Heart failure is common in older people and its prevalence is increasing.The Heart 'omics' in AGEing(HOMAGE) project aims to provide a biomarker approach that will improve the early diagnosis of heart failure.A la...Heart failure is common in older people and its prevalence is increasing.The Heart 'omics' in AGEing(HOMAGE) project aims to provide a biomarker approach that will improve the early diagnosis of heart failure.A large clinical database,based on(1) prospective population studies or(2) cross-sectional,prospective studies or randomized controlled trials(RCTs) of patients at risk for or with overt cardiovascular disease will be constructed to determine most promising 'omics'-based biomarkers to identify the risk of developing heart failure and/or comorbidities.Population studies,patient cohorts and RCTs are eligible for inclusion in the common database,if they received ethical approval to obtain and share data and have baseline information on cardiovascular risk factors.Currently,the HOMAGE database includes 43,065 subjects,from 20 studies in eight European countries,including healthy subjects from three population studies in France,Belgium and Italy(n = 7,124),patients with heart failure(n = 4,312) from four cohorts in the UK,Spain and Switzerland and patients at high risk for cardiovascular disease(n = 31,629) in 13 cohorts.It is anticipated that more partners will join the consortium and enlarge the pooled data.This large merged database will be a useful resource with which to identify candidate biomarkers that play a role in the mechanism underlying the onset and progression of heart failure.展开更多
Background The myocardial ATP sensitive potassium channel (KATP channel) has been known for more than two decades, the properties of this channel have been intensively investigated, especially the myocardial protect...Background The myocardial ATP sensitive potassium channel (KATP channel) has been known for more than two decades, the properties of this channel have been intensively investigated, especially the myocardial protection effect by opening this channel. Numerous studies, including hypothermic, using KATP agonists to achieve a hyperpolarizing cardioplegic arrest, have shown a better myocardial protection than potassium arrest. However, there is no evidence showing that KATP channel could be opened by its agonists under profound hypothermia. We investigated the effect of temperature on activation of myocardial KATP channel by nicorandil.Methods Isolated ventricular myocytes were obtained by collagenase digestion of the hearts of guinea pigs and stored in KB solution at 4℃. With a steady ground current, the myocytes were perfused with 1 mmol/L nicorandil until a steady IKATP occurred. Then the cells were perfused with 1 mmol/L nicorandil plus 1 μmol/L glybenclamide. Currents signals were recorded on whole cells using patch clamp technique at several temperatures. The temperature of the bath solution around myocytes was monitored and was controlled at 4℃, 10℃, 20℃, 25℃ and 35℃ respectively. About 10 cells were tested at each temperature, the cells were considered useful only when the outward current could be induced by nicorandil and blocked by glybenclamide. All data were analyzed using Graphpad PRISM 3.0 (Graphpad, San Diego, CA, USA). Nonlinear curve fitting was done in Clampfit (Axon) or Sigmaplot (SPSS).Results At 4℃, 10℃, 20℃, 25℃ and 35℃, the time needed to open the myocardial KATP channel was (81.0±0) minutes, (50.54±11.7) minutes, (28.84±2.3) minutes, (9.4± 10.2) minutes and (2.3± 1.0) minutes respectively (P=0.003). The linear relationship between temperature and time needed to open the channel was y (min) = (4348.790±124.277x)/60, where y (min) is time needed to open KATP channel, x is temperature, correlation coefficient r =-0.942 (P=0.00), regression coefficient b =-124.277 (P=0.00). The current densities among different temperatures were statistically different (P=0.022), the current density was greater after the activation of KATP channel at higher temperatures. The lower the temperature, the fewer cells in which KATP channels could be opened. At 4℃, only one cell in which the KATP channel could be opened, took a quite long time (81 minutes)and the Ⅰ-Ⅴ curve was quite untypical.Conclusions KATP channel activated by nicorandil is temperature dependent and the temperature linearly related to time needed to open KATP channel; the lower the temperature, the longer the time needed to open channel and the smaller the current density. At profound hypothermia, it is difficult to activate KATP channels.展开更多
Background Some studies have confirmed that the right ventricular walls of most rodents, such as canines and humans, have evident transient outward potassium current (I to1) heterogeneity, and this heterogeneity i...Background Some studies have confirmed that the right ventricular walls of most rodents, such as canines and humans, have evident transient outward potassium current (I to1) heterogeneity, and this heterogeneity is closely related to J point elevation, J wave formation, and some ventricular tachycardias such as ventricular fibrillations caused by Brugada syndrome. This study is designed to investigate transmural electrical heterogeneity of the canine right ventricle during repolarization (phase 1) from the viewpoint of 4-aminopyridine sensitive and calcium-independent I to1. Methods Adult canine single right ventricular epicardial (Epi) cells, mid-myocardial (M) cells, and endocardial (Endo) cells were enzymatically dissociated. Whole cell voltage-clamp recordings were made to compare the I to1 values of the three cell types. Results At 37℃ and using 0.2 Hz and +70 mV depolarizing test potentials, the average peak I to1 values of Epi cells and M cells averaged (4070±1720) pA and (3540±1840) pA, respectively. The activated and inactivated Epi and M cells kinetic processes were in accordance with the Boltzmann distribution. Compared with I to1 in Epi cells and M cells, the average peak I to1 in Endo cells was very low, averaged (470±130) pA. Conclusions These results suggest that there are evident differences and potent gradients in I to1 between the three cardiac cell types, especially between Epi and Endo cells. These differences are among the prominent manifestations of right ventricular electrical heterogeneity, and may form an important ionic basis and prerequisite for some malignant arrhythmias in the right ventricle, including those arising from Brugada syndrome and other diseases.展开更多
文摘Heart failure is common in older people and its prevalence is increasing.The Heart 'omics' in AGEing(HOMAGE) project aims to provide a biomarker approach that will improve the early diagnosis of heart failure.A large clinical database,based on(1) prospective population studies or(2) cross-sectional,prospective studies or randomized controlled trials(RCTs) of patients at risk for or with overt cardiovascular disease will be constructed to determine most promising 'omics'-based biomarkers to identify the risk of developing heart failure and/or comorbidities.Population studies,patient cohorts and RCTs are eligible for inclusion in the common database,if they received ethical approval to obtain and share data and have baseline information on cardiovascular risk factors.Currently,the HOMAGE database includes 43,065 subjects,from 20 studies in eight European countries,including healthy subjects from three population studies in France,Belgium and Italy(n = 7,124),patients with heart failure(n = 4,312) from four cohorts in the UK,Spain and Switzerland and patients at high risk for cardiovascular disease(n = 31,629) in 13 cohorts.It is anticipated that more partners will join the consortium and enlarge the pooled data.This large merged database will be a useful resource with which to identify candidate biomarkers that play a role in the mechanism underlying the onset and progression of heart failure.
基金This work was supported by a grant from the Natural Science Foundation of China (No. 30371374).
文摘Background The myocardial ATP sensitive potassium channel (KATP channel) has been known for more than two decades, the properties of this channel have been intensively investigated, especially the myocardial protection effect by opening this channel. Numerous studies, including hypothermic, using KATP agonists to achieve a hyperpolarizing cardioplegic arrest, have shown a better myocardial protection than potassium arrest. However, there is no evidence showing that KATP channel could be opened by its agonists under profound hypothermia. We investigated the effect of temperature on activation of myocardial KATP channel by nicorandil.Methods Isolated ventricular myocytes were obtained by collagenase digestion of the hearts of guinea pigs and stored in KB solution at 4℃. With a steady ground current, the myocytes were perfused with 1 mmol/L nicorandil until a steady IKATP occurred. Then the cells were perfused with 1 mmol/L nicorandil plus 1 μmol/L glybenclamide. Currents signals were recorded on whole cells using patch clamp technique at several temperatures. The temperature of the bath solution around myocytes was monitored and was controlled at 4℃, 10℃, 20℃, 25℃ and 35℃ respectively. About 10 cells were tested at each temperature, the cells were considered useful only when the outward current could be induced by nicorandil and blocked by glybenclamide. All data were analyzed using Graphpad PRISM 3.0 (Graphpad, San Diego, CA, USA). Nonlinear curve fitting was done in Clampfit (Axon) or Sigmaplot (SPSS).Results At 4℃, 10℃, 20℃, 25℃ and 35℃, the time needed to open the myocardial KATP channel was (81.0±0) minutes, (50.54±11.7) minutes, (28.84±2.3) minutes, (9.4± 10.2) minutes and (2.3± 1.0) minutes respectively (P=0.003). The linear relationship between temperature and time needed to open the channel was y (min) = (4348.790±124.277x)/60, where y (min) is time needed to open KATP channel, x is temperature, correlation coefficient r =-0.942 (P=0.00), regression coefficient b =-124.277 (P=0.00). The current densities among different temperatures were statistically different (P=0.022), the current density was greater after the activation of KATP channel at higher temperatures. The lower the temperature, the fewer cells in which KATP channels could be opened. At 4℃, only one cell in which the KATP channel could be opened, took a quite long time (81 minutes)and the Ⅰ-Ⅴ curve was quite untypical.Conclusions KATP channel activated by nicorandil is temperature dependent and the temperature linearly related to time needed to open KATP channel; the lower the temperature, the longer the time needed to open channel and the smaller the current density. At profound hypothermia, it is difficult to activate KATP channels.
文摘Background Some studies have confirmed that the right ventricular walls of most rodents, such as canines and humans, have evident transient outward potassium current (I to1) heterogeneity, and this heterogeneity is closely related to J point elevation, J wave formation, and some ventricular tachycardias such as ventricular fibrillations caused by Brugada syndrome. This study is designed to investigate transmural electrical heterogeneity of the canine right ventricle during repolarization (phase 1) from the viewpoint of 4-aminopyridine sensitive and calcium-independent I to1. Methods Adult canine single right ventricular epicardial (Epi) cells, mid-myocardial (M) cells, and endocardial (Endo) cells were enzymatically dissociated. Whole cell voltage-clamp recordings were made to compare the I to1 values of the three cell types. Results At 37℃ and using 0.2 Hz and +70 mV depolarizing test potentials, the average peak I to1 values of Epi cells and M cells averaged (4070±1720) pA and (3540±1840) pA, respectively. The activated and inactivated Epi and M cells kinetic processes were in accordance with the Boltzmann distribution. Compared with I to1 in Epi cells and M cells, the average peak I to1 in Endo cells was very low, averaged (470±130) pA. Conclusions These results suggest that there are evident differences and potent gradients in I to1 between the three cardiac cell types, especially between Epi and Endo cells. These differences are among the prominent manifestations of right ventricular electrical heterogeneity, and may form an important ionic basis and prerequisite for some malignant arrhythmias in the right ventricle, including those arising from Brugada syndrome and other diseases.