Dutch outcome in implantable cardioverter-defibrillator therapy (DO-IT): registry design and baseline characteristics of a prospective observational cohort study to predict appropriate indication for implantable cardioverter-defibrillator

Since September 2014, the DO-IT Registry documents the current nationwide practice of ICD implantation in the primary prevention of SCD with reduced left ventricular function in a setting of structural heart disease. We planned to collect data on demographic, clinical, and ICD characteristics of 1,500 consecutively recruited patients in all 28 ICD implanting centres in the Netherlands. Currently, we are collecting follow-up data up to 24 months after inclusion of the last patient. The inclusion and exclusion criteria are shown in Tab. 1. The inclusion criteria are based on current guidelines (e. g. before 2014) for primary prevention ICD implantation [9, 10]. The LVEF assessment method was at the discretion of the local centre. The registry has been approved by the institutional review boards of all participating hospitals.

Cardiologists, electrophysiologists, biostatisticians and health economists have jointly defined the relevant data set, in view of existing literature on possible predictors for SCD. Electronic case report forms (e-CRFs) were generated using an open source web-based software platform OpenClinica [32] in compliance with good clinical practice. By randomly generating a unique identification number, the anonymity of the patient is maintained. Data of the patient are collected from medical records and entered into the eCRF. All participating sites access the registry via a personal password protected login procedure and can only access the records of the patients of their own centre. We provided the participating centres with a sequential set of instructions for data entry and offered a training, if needed.

We collected baseline data on demographics, medical history and diagnostics, as well as implantation and device data. We collected clinical and ICD follow-up data, based on the normal follow-up of these patients assuming ICD interrogations take place every six months and clinical follow-up is once a year. Every six months, we register occurrence of ventricular arrhythmias and data regarding ICD therapies. ICD therapy is defined as anti-tachycardia pacing (ATP) and defibrillator shocks. During clinical follow-up, medical history, functional status, cardiovascular hospitalisations and performed procedures and diagnostics of the past year are entered into the registry. In addition, the participating hospitals report adverse events, defined as ICD related complications and deaths of any cause. Events such as death, arrhythmias, cardiovascular hospitalisations, cardiac interventions, diagnostic procedures and laboratory parameters between last follow-up visit and death are documented. Medical documentation around the time of death and ICD interrogations are collected, whenever possible. A more detailed list of the collected parameters is provided in the online supplementary material.

Verification rules and edit checks have been built into the system to validate completeness, accuracy and consistency of the dataset. Data quality is also maintained by online and on-site monitoring and continuous assessment of data quality during the export of datasets to statistical packages for subsequent analysis. A monitor plan is used which describes whether outcomes and variables need to be monitored entirely. This decision depends on the expected role of the variable in the prediction models, expected frequency of mistakes and the time needed to monitor the variable. The site investigator is required to maintain adequate records to ensure the manner in which the registry is conducted is well documented. The investigator should keep the records on file for a period of time specified by local law for the preservation of hospital documents. If requested, the investigator supplies the monitor with any required data.

A steering committee, represented by cardiologists of the participating hospitals, is responsible for the scientific integrity and the way that the study is conducted and advises the registry coordinating centre, when needed. A clinical event committee, consisting of independent cardiologists, assesses all ICD delivered therapies by analysing stored electrograms. The committee also determines whether deaths are of cardiac origin.

The incidence for the outcomes of appropriate ICD therapy and death are illustrated by Kaplan-Meier curves. Cox regression models with baseline characteristics of patients are developed to predict the outcomes of death or appropriate ICD therapy over time, considering the competing risk. The risk models will be developed according to the methods that have been used in the paper on the widely accepted ‘MADIT-II risk score’ for primary therapy with an ICD [33]. First, we will develop a model with important baseline characteristics, selected from previous publications on ICD mortality risk stratification and appropriate ICD therapy. We will consider age, gender, body mass index, LVEF, NYHA class, prior (<1-year) heart failure hospitalisation, history of atrial fibrillation and non-sustained VT, renal function, diabetes mellitus, smoking history, pulmonary disease and electrocardiographic parameters. Next, we will identify further factors, such as events during follow-up (complications and appropriate shock), that might improve prediction of the primary outcomes in exploratory analyses. The validity of the resulting predictor sets will be assessed by bootstrapping. A total of 200 bootstrap regression analyses will be performed for internal cross validation. The predictive values of the prediction models will be quantified using c‑statistics.

A cost-minimisation analysis and a budget impact of targeted supply of ICD implantation will be performed. This economic evaluation will compare targeted supply of ICD implantation based on new prediction rules with current practice as reflected in the DO-IT Registry. Targeted supply, however, is not registered; no ICD implantation is withheld from patients who meet the current guidelines. That is why we are not able to observe what would have happened to these patients had they not received an ICD. To circumvent the missing data, the economic evaluation will be conducted as a modelling study, and assuming that not performing unnecessary ICD implantations does not affect health outcomes, only costs, except for temporal implantation related complications. These assumptions are realistic, but depend on the quality of the prediction rules. That is why we will develop prediction rules which can be applied in a way that will minimise the number of false negative predictions. Further details regarding the cost-minimisation and budget impact analysis are provided in the online supplementary material.

Between September 10th, 2014 and May 13th, 2016, 1,619 patients were assessed for eligibility. A flowchart of the study participants is presented in Fig. 1. Sixty-nine patients refused to participate. Data of 1,550 patients were initially entered into the registry. However, 82 patients were excluded because they did not meet the inclusion criteria for various reasons. Although 153 patients did not fully meet the inclusion criteria, we decided that these patients should remain in the registry because they received their ICD in context of primary prevention with a reduced LVEF in a setting of structural heart disease and were assumed to be a clinical relevant subgroup. Therefore, 1,468 patients in total were included in the DO-IT Registry.

The baseline characteristics are presented in Tab. 2. Overall, 1,468 patients received their first ICD (single-chamber or dual-chamber), subcutaneous ICD (S-ICD) or cardiac resynchronisation therapy defibrillator (CRT-D) for primary prevention of SCD (32%, 16%, 9% and 43%, respectively). Seventy-three percent of patients were men and the mean age at implantation was 66 (SD 10) years. The mean LVEF was 26% and more than half of the patients (61%) experienced NYHA class II heart failure symptoms. Most patients, 56%, had ischaemic heart disease. The remaining 641 (44%) patients were considered non-ischaemic.