1.Is Increased Aortic Stiffness Associated with Advanced Ischemic Stroke?.
Journal of Cardiovascular Ultrasound 2013;21(1):10-11
No abstract available.
Vascular Stiffness
2.T Cell Immunosenescence, Hypertension, and Arterial Stiffness.
Epidemiology and Health 2014;36(1):e2014005-
No abstract available.
Hypertension*
;
Vascular Stiffness*
3.Arterial stiffness during acute and recovery phases of children with rheumatic fever
Nik Nor Izah Nik Ibrahim ; Hayati Jaafar ; Aida Hanum Ghulam Rasool ; Abdul Rahim Wong
The Medical Journal of Malaysia 2016;71(1):23-25
Acute rheumatic fever (ARF) is associated with systemic
inflammation and arterial stiffness during the acute stage. It
has not been reported if arterial stiffness remains after
recovery. The aim of this study was to determine the arterial
stiffness during acute stage and 6 months after recovery
from ARF. Arterial stiffness was assessed by carotid femoral
pulse wave velocity (PWV) in 23 ARF patients during the
acute stage of ARF and 6 months later. Simultaneously,
erythrocyte sedimentation rate (ESR) and other
anthropometric measurements were taken during both
stages. There was a significant reduction in PWV; 6.5 (6.0,
7.45) m/s to 5.9 (5.38, 6.48) m/s, p=0.003 6 months after the
acute stage of ARF. Similarly, ESR was also significantly
reduced from 92.0 (37.5, 110.50) mm/hr to 7.0 (5.0, 16.0)
mm/hr, p=0.001. In conclusion, arterial stiffness improved 6
months after the acute stage with routine aspirin treatment;
this correlates well with the reduction in systemic
inflammation.
Rheumatic Fever
;
Vascular Stiffness
4.Association between Fruit and Vegetable Intake and Arterial Stiffness: The China-PAR Project.
Shuai LIU ; Fang Chao LIU ; Jian Xin LI ; Ke Yong HUANG ; Xue Li YANG ; Ji Chun CHEN ; Jie CAO ; Shu Feng CHEN ; Jian Feng HUANG ; Chong SHEN ; Xiang Feng LU ; Dong Feng GU
Biomedical and Environmental Sciences 2023;36(12):1113-1122
OBJECTIVE:
This study aimed to investigate the association between fruit and vegetable intake and arterial stiffness.
METHODS:
We conducted a cohort-based study comprising 6,628 participants with arterial stiffness information in the Prediction for Atherosclerotic Cardiovascular Disease Risk in China (China-PAR) project. A semi-quantitative food-frequency questionnaire was used to assess baseline (2007-2008) and recent (2018-2021) fruit and vegetable intake. We assessed changes in fruit and vegetable intake from 2007-2008 to 2018-2021 in 6,481 participants. Arterial stiffness was measured using the arterial velocity-pulse index (AVI) and arterial pressure-volume index (API). Elevated AVI and API values were defined according to diverse age reference ranges.
RESULTS:
Multivariable-adjusted linear regression models revealed that every 100 g/d increment in fruit and vegetable intake was associated with a 0.11 decrease in AVI ( B= -0.11; 95% confidence interval [ CI]: -0.20, -0.02) on average, rather than API ( B = 0.02; 95% CI: -0.09, 0.13). The risk of elevated AVI (odds ratio [ OR] = 0.82; 95% CI: 0.70, 0.97) is 18% lower in individuals with high intake (≥ 500 g/d) than in those with low intake (< 500 g/d). Furthermore, maintaining a high intake in the past median of 11.5 years of follow-up was associated with an even lower risk of elevated AVI compared with a low intake at both baseline and follow-up ( OR = 0.64; 95% CI: 0.49, 0.83).
CONCLUSION
Fruit and vegetable intake was negatively associated with arterial stiffness, emphasizing recommendations for adherence to fruit and vegetable intake for the prevention of arterial stiffness.
Humans
;
Vascular Stiffness
;
Fruit
;
Vegetables
;
Atherosclerosis
;
China
5.Effects of Age on Arterial Stiffness and Blood Pressure Variables in Patients with Newly Diagnosed Untreated Hypertension.
Soo Kyung CHO ; Sang Ki CHO ; Kye Hun KIM ; Jae Yeong CHO ; Hyun Ju YOON ; Nam Sik YOON ; Young Joon HONG ; Hyung Wook PARK ; Ju Han KIM ; Youngkeun AHN ; Myung Ho JEONG ; Jeong Gwan CHO ; Jong Chun PARK
Korean Circulation Journal 2015;45(1):44-50
BACKGROUND AND OBJECTIVES: To investigate the impact of age on arterial stiffness and blood pressure (BP) variables in newly diagnosed untreated hypertension (HT). SUBJECTS AND METHODS: A total of 144 patients with newly diagnosed untreated HT were divided into two groups: young group (age < or =50 years, n=71), and old group (age >50 years, n=73). BP variables were measured on office or 24 hours ambulatory BP monitoring (ABPM). Parameters of arterial stiffness were measured on pulse wave velocity (PWV). Pulse wave analysis (PWA) was compared. RESULTS: Although office BP and pulse pressure (PP) were significantly (p<0.05) higher in the young group than in the old group, BP and PP on ABPM were not significantly different. Central systolic BP and PP, augmentation pressure, augmentation index on PWA, and PWV were significantly higher or faster in the old group compared to that in the young group. Age showed significant positive correlation with both PWV and PWA variables in the young group with HT. However, age only showed significant positive correlation with PWV in the old group with HT. In the young group with HT, PWA variable showed better correlation with age than PWV. CONCLUSION: Considering BP levels on ABPM, office BP is prone to be overestimated in young patients with HT. Parameters of arterial stiffness measured by PWV and PWA were more affected by age rather than by BP level in patients with HT. Therefore, PWA variable might be a more sensitive marker of arterial stiffness in young patients with HT. However, PWV might be a better marker for old patients with HT.
Aging
;
Blood Pressure*
;
Humans
;
Hypertension*
;
Pulse Wave Analysis
;
Vascular Stiffness*
6.Measurements of Arterial Stiffness: Methodological Aspects.
Moo Yong RHEE ; Hae Young LEE ; Jeong Bae PARK
Korean Circulation Journal 2008;38(7):343-350
A significant association between increased arterial stiffness and the development of cardiovascular disease has led to the increased use of arterial stiffness in the clinical assessment of cardiovascular risk. Various methods are currently available. With advances in technology, the assessment methods have become easy to use and more acceptable to patients. However, the different techniques that are available measure arterial stiffness at different locations and have unique indices for arterial stiffness. For the appropriate assessment of arterial stiffness, accurate and reproducible measurements of arterial stiffness are essential. Here we review the methodological aspects of the measurement of arterial stiffness and provide information on the measurement methods available and their clinical applications.
Arteries
;
Atherosclerosis
;
Cardiovascular Diseases
;
Elasticity
;
Humans
;
Risk Factors
;
Vascular Stiffness
7.Response: The Effect of an Angiotensin Receptor Blocker on Arterial Stiffness in Type 2 Diabetes Mellitus Patients with Hypertension (Diabetes Metab J 2011;35:236-42).
Ji Hyun KIM ; Su Jin OH ; Jung Min LEE ; Eun Gyoung HONG ; Jae Myung YU ; Kyung Ah HAN ; Kyung Wan MIN ; Hyun Shik SON ; Sang Ah CHANG
Diabetes & Metabolism Journal 2011;35(4):429-430
No abstract available.
Angiotensins
;
Diabetes Mellitus, Type 2
;
Humans
;
Hypertension
;
Vascular Stiffness
8.Letter: The Effect of an Angiotensin Receptor Blocker on Arterial Stiffness in Type 2 Diabetes Mellitus Patients with Hypertension (Diabetes Metab J 2011;35:236-42).
Diabetes & Metabolism Journal 2011;35(4):427-428
No abstract available.
Angiotensins
;
Diabetes Mellitus, Type 2
;
Humans
;
Hypertension
;
Vascular Stiffness
9.Effect of Rheumatoid Factor on Vascular Stiffness in General Population without Joint Symptoms.
Ji Hyun LEE ; Hee Sang TAG ; Geun Tae KIM ; Min Jeong KIM ; Seung Geun LEE ; Eun Kyung PARK ; Dong Wan KOO
Kosin Medical Journal 2017;32(1):25-35
OBJECTIVES: The role of rheumatoid factor (RF) in vascular stiffness and cardiovascular risk in subjects without joint symptoms remains unclear. We investigated vascular stiffness in subjects without joint symptoms using pulse wave velocity (PWV), calculated Framingham risk scores (FRS), an estimator of cardiovascular risk, and analyzed whether vascular stiffness and FRS were affected by RF. METHODS: Two hundred forty-two subjects were included in this population-based study. RF was quantified with turbid immunometry using a cut-off of RF > 15 IU/ml to denote RF positivity. Information was then obtained on joint symptoms. Brachial-ankle PWV (baPWV) was measured using an automated device. RESULTS: Of the 242 subjects, 15 were RF-positive. RF-positive subjects without joint symptoms had a higher baPWV and FRS than RF-negative subjects without joint symptoms, but the difference did not reach statistical significance. However, when we stratified the subjects into two groups (group A – high RF: RF ≥ 40 IU/ml; group B – low RF: RF < 40 IU/ml), group A showed significantly higher baPWV (1640.7 ± 179.6 ㎝/s vs. 1405.7 ± 225.7 ㎝/s, P = 0.008) and FRS (25.7 ± 4.87 vs. 11.8 ± 9.6, P < 0.001). Multiple regression analysis was used to examine potential confounders, and RF exhibited significant but modest effects on baPWV (adjusted R-squared = 0.038, P = 0.030). CONCLUSIONS: In a sample of the general population without joint symptoms, higher levels of RF were associated with increased vascular stiffness, suggesting a pathophysiologic link between RF and endothelial dysfunction.
Joints*
;
Pulse Wave Analysis
;
Rheumatoid Factor*
;
Vascular Stiffness*
10.New Aging Index Using Signal Features of Both Photoplethysmograms and Acceleration Plethysmograms.
Healthcare Informatics Research 2017;23(1):53-59
OBJECTIVES: Acceleration plethysmograms (APGs) are obtained by taking the second derivative of photoplethysmograms (PPGs) and are noninvasive circulatory signals related to risk factors for atherosclerosis with age. There has been growing interest in the development of mobile devices to collect and analyze PPG single features for ambulatory health monitoring. The present study aimed to extract a new feature from the morphologies of APG and PPG signals to classify the dominant indices related to the pulsatile volume of blood in tissue according to age. METHODS: Ten APG and 14 PPG indices were simultaneously extracted. All indices were compared via Pearson correlation coefficients (r) and a regression analysis. We introduced a combined index extracted from both the PPG and APG indices defined as the inflection point area plus the d_peak (IPAD). The participants included 93 healthy adults aged 36–86 years with a mean ± standard deviation age of 57.43 ± 11.99 years. RESULTS: The d_peak and age index for the APG indices were significantly correlated with age (r = −0.408, p < 0.0001 and r = 0.296, p = 0.0039, respectively). Only the A1 time for PPG indices was moderately correlated with age (r = −0.247, p = 0.017). The stiffness index, including individual height information, was not related to age (r = −0.031, p = 0.7713). However, the combined IPAD index was significantly more correlated with age (r = 0.56, p < 0.001) than the other indices. CONCLUSIONS: The proposed index outperformed the other 24 indices for evaluating vascular aging. We suggest that the IPAD is a significant factor related to the clinical information embedded in the PPG waveform.
Acceleration*
;
Adult
;
Aging*
;
Atherosclerosis
;
Humans
;
Photoplethysmography
;
Risk Factors
;
Vascular Stiffness