Heart failure syndrome and predicting response to cardiac resynchronisation therapy.

Heart failure results from the heart pumping insufficient quantities of blood to meet the body’s metabolic requirements. This condition affects around 600,000 people in the United Kingdom and carries with it a significant morbidity and mortality. Patients typically complain of reduced exercise capacity and a poor quality of life. Whilst there are various pharmaceutical options available to clinicians, none directly augment cardiac function. Cardiac resynchronisation therapy (CRT) is proven to reverse the progression of left ventricular systolic dysfunction, the most common cause of heart failure. The device resynchronises inefficient cardiac function, reducing symptoms and improving stroke volume and life expectancy. However, only two thirds of patients typically derive benefit from this pacemaker, it being unclear why. Finding a sensitive and specific predictor of response would be invaluable, preventing potential harm to patients, reducing waste and targeting the patient groups who will derive benefit. In this body of work, the heart failure syndrome is delineated; the evidence underpinning CRT discussed and the difficulties in defining response outlined. There are 2 main research themes in this body of work, measuring and predicting response to CRT. In the former, the role of patient specific three-­‐dimensional computational models and biophysical properties are investigated, and, in the latter, the influence of CRT on the heart failure syndrome using biomarkers. It is concluded that CRT response can be predicted using patient specific computational models of the left ventricle, but they are too complex for routine clinical use. Biophysical markers have more merit in the immediate future, being simper and quicker, with measures of endothelial and skeletal muscle function, demonstrating promise in a small cohort of patients. Finally, there exists a significant level of undiagnosed pathology in this patient group, such as hyperuricaemia and hyperparathyroidism, but it remains unclear what impact CRT has on this comorbidity

Use of a comprehensive numerical model to improve biventricular pacemaker temporization in patients affected by heart failure undergoing to CRT-D therapy

Cardiac resynchronization therapy by biventricular pacemaker/ICD implantation is a validated therapy for patients affected by heart failure with asynchrony of ventricular contraction. Considering the large number of parameters which play a role in cardiac resynchronization therapy, a comprehensive numerical model of cardiocirculatory system could be a useful tool to support clinical decisions. A variable elastance model of ventricles was updated to model the interventricular septum and to simulate the interventricular and the intraventricular desynchrony, and the effect of the biventricular stimulation. In addition, a numerical model of the biventricular pacemaker, which drives the beginning of the heart chambers and interventricular septum contraction, was also developed. In order to validate the model, five patients affected by dilated cardiomyopathy were analysed by echocardiography and electrocardiography before implantation, 24 h and 3 months after the implantation. The developed numerical model permits to reproduce clinical data and to estimate the trend of parameters that are difficult to measure (i.e. left ventricular systolic elastance). Furthermore, the model permits to study the effect of different biventricular pacemaker temporizations on hemodynamic variables

Medical-Data-Models.org:A collection of freely available forms (September 2016)

MDM-Portal (Medical Data-Models) is a meta-data repository for creating, analysing, sharing and reusing medical forms, developed by the Institute of Medical Informatics, University of Muenster in Germany. Electronic forms for documentation of patient data are an integral part within the workflow of physicians. A huge amount of data is collected either through routine documentation forms (EHRs) for electronic health records or as case report forms (CRFs) for clinical trials. This raises major scientific challenges for health care, since different health information systems are not necessarily compatible with each other and thus information exchange of structured data is hampered. Software vendors provide a variety of individual documentation forms according to their standard contracts, which function as isolated applications. Furthermore, free availability of those forms is rarely the case. Currently less than 5 % of medical forms are freely accessible. Based on this lack of transparency harmonization of data models in health care is extremely cumbersome, thus work and know-how of completed clinical trials and routine documentation in hospitals are hard to be re-used. The MDM-Portal serves as an infrastructure for academic (non-commercial) medical research to contribute a solution to this problem. It already contains more than 4,000 system-independent forms (CDISC ODM Format, www.cdisc.org, Operational Data Model) with more than 380,000 dataelements. This enables researchers to view, discuss, download and export forms in most common technical formats such as PDF, CSV, Excel, SQL, SPSS, R, etc. A growing user community will lead to a growing database of medical forms. In this matter, we would like to encourage all medical researchers to register and add forms and discuss existing forms