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Hälsa & medicin 6.2 🇸🇪

New test spots heart disease without catheterization

Researchers have developed a non-invasive way to detect abnormal heart function by analyzing pressure and volume changes during stress tests. The method could transform how doctors screen for cardiomyopathy and heart failure, reducing need for invasive procedures and accelerating diagnosis in routine clinical settings.

Originaltitel: Non-invasive pressure-volume loop analysis in left ventricular load manipulation.

TL;DR — på svenska

Kardiomagnetisk resonans kan nu användas för att bedöma hjärtats hemodynamiska svar på förändrade belastningsförhållanden utan invasiv katetrisering. Forskargruppen från Lunds universitet och samarbetsinstitutioner testade denna non-invasiv metod på 46 deltagare — 24 friska kontroller, 14 patienter med hypertrofisk kardiomyopati och 8 volontärer. Vid saltvatteninfusion skilde sig kontrollgruppen från HCM-patienterna: endast kontroller visade minskad arteriell elastans och förändrad ventrikulär-arteriell koppling. Vid nitratkörning var responsen mindre uttalad. Metoden detekterar således mekanistiska skillnader mellan hälsa och sjukdom. För inköpschefer och kardiologiska enheter betyder detta en väg framåt för funktionell hjärtövervakning utan kateter — relevant för riskstratifiering av kardiomyopati-patienter och tillval av terapeutiska interventioner baserat på individuell hemodynamik.

Abstrakt

BACKGROUND: Clinical monitoring of patients with heart failure or cardiomyopathy is facilitated by detailed assessment of cardiac loading conditions. Specifically, alterations in preload and afterload may unmask pathology through effects on ventricular pressure-volume (PV) relations. Therefore, the aim was to assess non-invasive PV loops during left ventricular load manipulation in healthy participants and in patients with hypertrophic cardiomyopathy (HCM). METHODS: In total, n = 46 participants were studied in paired experiments at baseline and during load manipulation. Controls (n = 24) and patients with HCM (n = 14) were assessed at baseline and during intravenous infusion of 1.5-2 L isotonic saline, and another group of volunteers (n = 8) was assessed at baseline and during infusion of glyceryl trinitrate (GTN). Non-invasive PV loops were calculated from cardiovascular magnetic resonance (CMR) and concurrent brachial blood-pressure measurements. RESULTS: Saline infusion brought about increased end-diastolic and decreased end-systolic volumes in controls, but not in HCM. Concurrently, PV loops revealed mechanistic differences, where controls but not HCM exhibited decreased arterial elastance and potential energy during load manipulation. In both groups, ventricular-arterial coupling (VAC) decreased, and ventricular efficiency and cardiac output increased. Infusion of GTN resulted in decreased ventricular volumes. Contrary to saline infusion, volunteers receiving GTN retained unchanged arterial elastance, VAC, ventricular efficiency and cardiac output. CONCLUSION: Non-invasive PV analysis from CMR detects cardiac response to altered loading conditions in healthy participants and in patients with HCM. Our findings support the use of CMR-derived PV loops for detailed assessment of cardiac thermodynamic performance in relation to interventions affecting preload and afterload.

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