Anti-melanoma differentiation-associated gene 5 (anti-MDA5) positive dermatomyositis: early detection is crucial.

Anti-melanoma differentiation-associated gene 5-positive (Anti-MDA5) dermatomyositis (DM) is an aggressive phenotype of DM associated with rapidly progressive interstitial lung disease (RP-ILD). It is a rare condition that carries high mortality. Diagnosis and management of patients with anti-MDA5 DM RP-ILD presents several challenges, including uncertainty around treatment algorithms and a lack of evidence to inform practice. This case report of a patient with anti-MDA5 DM RP-ILD highlights these challenges, emphasising the fulminant course of this disease despite aggressive immunosuppression. Further research is required to guide management and to minimise morbidity and mortality, and greater awareness of the condition is required to minimise delays in diagnosis.

Dose equivalence between metaraminol and norepinephrine in critical care.

AIMS: The aim of this study was to determine the conversion dose ratio between continuous infusion metaraminol and norepinephrine in critically ill patients with shock. METHODS: A retrospective cohort study was conducted in adult patients with shock admitted to an intensive care unit from 29 October 2018 to 30 October 2019 and who transitioned from metaraminol monotherapy to norepinephrine monotherapy. Mean arterial pressure (MAP) and infusion doses for both drugs were collected at hourly intervals; 2 hours before to 5 hours after switching from metaraminol monotherapy to norepinephrine monotherapy. The conversion dose ratio was defined as the ratio of metaraminol (µg.kg-1 .min-1) : norepinephrine (µg.kg-1 .min-1 ) required to achieve a similar MAP. RESULTS: A total of 43 out of 144 eligible patients were included. The median age was 68 years (IQR 56-76) and 22 (51%) were male. There was no significant difference between the baseline MAP during metaraminol monotherapy (median 71 mm Hg, IQR 66-76) and the post-transition MAP during norepinephrine monotherapy (median 70 mm Hg, IQR 66-73) (P = .09). The median conversion dose ratio between metaraminol and norepinephrine was 13 (IQR 7-24). In the sensitivity analyses, the median conversion dose ratio using the maximum and the mean norepinephrine infusion dose was 8 (IQR 5-16) and 12 (IQR 8-23), respectively. CONCLUSION: A conversion dose ratio of 10:1 (metaraminol µg.kg-1 .min-1 :norepinephrine µg.kg-1 .min-1 ) may be used in critically ill patients with shock to account for ease of calculations and variability of the conversion ratio in the primary and sensitivity analyses.

Vasopressor dose equivalence: A scoping review and suggested formula.

PURPOSE: Calculating equipotent doses between vasopressor agents is necessary in clinical practice and research pertaining to the management of shock. This scoping review summarizes conversion ratios between vasopressors and provides a formula to incorporate into study designs. MATERIALS AND METHODS: Medline, Embase and Web of Science databases were searched from inception to 21st October 2020. Additional papers were obtained through bibliography searches of retrieved articles. Two investigators assessed articles for eligibility. Clinical trials comparing the potency of at least two intravenous vasopressors (norepinephrine, epinephrine, dopamine, phenylephrine, vasopressin, metaraminol or angiotensin II), with regard to an outcome of blood pressure, were selected. RESULTS: Of 16,315 articles, 21 were included for synthesis. The range of conversion ratios equivalent to one unit of norepinephrine were: epinephrine (0.7-1.4), dopamine (75.2-144.4), metaraminol (8.3), phenylephrine (1.1-16.3), vasopressin (0.3-0.4) and angiotensin II (0.07-0.13). The following formula may be considered for the calculation of norepinephrine equivalents (NE) (all in mcg/kg/min, except vasopressin in units/min): NE = norepinephrine + epinephrine + phenylephrine/10 + dopamine/100 + metaraminol/8 + vasopressin*2.5 + angiotensin II*10. CONCLUSION: A summary of equipotent ratios for common vasopressors used in clinical practice has been provided. Our formula may be considered to calculate NE for studies in the intensive care unit.

A new age intervention to support medication adherence.

Adherence to pharmacological treatments is a complex behaviour which is influenced by a number of factors throughout a person's medication use journey. No single intervention has yet been shown to effectively address non-adherence long term. Technology, which can support a multifaceted intervention targeted to the needs of a person, may present a feasible solution to optimise adherence. Technological interventions such as mobile applications (apps) have shown early promise, increasing medication adherence rates and providing health care practitioners with an opportunity to monitor and measure adherence. Some of their features include providing informational messages, saving prescription details and sending refill reminders. Their inability to address patient specific factors across the three phases of adherence (initiation, implementation and discontinuation) limit their usefulness in clinical practice. We propose recommendations to guide the design of digital interventions that can support adherence. Interventions should be individualised to address patient specific factors that affect adherence to medications; the features should support individuals across all three phases of adherence. Interventions must integrate within existing prescriber and dispensing software and interconnect all members of an individual's healthcare team. Finally, to ensure optimal outcomes for the individual, all digital interventions should inform the person about why adherence is necessary.