Objective: To investigate the underlying metabolomic profiling of coronary heart disease(CHD) with blood stasis syndrome(BSS). Methods: CHD model was induced by a nameroid constrictor in Chinese miniature swine....Objective: To investigate the underlying metabolomic profiling of coronary heart disease(CHD) with blood stasis syndrome(BSS). Methods: CHD model was induced by a nameroid constrictor in Chinese miniature swine. Fifteen miniature swine were randomly divided into a model group(n=9) and a control group(n=6), respectively according to arandom number table. After 4 weeks, plasma hemorheology was detected by automatic hemorheological analyzer, indices including hematocrit, plasma viscosity, blood viscosity, rigidity index and erythrocyte sedimentation rate; cardiac function was assessed by echocardiograph to detect left ventricular end-systolic diameter(LVED), left ventricular end-diastolic diameter(LVEDd), ejection fraction(EF), fractional shortening(FS) and other indicators. Gas chromatography coupled with mass spectrometry(GC-MS) and bioinformatics were applied to analyze spectra of CHD plasma with BSS. Results: The results of hemorheology analysis showed significant changes in viscosity, with low shear whole blood viscosity being lower and plasma viscosity higher in the model group compared with the control group. Moreover, whole blood reduction viscosity at high shear rate and whole blood reduction viscosity at low shear rate increased significantly(P〈0.05). The echocardiograph results demonstrated that cardiac EF and FS showed significant difference(P〈0.05), with EF values being decreased to 50% or less. The GC-MS data showed that principal component analysis can clearly separate the animals with BSS from those in the control group. The enriched Kyoto Encyclopedia of Genes and Genomes biological pathways results suggested that the patterns involved were associated with dysfunction of energy metabolism including glucose and lipid disorders, especially in glycolysis/gluconeogenesis, galactose metabolism and adenosine-triphosphate-binding cassette transporters. Conclusion: Glucose metabolism and lipid metabolism disorders were the major contributors to the syndrome classification of CHD with BSS.展开更多
基金Supported by the National Natural Science Foundation of China(Nos.81202788,81473456,81470191 and 81302908)the National Science and Technology Pillar Program(No.2012BAI29B07)+1 种基金Beijing Natural Science Foundation(No.7142099)Excellent Young Scientist Foundation of Beijing University of Chinese Medicine(No.2015-JYB-XYQ001)
文摘Objective: To investigate the underlying metabolomic profiling of coronary heart disease(CHD) with blood stasis syndrome(BSS). Methods: CHD model was induced by a nameroid constrictor in Chinese miniature swine. Fifteen miniature swine were randomly divided into a model group(n=9) and a control group(n=6), respectively according to arandom number table. After 4 weeks, plasma hemorheology was detected by automatic hemorheological analyzer, indices including hematocrit, plasma viscosity, blood viscosity, rigidity index and erythrocyte sedimentation rate; cardiac function was assessed by echocardiograph to detect left ventricular end-systolic diameter(LVED), left ventricular end-diastolic diameter(LVEDd), ejection fraction(EF), fractional shortening(FS) and other indicators. Gas chromatography coupled with mass spectrometry(GC-MS) and bioinformatics were applied to analyze spectra of CHD plasma with BSS. Results: The results of hemorheology analysis showed significant changes in viscosity, with low shear whole blood viscosity being lower and plasma viscosity higher in the model group compared with the control group. Moreover, whole blood reduction viscosity at high shear rate and whole blood reduction viscosity at low shear rate increased significantly(P〈0.05). The echocardiograph results demonstrated that cardiac EF and FS showed significant difference(P〈0.05), with EF values being decreased to 50% or less. The GC-MS data showed that principal component analysis can clearly separate the animals with BSS from those in the control group. The enriched Kyoto Encyclopedia of Genes and Genomes biological pathways results suggested that the patterns involved were associated with dysfunction of energy metabolism including glucose and lipid disorders, especially in glycolysis/gluconeogenesis, galactose metabolism and adenosine-triphosphate-binding cassette transporters. Conclusion: Glucose metabolism and lipid metabolism disorders were the major contributors to the syndrome classification of CHD with BSS.
