Introduction: Few data described practicalities of using mechanical insufflation-exsufflation (MI-E) for invasively ventilated ICU patients and evidence for benefit of their use is lacking.Aim and objective: To identify barriers and facilitators to use MI-E devices in invasively ventilated ICU patients, and to explore reasons for their use in various patient indications.Methods: Four focus group discussions; 3 national (Netherlands) and 1 with international representation, each with a purposeful interprofessional sample of a maximum 10 participants with experience in using MI-E in invasively ventilated ICU patients. We developed a semi-structured interview guide informed by the Theoretical Domain Framework. An observer was present in each session. Sessions were audio recorded and transcribed verbatim. Data were analysed using content analysis.Results: Barriers for MI-E use were lack of evidence and lack of expertise in MI-E, as well as lack of device availability within the ICU. Facilitators were experience with MI-E and perceived clinical improvement in patients with MI-E use. Common reasons to start using MI-E were difficult weaning, recurrent atelectasis and pneumonia. Main contraindications were, bullous emphysema, ARDS, high PEEP, hemodynamic instability, recent pneumothorax. There was substantial variability on used technical settings of MI-E in invasively ventilated patients.Conclusions: Key barriers and facilitators to MI-E were lack of evidence, available expertise and perceived clinical improvement. Variability on technical settings likely reflect lack of evidence. Future studies should focus on settings, safety and feasibility of MI-E in invasively ventilated patients before studies on effect can be conducted.
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Atherosclerosis is the development of lipid-laden plaques in arteries and is nowadays considered as an inflammatory disease. It has been shown that high doses of ionizing radiation, as used in radiotherapy, can increase the risk of development or progression of atherosclerosis. To elucidate the effects of radiation on atherosclerosis, we propose a mathematical model to describe radiation-promoted plaque evelopment. This model distinguishes itself from other models by combining plaque initiation and plaque growth, and by incorporating information from biological experiments. It is based on two consecutive processes: a probabilistic dose-dependent plaque initiation process, followed by deterministic plaque growth.
