Influence of Thoracic Paravertebral Block on Atrioventricular Conduction

Paravertebral blockade (PVB), the injection of local anaesthetic into the paravertebral space located along the vertebral column, temporarily impair the transmission in nerve fibers located in this space. Although PVB is usually used primarily with the intention of achieving block of the thoracic wall pain sensation, the paravertebral space contains not only motoric and sensory nerves, but also autonomic nerve fibers. Achieving the blockade at top four thoracic levels of paravertebral space may affect, among the others, the function of preganglionic sympathetic fibers, forming cardiac nerves, and affecting the heart function in various ways.

The assessment of electrocardiographical phenomena representing the depolarisation of the atria (P wave) and the propagation of the depolarisation by the atrioventricular node and bundle (PQ/PR interval) allows to detect the abnormalities related to proability of occurrence of supraventricular arrythmias and conduction blocks, including the life-threatening arrythmias.

The design of the study assume to retrospective re-analyse the electrocardiographical data achieved in the "Influence of Thoracic Paravertebral Block on Cardiac Repolarization" study (registred in Clinicaltrials.gov under ID NCT05822076), focused changes in heart repolarisation represented mainly by electrocardiographical QT interval and T wave dispersion.

The population of primary investigation was 60 women above 18 years of age scheduled to elective breast surgery in combined regional and general anaesthesia will be enrolled to study, divided in two groups depending of the side of operation. Participants underwent the ultrasound-guided paravertebral block with single injection of 0.5% ropivacaine (0.3 ml·kg-1, not exceeding 30 ml, based on ideal body weight in obese patients) without adjuvants. Before injection (T0) and after confirmation of sufficient sensory block area covering 1st to 4th thoracic dermatomes (T1), 12-lead electrocardiogram (ECG) will be recorded using a Holter device. First examination of sensory block distribution was performed 6 minutes after injection, with subsequent examinations if needed - every minute up to 15 minutes. No sedative premedication, general anaesthesia induction or additional medications (except of neutral saline maintaining intravenous access) were administered until completions of ECG recording. Both T0 and T1 electrocardiogram will be preceded by rest in supine position for at least 5 minutes, without any medical procedures other than monitoring.

As part of the retrospective analysis of ECG recordings obtained from the primary study, repeated measurements will be performed to assess the length of the P wave and the PQ interval at time points T0 and T1, taken as the average of three subsequent heart evolutions and measured separately for each lead. Only cases in which ECG waveform without significant artifact or interferences was obtained in at least 8 leads in both T0 and T1 will be analyzed.

From the obtained values, the P wave dispersion will be calculated (as the difference in the length of the P wave in two leads in which the average time of three evolutions was the longest and the shortest) and the PQ dispersion (as the difference in the length of the PQ interval in two leads in which the average time of three evolutions was the longest and the shortest). The obtained data will be subjected to statistical analysis taking into account the side of the body on which the intervention was performed.