate whether the risk of MUCH varied with the drug of choice, there was no significant difference. Further study will be needed in the future to determine which combination of antihypertensive drugs affects the risk of MUCH. In addition to suboptimal office BP, studies to determine MUCH-specific parameters to filter out those patients with actual uncontrolled BP will be needed.

This study has several limitations. First, as with any cross-sectional study, the associations between the variables observed could not establish a causal relationship. Second, we did not assess medication non-compliance, a well-known cause of uncontrolled BP in patients on antihypertensive drugs. However, a recent study showed that unlike uncontrolled hypertension, MUCH is not attributable to medication non-adherence [25]. Third, the duration of history of comorbidities, including hypertension and stroke, may be an important factor in uncontrolled hypertension, but data on these were insufficient. Approximately 8% of the original data were missing, with the rate of missing values varying from 0% to 58% among the variables. We did not exclude records with missing values and performed multiple imputations to prevent a loss of statistical power due to exclusion of data [26]. Although multiple imputation using a bootstrap expectation-maximization algorithm is a frequently employed method for imputations, imputed data may have had unanticipated effects on the results. Finally, we validated and calibrated the prediction model internally using bootstrap resampling. Although resampling is a well-established method for internal validation, external validation using an independent dataset derived from a similar clinical settings will provide more confidence in the model.

MUCH is highly prevalent in patients with apparently controlled office BP. A borderline increase in office SBP and DBP, and underuse of antihypertensive drugs, as well as dyslipidemia, increased HRs, previous stroke, and LVH are independently associated with the presence of MUCH, which underscores the role of suboptimal treatment of hypertension in the development of MUCH. Clinicians should be mindful of the presence of MUCH in patients with these predictors, and the proposed prediction model may serve as a useful screening tool for MUCH to provide a clinical cue to prescribe 24-hour ABPM to patients.

KEY MESSAGE

1. Among patients with treated hypertension and normal office blood pressure (BP), 45.6% had masked uncontrolled hypertension (MUCH), which could be mistaken for good control by masking.

2. The borderline ranges of office systolic BP and diastolic BP were independently associated with a significantly increased risk of MUCH.

3. In this study, the proposed predictive model can act as a quick screening tool for MUCH before patients can perform 24-hour ambulatory BP monitoring.

Supplementary Materials

kjim-2020-650-suppl1.pdf

kjim-2020-650-suppl2.pdf

kjim-2020-650-suppl3.pdf

kjim-2020-650-suppl4.pdf

kjim-2020-650-suppl5.pdf

Conflict of Interest

No potential conflict of interest relevant to this article was reported.

Acknowledgments

We wish to thank the Working Group of Blood Pressure Monitoring in Korean Society of Hypertension for managing the registry data construction.

Figure 1

Study population. ABPM, ambulatory blood pressure monitoring; BP, blood pressure; MUCH, masked uncontrolled hypertension; ROC, receiver operating characteristic. ^aAt least 20 recordings during wakefulness and seven recordings during sleep, after the exclusion of unmeasured recordings and recordings with extreme blood pressures (systolic BP ≥ 350 or < 60 mmHg; diastolic BP ≥ 250 or < 30 mmHg).

Figure 2

Prevalence of masked uncontrolled hypertension (MUCH) according to blood pressure levels. (A) MUCH was more frequent in patients with high systolic blood pressure (SBP) and diastolic blood pressure (DBP). However, when office SBP was ≥ 130 mmHg, the frequencies of MUCH were comparably high. (B) The frequencies of MUCH did not differ according to the number of antihypertensive drugs; however, when the SBP was ≥ 130 mmHg, the frequencies of MUCH decreased with increasing numbers of antihypertensive drugs.

Figure 3

Nomogram of the scoring system predicting for masked uncontrolled hypertension. SBP, systolic blood pressure; DBP, diastolic blood pressure; LVMI, left ventricular mass index.

Figure 4

Diagnostic performances and the goodness of fit of the score system predicting. (A) Receiver operating characteristic curve analysis showed that the score system showed good diagnostic performance for masked uncontrolled hypertension. (B) Hosmer-Lemeshow goodness-of-fit test. AUC, area under the curve; CI, confidence interval; PPV, positive predictive value; NPV, negative predictive value.

Table 1

Comparison of the baseline characteristics between the controlled HTN and MUCH groups

Characteristic	Controlled HTN (n = 465)	Masked uncontrolled HTN (n = 389)	p value
Male sex	241 (51.8)	236 (60.7)	0.012
Age, yr	61.1 ± 11.6	60.2 ± 12.9	0.268
BMI, kg/m²	24.6 ± 3.3	25.0 ± 3.3	0.047
WC, cm	89.6 ± 9.0	91.0 ± 9.0	0.021
Exercise			0.597
None	212 (45.6)	182 (46.8)
1 time/week	32 (6.9)	30 (7.7)
2 times/week	44 (9.5)	33 (8.5)
3 times/week	53 (11.4)	37 (9.5)
4 times/week	23 (4.9)	29 (7.5)
≥ 5 times/week	101 (21.7)	78 (20.1)
Exercise ≥ 3 times/week	177 (38.1)	144 (37.0)	0.808
Smoking			0.405
Never	285 (61.3)	225 (57.8)
Former	139 (29.9)	120 (30.8)
Current	41 (8.8)	44 (11.3)
Alcohol			0.004
Never	119 (25.6)	100 (25.7)
Former	245 (52.7)	168 (43.2)
Current	101 (21.7)	121 (31.1)
Comorbidities
Hypertension	349 (75.1)	296 (76.1)	0.786
Diabetes	121 (26.0)	115 (29.6)	0.282
Dyslipidemia	119 (25.6)	114 (29.3)	0.256
Stroke	26 (5.6)	45 (11.6)	0.002
Myocardial infarction	62 (13.3)	45 (11.6)	0.501
Heart failure^a	40 (8.6)	30 (7.7)	0.729
Malignancy	23 (4.9)	19 (4.9)	1.000
Family history
Hypertension	208 (44.7)	181 (46.5)	0.648
Diabetes	94 (20.2)	79 (20.3)	1.000
CV death	15 (3.2)	13 (3.3)	1.000
Medications
Antiplatelet agent^b	292 (63.2)	233 (59.9)	0.323
Statin	224 (48.2)	169 (43.4)	0.190
ACEI	41 (8.8)	39 (10.0)	0.627
ARB	289 (62.2)	209 (53.7)	0.016
CCB	226 (48.6)	197 (50.6)	0.599
Beta-blocker	208 (44.7)	149 (38.3)	0.068
Diuretics	90 (19.4)	63 (16.2)	0.267
Other antihypertensive	47 (10.1)	30 (7.7)	0.273
No. of antihypertensive drugs			0.009
1	172 (37.0)	186 (47.8)
2	180 (38.7)	133 (34.2)
≥ 3	113 (24.3)	70 (18.0)
Office BP
Office SBP, mmHg	119.7 ± 9.7	129.3 ± 8.8	< 0.001
Office DBP, mmHg	73.6 ± 7.6	78.7 ± 7.3	< 0.001
Heart rate, beats/min	71.5 ± 11.1	72.7 ± 10.4	0.096
Ambulatory blood pressure monitoring
24-hour mean SBP, mmHg	118.0 ± 7.0	134.9 ± 8.8	< 0.001
24-hour mean DBP, mmHg	72.2 ± 5.1	82.1 ± 6.8	< 0.001
Daytime mean SBP, mmHg	121.0 ± 8.0	137.6 ± 9.0	< 0.001
Daytime mean DBP, mmHg	74.3 ± 5.7	84.1 ± 7.3	< 0.001
Nighttime mean SBP, mmHg	109.6 ± 10.5	126.6 ± 13.7	< 0.001
Nighttime mean DBP, mmHg	66.3 ± 6.9	76.2 ± 8.7	< 0.001
Echocardiography
Ejection fraction	59.1 ± 7.1	58.8 ± 6.8	0.514
LVMI (BSA), g/m²	96.5 ± 25.0	102.3 ± 23.2	0.001
Laboratory tests
Hemoglobin, g/dL	13.4 ± 1.7	13.5 ± 1.8	0.384
Triglyceride, mg/dL	119 (87–152)	118 (85–159)	0.983
Total cholesterol, mg/dL	167.6 ± 40.8	173.3 ± 40.7	0.041
HDL-C, mg/dL	46.0 ± 11.0	46.0 ± 11.8	0.938
LDL-C, mg/dL	96.6 ± 35.3	100.7 ± 32.7	0.085
eGFR (CKD-EPI), mL/min/1.73 m²	81.9 ± 20.5	83.3 ± 21.0	0.316
Fasting glucose, mg/dL	110.6 ± 26.9	109.9 ± 27.5	0.703
HgA1c, %	6.1 ± 0.9	6.1 ± 1.0	0.499

Values are presented as number (%), mean ± standard deviation, or median (interquartile range).

HTN, hypertension; MUCH, masked uncontrolled hypertension; BMI, body mass index; WC, waist circumference; CV, cardiovascular; ACEI, angiotensin-converting enzyme inhibitor; ARB, angiotensin II receptor blocker; CCB, calcium channel blocker; BP, blood pressure; SBP, systolic blood pressure; DBP, diastolic blood pressure; LVMI, left ventricular mass index; BSA, body surface area; HDL-C, high-density lipoprotein cholesterol; LDL-C, low-density lipoprotein cholesterol; eGFR, estimated glomerular filtration rate; CKD-EPI, Chronic Kidney Disease Epidemiology Collaboration; HgA1c, hemoglobin A1c.

^a Heart failure was defined as the composite of hypertrophic cardiomyopathy, dilated cardiomyopathy, moderate to severe valve dysfunction, and ejection fraction < 40%.

^b Antiplatelet agents including aspirin, clopidogrel, and a new P2Y12 inhibitor.

Table 2

Prevalence of MUCH in various clinical settings

Variable	No.	MUCH	% (95% CI)	OR (95% CI), p value
Total	854	389	44.1 (40.8–47.5)
Office SBP
< 120 mmHg	251	41	16.3 (11.8–20.9)	Reference^b
120–129 mmHg	286	100	35.0 (29.4–40.5)	2.75 (1.82–4.16), < 0.001
130–139 mmHg	317	248	78.2 (73.7–82.8)	18.4 (12.0–28.2), < 0.001
Office DBP
< 80 mmHg	536	174	32.5 (28.5–36.4)	Reference
80–84 mmHg	203	132	65.0 (58.5–71.6)	3.87 (2.75–5.44), < 0.001
85–89 mmHg	115	83	72.2 (64.0–80.4)	5.40 (3.45–8.43), < 0.001
No. of antihypertensive drugs
≥ 3	183	70	38.3 (31.2–45.3)	Reference
2	313	133	42.5 (37.0–48.0)	1.29 (0.88–1.88), 0.183
1	358	186	52.0 (46.8–57.1)	1.71 (1.71–2.48), 0.005
History of stroke
No	783	344	43.9 (40.5–47.4)	Reference
Yes	71	45	63.4 (52.2–74.6)	2.21 (1.34–3.65), 0.002
Dyslipidemia
No	621	275	44.3 (40.4–48.2)	Reference
Yes	233	114	48.9 (42.5–55.3)	1.21 (0.89–1.63), 0.225
HR ≥ 75 beats/min^a
No	369	154	41.7 (36.7–46.8)	Reference
Yes	486	235	48.5 (44.0–52.9)	1.41 (1.06–1.86), 0.017
BMI ≥ 25 kg/m²
No	475	201	42.3 (37.9–46.8)	Reference
Yes	379	188	49.6 (44.6–54.6)	1.34 (1.02–1.76), 0.034
WC ≥ 90 cm for men, ≥ 85 cm for women
No	329	135	41.0 (35.7–46.3)	Reference
Yes	525	254	48.4 (44.1–52.7)	1.35 (1.02–1.78), 0.036
LVH^a
No	569	240	42.2 (38.1–46.2)	Reference
Yes	285	149	52.3 (46.5–58.1)	1.50 (1.13–2.00),0.005
Current alcohol intake
No	632	268	42.4 (38.6–46.3)	Reference
Yes	222	121	54.5 (48.0–61.1)	1.63 (1.20–2.21), 0.002
Antiplatelet agent
No	405	182	44.9 (40.1–49.8)	Reference
Yes	449	207	46.1 (41.5–50.7)	1.05 (0.80–1.37), 0.733
Current smoking
No	769	345	44.9 (41.3–48.4)	Reference
Yes	85	44	51.8 (41.1–62.4)	1.32 (0.84–2.07), 0.227
Sex
Female	377	153	40.6 (35.6–45.5)	Reference
Male	477	236	49.5 (45.0–54.0)	1.43 (1.09–1.88),0.010
Age ≥ 50 years^a
No	141	70	49.6 (41.4–57.9)	Reference
Yes	713	319	44.7 (41.1–48.4)	0.82 (0.57–1.18), 0.286
Diabetes
No	618	274	44.3 (40.4–48.3)	Reference
Yes	236	115	48.7 (42.4–55.1)	1.19 (0.88–1.61), 0.249

MUCH, masked uncontrolled hypertension; CI, confidence interval; OR, odds ratio; SBP, systolic blood pressure; DBP, diastolic blood pressure; HR, heart rate; BMI, body mass index; WC, waist circumference; LVH, left ventricular hypertrophy.

^a Cut-off values of the continuous variables were determined using univariate logistic regression models with a restrictive cubic spline fit for the variables.

^b Categories used as references.

Table 3

Multivariate logistic regression model of the predictors for masked hypertension

Variable	OR^a	95% CI	p value
Office SBP
120–129 mmHg vs. < 120 mmHg	2.22	1.42–3.46	< 0.001
130–139 mmHg vs. < 120 mmHg	14.9	9.34–23.7	< 0.001
Office DBP
80–84 mmHg vs. < 80 mmHg	2.47	1.64–3.71	< 0.001
85–89 mmHg vs. < 80 mmHg	3.15	1.87–5.30	< 0.001
Stroke	2.61	1.39–4.89	0.003
LVH	1.96	1.36–2.85	< 0.001
No. of antihypertensive drugs
1 vs. ≥ 3	2.39	1.52–3.77	< 0.001
2 vs. ≥ 3	1.58	1.00–2.51	0.048
Dyslipidemia	1.66	1.14–2.41	0.009
Heart rate ≥ 75 beats/min	1.45	1.02–2.06	0.040

The multivariate model was reduced using a backward variable selection process (cut-off criteria, p < 0.05).

OR, odds ratio; CI, confidence interval; SBP, systolic blood pressure; DBP, diastolic blood pressure; LVH, left ventricular hypertrophy.

^a Covariates include age, sex, body mass index, waist circumference, exercise < 3 times/week, current alcohol intake or smoking, diabetes and dyslipidemia, past histories of stroke, myocardial infarction, and malignancies; family histories of hypertension, diabetes, and cardiovascular death; types and number of antihypertensive medications, left ventricular mass index, medications, office SBP, office DBP, heart rate, and low-density lipoprotein cholesterol levels.

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