Technological and Patient-tailored Innovations for Maximizing Effectiveness of Cardiac Arrest Resuscitation

Out-of-hospital cardiac arrest (OHCA) annually affects 275000 individuals in Europe. In Italy alone, 50000 persons suffer from OHCA each year and only 9% survives1. Half of the survivors are left with severe brain damage. Prompt cardiopulmonary resuscitation (CPR) and defibrillation before ambulance arrival by bystanders can improve outcomes. However, in many cases, CPR only starts when the ambulance arrives. Additionally, half of all OHCAs occur in isolation, meaning that recognition, emergency calls, and lifesaving maneuvers are delayed. Chest compressions and defibrillation are critical for survival, but they are frequently inadequate or not patient-tailored. Current CPR guidelines recommend a uniform approach to chest compressions and defibrillation for all patients, which fails to account for individual differences. To address these unmet medical needs, we will develop artificial intelligence algorithms, smartphone apps, and novel devices. Starting with proof-of-concept approaches that we have already conceived, we will work to improve recognition of OHCA and provide timely and effective interventions. Our goal is to create tools and technologies that can help reduce the burden of OHCA and improve outcomes.

First, we aim to develop an artificial intelligence algorithm that can predict (minutes, hours, or days in advance) major cardiovascular events, such as myocardial infarction or cardiac arrest. To achieve this, we will collect biosignals recorded by wearables to train and validate the algorithm to identify individuals who are at risk of a major cardiovascular event. Alerted individuals will seek emergency medical care and receive treatments before a cardiac arrest occurs. We also aim to recognize OHCAs that occur in isolation from videos of surveillance cameras.

Second, to increase the rate of CPR and defibrillation provided before ambulance arrival, we will develop a smartphone app that will geolocate and alert nearby citizens to act as first responders. The app will also provide guidance on quickly retrieving a defibrillator.

Third, to determine the optimal compressions and defibrillation position on the chest, we will acquire scans of chest computer tomography and transesophageal echocardiography in elective patients and in victims of cardiac arrest. This will allow to determine optimal compression and defibrillator pads position, understanding the effects on outcomes of different cardiac structures compressed, and developing a modern sensor to estimate the optimal compression and defibrillator pads position on the chest.

Through experimental, simulation and observational studies and a multidisciplinary team of clinicians, researchers and engineers, we will develop the proof-of-concept of such technologies, evaluate their patentability, design an exploitation plan, and test efficacy in preventing and anticipating recognition of OHCA, reducing time to CPR and defibrillation, and offering patient-tailored CPR and defibrillation. Our underlying hypothesis is that developing novel methods and technologies to enhance each link in the chain of survival (preventative measures, early recognition, timely initiation of CPR and defibrillation, and high-quality advanced resuscitation) will significantly anticipate lifesaving treatments and reduce the global mortality and disability caused by OHCA.