Zone-wise occupancy schedules developed using Time Use Survey data for building energy performance simulations.

The occupancy profile dataset presented in this study leverages publicly available UK Time Use Survey (TUS) 2014-15 data to evaluate the impact of occupancy on energy consumption at various spatial and temporal scales using multi-scale archetypes. Constructing this occupancy dataset includes conversion, categorisation, extraction and analysis processes. The resulting dataset (in .csv) format represents realistic day-wise zone-level occupancy availability schedules that account for the effect of the type of dwelling, the number of occupants, the month of the year and the day of the week. A total of 5,376 occupancy profiles were extracted, representing a large number of dwellings. These profiles demonstrate the realistic behaviour of occupants' availability in dwellings. These profiles allow us to gain valuable insights into the energy usage patterns in dwellings based on the realistic behaviour of occupants, leading to more accurate and context-specific energy assessments.

Effect of nebuliser and patient interface type on fugitive medical aerosol emissions in adult and paediatric patients.

BACKGROUND: Open circuit aerosol therapy is associated with the potential for fugitive emissions of medical aerosol. Various nebulisers and interfaces are used in respiratory treatments, including the recent consideration of filtered interfaces. This study aims to quantify fugitive medical aerosols from various nebuliser types, in conjunction with different filtered and non-filtered interfaces. METHODS: For both simulated adult and paediatric breathing, four nebuliser types were assessed including; a small volume jet nebuliser (SVN), a breath enhanced jet nebuliser (BEN), a breath actuated jet nebuliser (BAN) and a vibrating mesh nebuliser (VMN). A combination of different interfaces were used including filtered and unfiltered mouthpieces, as well as open, valved and filtered facemasks. Aerosol mass concentrations were measured using an Aerodynamic Particle Sizer at 0.8 m and 2.0 m. Additionally, inhaled dose was assessed. RESULTS: Highest mass concentrations recorded were 214 (177, 262) µg m-3 at 0.8 m over 45-minute run. The highest and lowest fugitive emissions were observed for the adult SVN facemask combination, and the adult BAN filtered mouthpiece combination respectively. Fugitive emissions decreased when using breath-actuated (BA) mode compared to continuous (CN) mode on the BAN for the adult and paediatric mouthpiece combination. Lower fugitive emissions were observed when a filtered facemask or mouthpiece was used, compared to unfiltered scenarios. For the simulated adult, highest and lowest inhaled dose were 45.1 (42.6, 45.6)% and 11.0 (10.1,11.9)% for the VMN and SVN respectively. For the simulated paediatric, highest and lowest inhaled dose were 44.0 (42.4, 44.8)% and 6.1 (5.9, 7.0)% for the VMN and BAN CN respectively. Potential inhalation exposure of albuterol was calculated to be up to 0.11 µg and 0.12 µg for a bystander and healthcare worker respectively. CONCLUSION: This work demonstrates the need for filtered interfaces in clinical and homecare settings to minimise fugitive emissions and to reduce the risk of secondary exposure to care givers.

In vitro model for investigating aerosol dispersion in a simulated COVID-19 patient during high-flow nasal cannula treatment.

The use of high-flow nasal cannula in the treatment of COVID-19 infected patients has proven to be a valuable treatment option to improve oxygenation. Early in the pandemic, there were concerns for the degree of risk of disease transmission to health care workers utilizing these treatments that are considered aerosol generating procedures. This study developed an in vitro model to examine the release of simulated patient-derived bioaerosol with and without high-flow nasal cannula at gas flow rates of 30 and 50 L/min. Aerosol dispersion was evaluated at 30 and 90 cm distances. Reduction of transmission risk was assessed using a surgical facemask on the manikin. Results indicated that the use of a facemask facilitated a 94-95% reduction in exhaled aerosol concentration at 30 cm and 22-60% reduction for 90 cm distance across both gas flow rates. This bench study confirms that this in vitro model can be used as a tool to assess the risk of disease transmission during aerosol generating procedures in a simulated patient and to test factors to mitigate the risk.

Fugitive aerosols in the intensive care unit: a narrative review.

The risk of unintended inhalation of fugitive aerosols is becoming a topic of increasing interest in the healthcare arena. These fugitive aerosols may be bioaerosols, generated by the patient themselves through cough or sneeze, or they may be therapeutic medical aerosols, generated by therapeutic medical aerosol generators with the intent of delivery to a specific patient's respiratory tract. This review focus' on therapeutic aerosols in the intensive care unit (ICU) only, those typically generated by nebulisers. In the intensive care environment, patients are generally in receipt of ventilatory support, and the literature suggests that these different support interventions influence fugitive therapeutic medical aerosol emissions in a variety of ways. Predominant ventilatory support interventions include, but are not limited to, invasive mechanical ventilation (MV), non-invasive mechanical ventilation (NIV), high flow nasal therapy (HFNT), and supplemental oxygen delivery in spontaneously breathing patients. Further, factors such as nebuliser type, patient interface, patient breathing pattern, nebuliser position in the patient breathing circuit and medication formulation characteristics also have been shown to exert influence on aerosol concentrations and distance from the source. Here we present the state of the art knowledge in this, as yet, poorly described field of research, and identify the key risks, and subsequently, opportunities to mitigate the risks of unintended exposure of both patients and bystanders during and for periods following the administration of therapeutic aerosols.

Investigation of Fugitive Aerosols Released into the Environment during High-Flow Therapy.

BACKGROUND: Nebulised medical aerosols are designed to deliver drugs to the lungs to aid in the treatment of respiratory diseases. However, an unintended consequence is the potential for fugitive emissions during patient treatment, which may pose a risk factor in both clinical and homecare settings. METHODS: The current study examined the potential for fugitive emissions, using albuterol sulphate as a tracer aerosol during high-flow therapy. A nasal cannula was connected to a head model or alternatively, a interface was connected to a tracheostomy tube in combination with a simulated adult and paediatric breathing profile. Two aerodynamic particle sizers (APS) recorded time-series aerosol concentrations and size distributions at two different distances relative to the simulated patient. RESULTS: The results showed that the quantity and characteristics of the fugitive emissions were influenced by the interface type, patient type and supplemental gas-flow rate. There was a trend in the adult scenarios; as the flow rate increased, the fugitive emissions and the mass median aerodynamic diameter (MMAD) of the aerosol both decreased. The fugitive emissions were comparable when using the adult breathing profiles for the nasal cannula and tracheostomy interfaces; however, there was a noticeable distinction between the two interfaces when compared for the paediatric breathing profiles. The highest recorded aerosol concentration was 0.370 ± 0.046 mg m-3 from the tracheostomy interface during simulated paediatric breathing with a gas-flow rate of 20 L/min. The averaged MMAD across all combinations ranged from 1.248 to 1.793 µm by the APS at a distance of 0.8 m away from the patient interface. CONCLUSIONS: Overall, the results highlight the potential for secondary inhalation of fugitive emissions released during simulated aerosol treatment with concurrent high-flow therapy. The findings will help in developing policy and best practice for risk mitigation from fugitive emissions.

Investigation of the Quantity of Exhaled Aerosols Released into the Environment during Nebulisation.

BACKGROUND: Secondary inhalation of medical aerosols is a significant occupational hazard in both clinical and homecare settings. Exposure to fugitive emissions generated during aerosol therapy increases the risk of the unnecessary inhalation of medication, as well as toxic side effects. METHODS: This study examines fugitively-emitted aerosol emissions when nebulising albuterol sulphate, as a tracer aerosol, using two commercially available nebulisers in combination with an open or valved facemask or using a mouthpiece with and without a filter on the exhalation port. Each combination was connected to a breathing simulator during simulated adult breathing. The inhaled dose and residual mass were quantified using UV spectrophotometry. Time-varying fugitively-emitted aerosol concentrations and size distributions during nebulisation were recorded using aerodynamic particle sizers at two distances relative to the simulated patient. Different aerosol concentrations and size distributions were observed depending on the interface. RESULTS: Within each nebuliser, the facemask combination had the highest time-averaged fugitively-emitted aerosol concentration, and values up to 0.072 ± 0.001 mg m-3 were recorded. The placement of a filter on the exhalation port of the mouthpiece yielded the lowest recorded concentrations. The mass median aerodynamic diameter of the fugitively-emitted aerosol was recorded as 0.890 ± 0.044 µm, lower the initially generated medical aerosol in the range of 2⁻5 µm. CONCLUSIONS: The results highlight the potential secondary inhalation of exhaled aerosols from commercially available nebuliser facemask/mouthpiece combinations. The results will aid in developing approaches to inform policy and best practices for risk mitigation from fugitive emissions.