The science behind the nose: correlating volatile organic compound characterisation with canine biodetection of COVID-19.

Background: The SARS-CoV-2 pandemic stimulated the advancement and research in the field of canine scent detection of COVID-19 and volatile organic compound (VOC) breath sampling. It remains unclear which VOCs are associated with positive canine alerts. This study aimed to confirm that the training aids used for COVID-19 canine scent detection were indeed releasing discriminant COVID-19 VOCs detectable and identifiable by gas chromatography (GC-MS). Methods: Inexperienced dogs (two Labradors and one English Springer Spaniel) were trained over 19 weeks to discriminate between COVID-19 infected and uninfected individuals and then independently validated. Getxent tubes, impregnated with the odours from clinical gargle samples, used during the canines' maintenance training process were also analysed using GC-MS. Results: Three dogs were successfully trained to detect COVID-19. A principal components analysis model was created and confirmed the ability to discriminate between VOCs from positive and negative COVID-19 Getxent tubes with a sensitivity of 78% and a specificity of 77%. Two VOCs were found to be very predictive of positive COVID-19 cases. When comparing the dogs with GC-MS, F1 and Matthew's correlation coefficient, correlation scores of 0.69 and 0.37 were observed, respectively, demonstrating good concordance between the two methods. Interpretation: This study provides analytical confirmation that canine training aids can be safely and reliably produced with good discrimination between positive samples and negative controls. It is also a further step towards better understanding of canine odour discrimination of COVID-19 as the scent of interest and defining what VOC elements the canines interpret as "essential".

In search of COVID-19: The ability of biodetection canines to detect COVID-19 odours from clinical samples.

BACKGROUND: COVID-19 continues to be a public health concern and the demand for fast and reliable screening tests remains. SARS-CoV-2 infection in humans generates a specific volatile organic compound signature; this 'volatilome' could be used to deploy highly trained canine scent detection teams if they could reliably detect odours from infected individuals. METHODS: Two dogs were trained over 19 weeks to discriminate between the odours produced by breath, sweat, and gargle specimens collected from SARS-CoV-2 infected and uninfected individuals. Third party validation was conducted in a randomized double-blinded controlled manner using fresh odours obtained from different patients within 10 days of their first positive SARS-CoV-2 molecular result. RESULTS: Cumulatively, the dogs completed 299 training sessions on odours from 108 unique participants. Validation was conducted over 2 days with 120 new odours. Twenty-four were odours collected from SARS-CoV-2 positive individuals (8 gargle, 8 sweat, and 8 breath); 21 were from SARS-CoV-2 negative individuals (5 gargle, 8 sweat, and 8 breath) and the remaining 75 were odours that the dogs could have associated with the target odour during training. The dogs were able to identify odours from positive specimens with an overall sensitivity of 100% and a specificity of 87.5%. Considering a community prevalence of 10%, the combined negative predictive value of the dogs was 100% and the positive predictive value was 47.1%. CONCLUSIONS: Multiple dogs can be trained to accurately detect SARS-CoV-2 positive individuals. Future research is required to determine how and when canine scent detection teams should be deployed.

HISTORIQUE: La COVID-19 continue d'être une préoccupation sanitaire, et la demande de tests de dépistage rapides et fiables se maintient. L'infection par le SRAS-CoV-2 chez les humains produit une signature composée organique volatile bien précise. Ce « volatilome ¼ pourrait être utilisé pour déployer des équipes canines hautement formées et spécialisées dans la détection des odeurs afin d'établir si elles peuvent détecter les odeurs des personnes infectées avec fiabilité. MÉTHODOLOGIE: Deux chiens ont été formés pendant 19 semaines pour distinguer les odeurs émanantes des échantillons d'haleine, de sueur et de gargarisme prélevés chez des personnes infectées et non infectées par le SRAS-CoV-2. Les chercheurs ont effectué une validation par des tiers dans le cadre d'une étude contrôlée randomisée à double insu au moyen d'odeurs fraîches obtenues auprès de divers patients dans les dix jours suivant le premier résultat moléculaire positif au SRAS-CoV-2. RÉSULTATS: Dans l'ensemble, les chiens ont effectué 299 séances de formation sur les odeurs de 108 participants uniques. La validation a eu lieu sur deux jours à partir de 120 nouvelles odeurs. Ainsi, 24 odeurs provenaient de personnes positives au SRAS-CoV-2 (8 échantillons de gargarisme, 8 de sueur et 8 d'haleine); 21 provenaient de personnes négatives au SRAS-CoV-2 (5 échantillons de gargarisme, 8 de sueur et 8 d'haleine) et les 75 autres étaient des odeurs que les chiens avaient pu associer à l'odeur cible pendant la formation. Les chiens ont été en mesure de dépister les odeurs des échantillons positifs selon une sensibilité globale de 100 % et une spécificité de 87,5 %. Étant donné une prévalence communautaire de 10 %, la valeur prédictive négative combinée des chiens s'élevait à 100 % et la valeur prédictive positive, à 47,1 %. CONCLUSIONS: De nombreux chiens peuvent être formés pour dépister avec exactitude les personnes positives au SRAS-CoV-2. De futures recherches devront être réalisées pour déterminer quand et comment déployer ces équipes canines spécialisées en biodétection.

Pups Assisting Wellness for Staff (P.A.W.S.): Evaluating the impact of canine-assisted interventions on critical care staff wellness.

Acute care settings can expose staff to job-related stressors. Pups Assisting Wellness for Staff (P.A.W.S.) has been designed as an innovative approach to support acute care staff in the emergency department and intensive care unit. Initially, P.A.W.S. was implemented as a Comfort Dog Pilot and then expanded into a Therapy Dog Model. The Therapy Dog Model incorporated learnings from the Comfort Dog Pilot to evaluate the impact of the following: more dogs, using certified therapy dogs, and visiting at different times of the day. Results throughout the project demonstrated a positive impact on staff morale, staff stress, overall and staff satisfaction, and a strong desire for the project to continue. As a result and with a collaborative effort between a multidisciplinary team, P.A.W.S. has now been operationalized as a permanent program to support staff in acute care.