by King’s College London
Antiarrhythmic and ECG effects of OCT2013 versus lidocaine in rat Langendorff hearts. (a,e) Incidence of ventricular fibrillation (VF), (b,f) heart rate, (c,g) PR and (d,h) QT90 intervals during 30 min of regional ischaemia in hearts perfused with Krebs, OCT2013 or lidocaine. (a–d) Perfusion with test solution started 10 min before coronary ligation (onset of ischaemia), n = 12 hearts per group were required to compare drugs (15 μM each) versus control group. (e–h) Test solution perfusion commenced at 10 min after ligation. A higher concentration of each drug (60 μM) and increased group sizes to n = 20 were implemented in the expectation of weaker drug effects with post-ligation administration. Binomially distributed variables (arrhythmia incidence) were compared using Fisher’s exact test. Gaussian distributed variables (mean ± SEM) were subjected to two-way ANOVA followed by Dunnett’s post hoc tests (following demonstration that F was significant and data Gaussian). *P < 0.05 versus Krebs’ control. Abbreviation, LAD, left anterior descending coronary artery. Credit: DOI: 10.1111/bph.15764
A new drug, OCT2013, was found in animal experiments to prevent lethal arrhythmias and ventricular fibrillation as effectively as lidocaine but without lidocaine’s severe side effects.
The new experiment, led by Dr. Mike Curtis, School of Cardiovascular Medicine & Sciences, used a heart attack model in rats to test the effectiveness of the newly synthesized compound OCT2013.
Many of the 100,000 deaths from heart attacks that happen each year in the UK occur before the ambulance can arrive on the scene. This is due to ischaemia—the heart’s muscle not receiving enough blood due to a block in a coronary artery. This can quickly lead to death from an irregular heartbeat known as ventricular fibrillation (VF).
Though previous research identified drugs that can counteract VF, their side effects meant they failed clinical trials. Lidocaine, for example, has been shown to prevent VF, but it has actions in other parts of the heart and in the nervous system.
Consequently, lidocaine is only administered via an I.V. drip within hospitals and cannot address the pre-hospital deaths associated with ischaemia-induced VF.
Dr. Curtis and his colleagues synthesized OCT2013, a compound with a similar structure to lidocaine. They demonstrated that OCT2013 converts to active lidocaine in an environment with reduced oxygen—in other words, the part of the heart undergoing ischaemia. OCT2013 itself is inactive so it has no effects elsewhere, and therefore no side effects.
The results, published in the British Journal of Pharmacology, found that OCT2013 prevented ischaemia-induced VF in rats, mimicking the effects of lidocaine on the electrical properties of the ischaemic parts of the heart, without mimicking the unwanted effects of lidocaine elsewhere.
Chemical analyses showed that OCT2013 was converted into lidocaine only in the parts of the heart experiencing ischaemia.
“We have invented a new class of drug that has the potential to prevent the sudden death associated with a heart attack,” says Dr. Mike Curtis, School of Cardiovascular Medicine & Sciences.
The researchers hope that OCT2013 could be the basis for a new anti-VF drug that can be prescribed outside of hospital, addressing an important unmet therapeutic need.
Dr. Curtis described the next steps for OCT2013: “We plan to test OCT2013 in a second species (rabbit) then seek funds to initiate testing in humans.”
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