Greenhouse gas emissions associated with suboptimal asthma care in the UK: the SABINA healthCARe-Based envirONmental cost of treatment (CARBON) study.

BACKGROUND: Poorly controlled asthma is associated with increased morbidity and healthcare resource utilisation (HCRU). Therefore, to quantify the environmental impact of asthma care, this retrospective, cohort, healthCARe-Based envirONmental cost of treatment (CARBON) study estimated greenhouse gas (GHG) emissions in the UK associated with the management of well-controlled versus poorly controlled asthma. METHODS: Patients with current asthma (aged ≥12 years) registered with the Clinical Practice Research Datalink (2008‒2019) were included. GHG emissions, measured as carbon dioxide equivalent (CO2e), were estimated for asthma-related medication use, HCRU and exacerbations during follow-up of patients with asthma classified at baseline as well-controlled (<3 short-acting ß2-agonist (SABA) canisters/year and no exacerbations) or poorly controlled (≥3 SABA canisters/year or ≥1 exacerbation). Excess GHG emissions due to suboptimal asthma control included ≥3 SABA canister prescriptions/year, exacerbations and any general practitioner and outpatient visits within 10 days of hospitalisation or an emergency department visit. RESULTS: Of the 236 506 patients analysed, 47.3% had poorly controlled asthma at baseline. Scaled to the national level, the overall carbon footprint of asthma care in the UK was 750 540 tonnes CO2e/year, with poorly controlled asthma contributing excess GHG emissions of 303 874 tonnes CO2e/year, which is equivalent to emissions from >124 000 houses in the UK. Poorly controlled versus well-controlled asthma generated 3.1-fold higher overall and 8.1-fold higher excess per capita carbon footprint, largely SABA-induced, with smaller contributions from HCRU. CONCLUSIONS: These findings suggest that addressing the high burden of poorly controlled asthma, including curbing high SABA use and its associated risk of exacerbations, may significantly alleviate asthma care-related carbon emissions.

Greenhouse Gas Emissions from Respiratory Treatments: Results from the SABA CARBON International Study.

INTRODUCTION: Healthcare systems are looking to reduce their carbon impact. Short-acting ß2-agonist (SABA) overuse (≥ 3 canisters/year) is common in asthma and linked to poor outcomes; however, its environmental impact remains unknown. As part of the CARBON programme, this study retrospectively quantified the carbon footprint of SABA and controller inhalers across all respiratory indications and SABA overuse in asthma in lower-middle-income countries (LMICs), upper-middle-income countries and high-income countries across Africa, Asia Pacific, Latin America and the Middle East. METHODS: Two data sources were utilised to evaluate the carbon contribution of inhalers to respiratory care. To quantify greenhouse gas (GHG) emissions associated with total inhaler use across all respiratory indications, inhaler sales data were obtained from IQVIA MIDAS® (Q4/2018-Q3/2019) and compared by dose to prevent confounding from differences in canister actuation counts. GHG emissions associated with SABA overuse in asthma were evaluated using prescription and self-reported over-the-counter purchase data from the SABA use IN Asthma (SABINA) III study (2019-2020). Inhaler-related GHG emissions were quantified using published data and product life cycle assessments. RESULTS: SABA accounted for > 50% of total inhaler use and inhaler-related emissions in most countries analysed. The total SABA-related emissions were estimated at 2.7 million tonnes carbon dioxide equivalents, accounting for 70% of total inhaler-related emissions. Among the countries, regions and economies analysed, per capita SABA use and associated emissions were higher in Australia, the Middle East and high-income countries. Most SABA prescriptions for asthma (> 90%) were given to patients already overusing SABA. CONCLUSIONS: Globally, SABA use/overuse is widespread and is the greatest contributor to the carbon footprint of respiratory treatment, regardless of the economic status of countries. Implementing evidence-based treatment recommendations, personalising treatment and reducing healthcare inequities, especially in LMICs, may improve disease control and patient outcomes, thereby reducing SABA overuse and associated carbon emissions beyond SABA use alone.

The healthcare sector is a large emitter of greenhouse gases (GHGs); therefore, healthcare systems will need to reduce their carbon footprint to meet their carbon reduction targets. In respiratory care, the environmental impact of controller inhalers has received considerable attention due to the global warming potential of the propellants used in metered-dose inhalers. In contrast, little is known about the contribution made by short-acting ß₂-agonist (SABA) relievers globally, which are often the only inhaled medication used by many patients with milder asthma. The SABA use IN Asthma (SABINA) programme reported that SABA overuse (3 or more SABA canisters/year) is common and associated with an increased risk of asthma attacks. Since all inhalers have a carbon footprint, SABA overuse may result in an avoidable excess carbon footprint. Therefore, to provide a complete picture of the carbon footprint of respiratory care, we examined the contribution of SABA relievers and their potential overuse. The total SABA-related GHG emissions accounted for 70% of total inhaler-related GHG emissions, and > 90% of prescriptions for SABA relievers for asthma were given to patients who were already overusing their SABA. Overall, SABA use/overuse is commonly observed worldwide and is likely a significant contributor to the carbon footprint of respiratory treatment. Therefore, there is an urgent need for healthcare providers to follow the latest international treatment guidelines to reduce high SABA use in respiratory care and improve patient outcomes. This, in turn, will enable healthcare systems to reduce their carbon footprint from both treatment and patient interactions.

Combined Intra-articular and Extra-articular Visualization for Repair of a Complete Subscapularis Tear: The "Blended View" Technique.

Repair of subscapularis tendon tears can be a challenging task, even for an experienced arthroscopist. The complexity results not only from the difficulty in identifying these tears accurately but also because establishing orientation for visualization and repair of this often distorted anatomy can be difficult. Even after a subscapularis tear is identified and mobilized, restoration of the footprint can prove demanding due to the limited view of the subscapularis tendon's lesser tuberosity insertion site, especially from the traditional posterior portal. Such visualization limitations often necessitate switching back and forth between 30° and 70° arthroscopes. A "blended view" technique is used routinely because it offers optimal visualization and access to the subscapularis tendon and the lesser tuberosity during full-thickness subscapularis repair.

Mechanism of action of inhibition of allergic immune responses by a novel antedrug TLR7 agonist.

Triggering innate immune responses through TLRs is expected to be a novel therapeutic strategy for the treatment of allergic diseases. TLR agonists are able to modulate Th2 immune responses through undefined mechanisms. We investigated the mechanism of action of the suppression of Th2 immune responses with a novel antedrug TLR7 agonist. The antedrug is rapidly metabolized by plasma esterases to an acid with reduced activity to limit systemic responses. Topical administration of this compound inhibited features of the allergic airway inflammatory response in rat and murine allergic airways model. Type I IFN played a role in the suppression of Th2 cytokines produced from murine splenocytes. Inhibition of Th2 immune responses with the antedrug TLR7 agonist was shown to be via a type I IFN-dependent mechanism following short-term exposure to the compound, although there might be type I IFN-independent mechanisms following long-term exposure. We have demonstrated that local type I IFN signaling and plasmacytoid dendritic cells, but not Th1 immune responses, are required for in vivo efficacy against murine airway Th2-driven eosinophilia. Furthermore, migration of dendritic cell subsets into the lung was related to efficacy and is dependent on type I IFN signaling. Thus, the mechanism of action at the cytokine and cellular level involved in the suppression of Th2 allergic responses has been characterized, providing a potential new approach to the treatment of allergic disease.

Cardiovascular reflexes during treatment of social phobia with moclobemide.

INTRODUCTION: Cardiovascular side-effects are less frequent with moclobemide than with tricyclic or monoamine oxidase inhibitor antidepressants. We performed a detailed assessment of cardiovascular reflexes in 15 patients meeting DSM-III-R criteria for social phobia, before treatment and whilst taking a stable dose of moclobemide for a median of 7 weeks. METHOD: Cardiovascular reflex responses to standing, deep breathing and the Valsalva manoeuvre were assessed using beat-by-beat blood pressure and heart rate recording. RESULTS: Moclobemide produced a statistically significant, but clinically modest, degree of improvement in social phobia symptoms. Only the maximum change in heart rate from supine to standing showed a change from before to after treatment, which was not statistically significant after Bonferroni correction, and there was no consistent pattern of altered sympathetic or parasympathetic function. CONCLUSION: Moclobemide is relatively devoid of cardiovascular autonomic effects in physically healthy subjects with social phobia. ( Int J Psych Clin Pract 2001; 5:27-31).