Non-invasive monitoring of central blood pressure by electrical impedance tomography: first experimental evidence
There is a strong clinical demand for devices allowing continuous non-invasive monitoring of central blood pressure (BP). In the state of the art a new family of techniques providing BP surrogates based on the measurement of the so-called pulse wave velocity (PWV) has been proposed, eliminating the need for inflation cuffs. PWV is defined as the velocity at which pressure pulses propagate along the arterial wall. However, no technique to assess PWV within central arteries in a fully unsupervised manner has been proposed so far. In this pilot study, we provide first experimental evidence that electrical impedance tomography (EIT) is capable of measuring pressure pulses directly within the descending aorta. To obtain a wide range of BP values, we administrated noradrenalin and nitroglycerine to an anesthetized pig under mechanical ventilation. An arterial line was inserted into the ascending aorta for measuring reference BP. EIT images were generated from 32 impedance electrodes placed around the chest at the level of the axilla. Regions of Interest (ROI) such as the descending aorta and the lungs were automatically identified by a novel time-based processing algorithm as the respective EIT pixels representing these structures. The correct positions of these ROIs were confirmed by bolus injections of highly conductive concentrated saline into the right heart and into the ascending aorta. Aortic pulse transit time (PTT) values were determined as the delay between the opening of the aortic valve (obtained from arterial line) and the arrival of pressure pulses at the aortic ROI within the EIT plane. For 11 experimental conditions, with mean BP ranging from 73 to 141 mmHg, strongly significant correlation (r = −0.97, P < 0.00001) between central BP and aortic PTT was observed, suggesting that EIT-derived aortic PTT is a potential non-invasive surrogate of central BP.
KeywordsBlood pressure Electrical impedance tomography Non invasive Monitoring Pulse wave velocity Pulse transit time Aorta Saline bolus Ambulatory
- 3.Holder DS (2005) Electrical impedance tomography: methods, history and applications. In: Holder D (ed) Medical physics and biomedical engineering. Institute of Physics Publishing, BristolGoogle Scholar
- 4.Hurwitz BE, Shyu LY, Reddy SP, Schneiderman N, Nagel JH (1990) Coherent ensemble averaging techniques for impedance cardiography. In: Proceedings of the third annual IEEE symposium on computer-based medical systems, Chapel HillGoogle Scholar
- 6.Nichols WW, O’Rourke MF (2005) McDonald’s blood flow in arteries. Hodder Arnold, LondonGoogle Scholar
- 10.Solà J, Rimoldi SF, Allemann Y (2010) Ambulatory monitoring of the cardiovascular system: the role of pulse wave velocity. In: Campolo D (ed) New developments in biomedical engineering. I-Tech Education and Publishing, ViennaGoogle Scholar