Depending on the pMDI/spacer system chosen the delivery of medication can vary significantly and as a result will have implications on the potential carbon footprint.
In this case, the use of the AeroChamber Plus* Flow-Vu* VHC could potentially reduce the carbon footprint by three fold compared to the alternative spacers.
By maximizing the amount of each puff reaching the lungs the patient is likely to be able to get relief sooner and reduce the amount of puffs needed.
Depending on the pMDI/spacer system chosen the delivery of medication can vary significantly and as a result will have implications on the potential carbon footprint.
In this case, the use of the AeroChamber Plus* Flow-Vu* VHC could potentially reduce the carbon footprint by three fold compared to the alternative spacers.
By maximizing the amount of each puff reaching the lungs the patient is likely to be able to get relief sooner and reduce the amount of puffs needed.
Joignez-vous à Dr. Brian Grondin-Beaudoin, pneumologue, pour une discussion sur la MPOC, afin d'en savoir plus sur les nouvelles lignes directrices et découvri des stratégies pour aider vos patients à mieux respirer et ultimement, améliorer leur qualité de vie.
La prise en charge de votre asthme est plus importante que jamais. Par conséquent, nous aimerions vous inviter à vous joindre à Stéphane Côté qui discutera de ce qui suit :
Meilleure façon de prendre en charge votre asthme (ou celui de votre enfant)
Comment maîtriser l’asthme
Utilisation de médicaments inhalés et rôle des chambres d’inhalation
Joignez-vous à Dr. Claude Poirier, Pneumologue, pour une discussion sur la santé respiratoire et comment vous pouvez aider vos patients à mieux respirer et améliorer leur qualité de vie avec une approche non-pharmacologique.
Nouveautés Loi 31 – Enfin! Mais comment faire mieux avec nos patients en santé respiratoire?
L’ajout récent des prises en charge pour l’asthme et la MPOC dans les actes de la Loi 31 est une opportunité intéressante et rentable d’améliorer la santé respiratoire des patients. Ce webinaire vous permettra de mettre à jour vos connaissances en santé respiratoire, d’obtenir des outils pratiques afin de réaliser ces actes dans vos pharmacies et d’apprivoiser leur facturation. Un événement à ne pas manquer!
While it’s one of the most anticipated seasons of the year, summer can also be the most difficult season for Canadians living with COPD (chronic obstructive pulmonary disease). We want to help you make the most of it! Here’s what you need to know about summer, and how you can enjoy yours this year.
As a medical device manufacturer, we are committed to minimizing any disruption to the supply of our products to our customers globally, during this unprecedented time with the outbreak of COVID-19.
While it’s one of the most anticipated seasons of the year, summer can also be the most difficult season for Canadians living with COPD (chronic obstructive pulmonary disease). We want to help you make the most of it! Here’s what you need to know about summer, and how you can enjoy yours this year.
Depending on the pMDI/spacer system chosen the delivery of medication can vary significantly and as a result will have implications on the potential carbon footprint.
In this case, the use of the AeroChamber Plus* Flow-Vu* VHC could potentially reduce the carbon footprint by three fold compared to the alternative spacers.
By maximizing the amount of each puff reaching the lungs the patient is likely to be able to get relief sooner and reduce the amount of puffs needed.
As current MDIs contain hydrofluorocarbon propellants, it would be beneficial to find ways to reduce carbon emissions without compromising patient safety.
This lab study investigated a way to optimize the modelled lung dose per actuation while at the same time minimizing the carbon emissions from the MDI
Depending on the pMDI/spacer system chosen the delivery of medication can vary significantly and as a result will have implications on the potential carbon footprint.
In this case, the use of the AeroChamber Plus* Flow-Vu* VHC could potentially reduce the carbon footprint by three fold compared to the alternative spacers.
By maximizing the amount of each puff reaching the lungs the patient is likely to be able to get relief sooner and reduce the amount of puffs needed.
As current MDIs contain hydrofluorocarbon propellants, it would be beneficial to find ways to reduce carbon emissions without compromising patient safety.
This lab study investigated a way to optimize the modelled lung dose per actuation while at the same time minimizing the carbon emissions from the MDI
Inhaled tobramycin is recommended for use in cystic fibrosis patients for treatment of Pseudomonas aeruginosa infection. This in vitro study looked at antibiotic delivery using a BA nebulizer/compressor system and two BE nebulizer/compressor systems.
The DPI results suggest that inhalation breathing profiles can have an appreciable impact upon aerosol delivery, with one participant having much less predicted medication as fine particles
In contrast, although the inhalation profiles across all participants were also divergent when asked to inhale from the pMDI + VHC, either tidal breathing or by a slow, deep inhalation, all volunteers would have received a relatively consistent amount of medication.
It also appears that the pMDI + VHC platform delivers a larger FPM<5.0 µm for both APIs and a consequently smaller coarse particle mass. However, it is recognized that more investigation is warranted with a larger number of volunteers and with other passive DPIs having different resistances
COPD is a chronic and progressive disease that requires regular self-administration of inhaled medications. However, as the disease progresses, reduced respiratory muscle strength may prevent patients from generating sufficient inspiratory effort to effectively use dry-powder inhalers (DPIs) [1, 2]. In contrast, patients can inhale slowly or breathe tidally from a pMDI with VHC without the need to coordinate with inhaler actuation [3].
The most efficient and effective delivery method remains that recommended in the device IFU (one actuation inhaled at a time, as well inhalation as soon as possible after actuation)
However, this laboratory-based study has indicated that a modified common-canister protocol with an anti-static VHC as the aerosol transfer vehicle has the potential to be a viable ‘off-label’ proposition in hospital situations where there is an urgent need to conserve pMDI medication as well as avoid cross-contamination from pathogenic viruses or bacteria
