Objective To detect the bile acid profile in serum based on liquid chromatography-tandem mass spectrometry, and construct a combined biomarker diagnostic model for differentiating acute myocardial infarction (AMI) from unstable angina (UA). Methods A total of 180 patients with acute coronary syndrome who visited Huludao Central Hospital between August 2023 and February 2024 were randomly selected, and there were 117 patients with UA and 63 patients with AMI. Using liquid chromatography-tandem mass spectrometry, 15 bile acid subtypes in serum were detected. Orthogonal partial least squares discriminant analysis was used to compare the serum bile acid metabolic profiles of the subjects. Differences in metabolites were screened based on a significance level of P<0.05 and variable importance in projection (VIP)>1. Multiple logistic regression analysis was performed to construct a diagnostic model for differentiating AMI from UA, and the diagnostic performance of the model was evaluated using receiver operating characteristic (ROC) curve and other statistical methods. Results The differential bile acid biomarkers in the serum of UA and AMI patients included glycodeoxycholic acid, glycochenodeoxycholic acid (GCDCA), deoxycholic acid (DCA), glycocholic acid, and aurodeoxycholic acid (TDCA) (P<0.05, VIP>1). A binary logistic stepwise regression analysis showed that three bile acid biomarkers (GCDCA, DCA, and TDCA) and three common biochemical indicators (aspartate aminotransferase, creatine kinase, and total bile acid) were factors differentiating AMI from UA (P<0.05). The area under the ROC curve of the model was 0.986 [95% confidence interval (0.973, 0.999), P<0.001], demonstrating a good diagnostic performance. Conclusions GCDCA, DCA, and TDCA can serve as potential biomarkers for distinguishing AMI from UA. The model combining these three bile acids with aspartate aminotransferase, creatine kinase, and total bile acid can effectively identify AMI.
Objective To report an acute ischemic left ventricular heart failure model of safe, simple, relatively steady, and reproducible in sheep. Methods Fourteen female sheep with a body weight of 36.80±3.43kg were used in this study. Heart failure model was induced by partial occluding the middle left circumflex coronary artery (LCX) combined with pacemaker-induced tachycardia. Hemodynamic measurement was done before and after heart failure, myocardial examination was observed. Results Heart failure model was induced successfully in 10 sheep. Cardiac output dropped from 3.74±0.48L/min to 2.02±0. 51L/min (P〈0. 01), mean arterial pressure decreased from 116. 10± 14.15 mmHg(1kPa = 7.5mmHg) to 68. 10± 14. 72mmHg (P〈0.01), central venous pressure rose from 7. 10±2.18mmHg to 10. 70± 3.50 mmHg (P〈0.05), right ventricular end-diastolic pressure increased from 6.10±3.57mmHg to 9.90±4.41mmHg(P〈0.05), left atrial pressure increased from 8.10±2.13 mmHg to 12.00± 4.57mmHg (P〈0. 01 ), and left ventricular end-diastolic pressure increased from 8. 50± 4. 17mmHg to 13.10± 10. 64mmHg(P〉 0. 05). The myocardial ultrastructure injuries was marked. Conclusions Acute ischemic left ventricular heart failure could be induced by partial occlusion of the middle LCX combined with pacemaker-induced taehyeardia in sheep. This model is simple, easy to manipulate, relatively steady, and reproducible . It may be used for assessing cardiac assist devices.
Mesenchymal stem cells(MSCs)is a kind of non hematopoietic stem cell from the mesoderm, which can self renew, proliferate and perform multilineage differentiation. Due to the characteristics of acquiring easily and low immunogenicity, it has become the main cell for myocardial infarction. In this article, the biology and the immunology of the MSCs is reviewed, the safety and the validity of the therapy on myocardial infarction with MSCs and the HGF/MSCs is introduced. And furthermore, it also explains the possible mechanism and the problems of how to improve the cardial function.
Abstract: Ventricular septal rupture is a rare complication of acute myocardial infarction, but it can easily lead to such complications as acute heart failure and cardiac shock with sinister prognosis. Surgical treatment is a fundamental measure to improve the prognosis, and the selection of operation time is a key factor. The basic guiding principles of operation timing are as follows. Those patients who have acute heart failure and/or cardiac shock soon after the onset of ventricular septal rupture, and can not be controlled by nonsurgery therapy and are also unable to tolerate surgery, will die soon. For them, surgery treatment cannot be implemented because they have missed the optimal operation time. For those whose perforation was so small that they can be stably controlled by nonsurgery therapy, surgery treatment can be postponed for 1 to 4 weeks. However, emergency operation should be performed in time once the condition of the patients becomes unstable. For others, no matter in what state they are, surgical treatment should be implemented immediately.
Abstract: Objective To observe the changes in morphology, structure, and ventricular function of infarct heart after bone marrow mononuclear cells (BMMNC) implantation. Methods Twenty-four dogs were divided into four groups with random number table, acute myocardial infarction (AM I) control group , AM I-BMMNC group , old myocardial infarct ion (OMI) control group and OM I-BMMNC group , 6 dogs each group. Autologous BMMNC were injected into infarct and peri-infarct myocardium fo r transplantation in AM I-BMMNC group and OM I-BMMNC group. The same volume of no-cells phosphate buffered solution (PBS) was injected into the myocardium in AM Icontrol group and OM I-control group. Before and at six weeks of cell t ransplantation, ult rasonic cardiography (UCG) were performed to observe the change of heart morphology and function, then the heart was harvested for morphological and histological study. Results U CG showed that left ventricular end diastolic dimension (LV EDD) , left ventricular end diastolic volume (LVEDV ) , the thickness of left ventricular postwall (LVPW ) in AM I-BMMNC group were significantly less than those in AM I-control group (32. 5±5. 1mm vs. 36. 6±3. 4mm , 46. 7±12. 1m l vs. 57. 5±10. 1m l, 6. 2±0. 6mm vs. 6. 9±0. 9mm; P lt; 0. 05). LVEDD, LVEDV , LVPW in OM I-BMMNC group were significantly less than those in OM I-control group (32. 8±4. 2 mm vs. 36. 8±4. 4mm , 48. 2±12. 9m l vs. 60.6±16.5m l, 7. 0±0. 4mm vs. 7. 3±0. 5mm; P lt; 0. 05). The value of eject fraction (EF) in OM I-BMMNC group were significantly higher than that in OM I-control group (53. 3% ±10. 3% vs. 44. 7%±10. 1% ). Compared with their control group in morphological measurement, the increase of infarct region thickness (7. 0 ± 1. 9mm vs. 5. 0 ±2.0mm , 6.0±0. 6mm vs. 4. 0±0. 5mm; P lt; 0. 05) and the reduction of infarct region length (25. 5±5. 2mm vs. 32. 1±612mm , 33. 6±5. 5mm vs. 39. 0±3. 2mm , P lt; 0. 05) were observed after transplantation in AM I-BMMNC group and OM I-BMMNC group, no ventricular aneurysm was found in AM I-BMMNC group, and the ratio between long axis and minor axis circumference of left ventricle increased in OM I-BMMNC group (0. 581±0. 013 vs. 0. 566±0.015; P lt; 0. 05). Both in AM I-BMMNC group and OM I-BMMNC group, fluorescence expressed in transplantation region was observed, the morphology of most nuclei with fluorescencew as irregular, and the differentiated cardiocyte with fluorescence was not found in myocardium after transplantation. The histological examination showed more neovascularization after transp lantation both in AMI and in OM I, and significant lymphocyte infiltration in AM I-BMMNC group. Conclusion BMMNC implantation into infarct myocardium both in AMI and OMI have a beneficial effect, which can attenuate deleterious ventricular remodeling in morphology and st ructure, and improve neovascularization in histology, and improve the heart function.
Abstract: Objective To evaluate the treatment efficacy of post-infarction left ventricular pseudo-aneurysm (LVPA) through surgical procedure, and explore the diagnosis and differential diagnosis details of LVPA. Methods Between May 1993 and July 2007, 7 cases were diagnosed through echocardiography aided with left ventriculography or multi-sliced computer tomography (MSCT) or magnetic resonance imaging (MRI); 6 cases with LVPA were surgically treated through different procedure that included direct closure, cut and patching or cut and sandwiching procedure choose according to its location, anatomical morphology, and comorbidity; accompanied diseases were treated by coronary artery bypass grafting(CABG) procedure. Results Six cases were diagnosed before surgery, and 1 case was diagnosed during the surgical procedure. One died from the cardiac tamponade due to rupture of LVPA before the surgical procedure, so the inhospital mortality was 14.3%(1/7). There was no operative death. With the follow-up from 2 months to 13 years of the 6 operational survivors, 1 case died from cardiac rupture and pericardial tamponade 4 years after the repair procedure. Of the 5 surviving LVPA, the left ventricular ejection fraction(LVEF) values were from 43% to 52%, and 3 cases were in New York Heart Association (NYHA) class Ⅰ, and 2 cases were in NYHA class Ⅱ. Conclusion Echocardiography, aided with left ventriculography or MSCT or MRI, is an effective measure for diagnosis of LVPA. Surgical procedure is an effective measure to treat LVPA,but different surgical procedures, accompanied with homeochronous CABG procedure,should be adopted to deal with LVPA according its location, anatomical morphology, and accompanied deformity. The perioperative and mid-long term efficacy were good for the surgical treatment of LVPA, but it is imperative to pay attention to prevention of the recurrence and the late rupture of repaired LVPA.
Inferior myocardial infarction is an acute ischemic heart disease with high mortality, which is easy to induce life-threatening complications such as arrhythmia, heart failure and cardiogenic shock. Therefore, it is of great clinical value to carry out accurate and efficient early diagnosis of inferior myocardial infarction. Electrocardiogram is the most sensitive means for early diagnosis of inferior myocardial infarction. This paper proposes a method for detecting inferior myocardial infarction based on densely connected convolutional neural network. The method uses the original electrocardiogram (ECG) signals of serially connected Ⅱ, Ⅲ and aVF leads as the input of the model and extracts the robust features of the ECG signals by using the scale invariance of the convolutional layers. The characteristic transmission of ECG signals is enhanced by the dense connectivity between different layers, so that the network can automatically learn the effective features with strong robustness and high recognition, so as to achieve accurate detection of inferior myocardial infarction. The Physikalisch Technische Bundesanstalt diagnosis public ECG database was used for verification. The accuracy, sensitivity and specificity of the model reached 99.95%, 100% and 99.90%, respectively. The accuracy, sensitivity and specificity of the model are also over 99% even though the noise exists. Based on the results of this study, it is expected that the method can be introduced in the clinical environment to help doctors quickly diagnose inferior myocardial infarction in the future.