Bioréacteurs de paillasse
Labfors 5
Bioréacteurs de paillasse
Labfors 5
La souplesse d’un système universel pour traiter de plus gros volumes lors du développement des procédés sur paillasse
Optimisez vos applications microbiennes avec un bioréacteur de paillasse plus grand qui outre la souplesse, permet de contrôler le procédé et de le qualifier.
Avantages
Le Labfors 5 est configurable en fonction des besoins individuels grâce à une sélection d’agitateurs, de tubes de barbotage et d’accessoires. Définissez la régulation de la température et l’injection de gaz selon le type de culture : batch, fed-batch ou continue.
Ce modèle a été conçu pour être compact et faciliter l'accès aux différents ports et à la platine. Les têtes de pompe sont démontables, ce qui permet de les stériliser à l’autoclave avec la cuve.
Organisez efficacement le travail grâce au panneau de commande tactile, qui permet de commander simultanément jusqu’à six cuves et d’économiser ainsi du temps et de la main d’œuvre.
Le Labfors 5 est configurable en fonction des besoins individuels grâce à une sélection d’agitateurs, de tubes de barbotage et d’accessoires. Définissez la régulation de la température et l’injection de gaz selon le type de culture : batch, fed-batch ou continue.
Ce modèle a été conçu pour être compact et faciliter l'accès aux différents ports et à la platine. Les têtes de pompe sont démontables, ce qui permet de les stériliser à l’autoclave avec la cuve.
Organisez efficacement le travail grâce au panneau de commande tactile, qui permet de commander simultanément jusqu’à six cuves et d’économiser ainsi du temps et de la main d’œuvre.
Une gestion simplifiée des données
Optimisez vos procédés grâce à l’automatisation. Quelle que soit la marque de votre bioréacteur, eve®, notre plateforme web pour les bioprocédés, s’intègre facilement et vous permet de contrôler efficacement le procédé par la surveillance et l’analyse des données.
Caractéristiques
- Dimension des cuves (et volumes utiles) : 2 L (0.5-1.2 L), 3,6 L (0,5-2,3 L), 7,5 L (1-5 L) et 13 L (2,2-10 L)
- Dimensions de l’unité de base, avec panneau de commande, des modèle 2, 3,6 et 7,5 L (l x P x H) : 464 x 462 x 996 mm
- Dimensions de l’unité de base, avec panneau de commande, du modèle 13 L (l x P x H) : 586 x 512 x 996 mm
- Le panneau de commande tactile permet de commander jusqu’à 6 cuves
- Entraînement direct jusqu’à 1500 min-1 grâce au moteur à couple élevé
Documentations
Publications associées
Toutes les publicationsAt the University of Boras in Sweden, researchers have scaled up second-generation bioethanol production from beech wood chips using an acetone-based organosolv fractionation process. With the help of the INFORS HT Multifors bench-top bioreactor, they confirmed high fermentation efficiency at the 10-L scale, reaching ethanol yields of up to 95% from glucose-rich C6 streams. This study illustrates how optimized biomass pre-treatment and fermentation workflows can drive more efficient and scalable biofuel production.
At Lund University, Division of Food and Pharma, researchers studied the role of annealing in the freeze-drying of probiotic bacteria. Using the INFORS HT Multifors bioreactor and eve software, they controlled the fermentation of Limosilactobacillus reuteri to produce consistent cell cultures for downstream drying. Their results show that increased annealing time leads to thicker encapsulating structures and enhanced storage stability, providing a clearer path to developing more robust probiotic products.
Researchers at Friedrich-Alexander-Universität Erlangen-Nürnberg developed and tested methods to improve the stability and recyclability of a PET-degrading enzyme for plastic recycling. Using the INFORS HT Labfors bioreactor, the team compared several immobilization strategies and found that pH-responsive polymers delivered the best results, retaining about 80% of enzyme activity and enabling up to five PET degradation cycles. In batch reactions, the process achieved more than 97% terephthalic acid yield in less than 14 hours for the first three cycles and about 78% yield in the fifth cycle. These findings support more efficient and scalable processes for enzymatic PET recycling.
At the University of Boras in Sweden, researchers have scaled up second-generation bioethanol production from beech wood chips using an acetone-based organosolv fractionation process. With the help of the INFORS HT Multifors bench-top bioreactor, they confirmed high fermentation efficiency at the 10-L scale, reaching ethanol yields of up to 95% from glucose-rich C6 streams. This study illustrates how optimized biomass pre-treatment and fermentation workflows can drive more efficient and scalable biofuel production.
At Lund University, Division of Food and Pharma, researchers studied the role of annealing in the freeze-drying of probiotic bacteria. Using the INFORS HT Multifors bioreactor and eve software, they controlled the fermentation of Limosilactobacillus reuteri to produce consistent cell cultures for downstream drying. Their results show that increased annealing time leads to thicker encapsulating structures and enhanced storage stability, providing a clearer path to developing more robust probiotic products.
Researchers at Friedrich-Alexander-Universität Erlangen-Nürnberg developed and tested methods to improve the stability and recyclability of a PET-degrading enzyme for plastic recycling. Using the INFORS HT Labfors bioreactor, the team compared several immobilization strategies and found that pH-responsive polymers delivered the best results, retaining about 80% of enzyme activity and enabling up to five PET degradation cycles. In batch reactions, the process achieved more than 97% terephthalic acid yield in less than 14 hours for the first three cycles and about 78% yield in the fifth cycle. These findings support more efficient and scalable processes for enzymatic PET recycling.
Ce qu’en disent nos clients
Prof. Dr. Christoph HerwigDirecteur du génie biochimique, Université technique de Vienne
Dr. Ben J. GuScientifique principal et chef de laboratoire, Laboratoire de phagocytose innée
Articles Liés
BlogScaling microbial fermentation, when working with bacterial, fungal, or yeast-based systems, from laboratory scale to pilot or commercial production involves many challenges. Whether you are producing bacterial cultures for biopharmaceuticals, yeast for bioethanol production, fungal systems for enzyme manufacturing, or precision fermentation products, understanding these specific challenges and confidently overcoming them is important.
A bioreactor provides an ideal environment where cells can focus on what they are supposed to do: proliferate. Like lab workers, cells can only produce consistently good work if the conditions are right: it should not be too hot or too cold, and they have to have enough nutritious food and fresh air. In terms of a bioreactor, this means maintaining pH, temperature, ensuring sufficient gas supply and, depending on how the instrument has been configured, adding nutrients for successful maintenance of growth.
Feeding strategy is one of the most influential variables in any bioprocess. Whether you’re working with bacterial, yeast, fungal, or mammalian cell cultures, how you supply nutrients affects everything from growth rates and yields to oxygen demand and product quality. The choice between batch, fed-batch, and continuous culture depends on your organism, application, and production goals. Fortunately, modern bioreactor systems like those from INFORS HT make it easy to implement any of these strategies at lab or pilot scale.
Scaling microbial fermentation, when working with bacterial, fungal, or yeast-based systems, from laboratory scale to pilot or commercial production involves many challenges. Whether you are producing bacterial cultures for biopharmaceuticals, yeast for bioethanol production, fungal systems for enzyme manufacturing, or precision fermentation products, understanding these specific challenges and confidently overcoming them is important.
A bioreactor provides an ideal environment where cells can focus on what they are supposed to do: proliferate. Like lab workers, cells can only produce consistently good work if the conditions are right: it should not be too hot or too cold, and they have to have enough nutritious food and fresh air. In terms of a bioreactor, this means maintaining pH, temperature, ensuring sufficient gas supply and, depending on how the instrument has been configured, adding nutrients for successful maintenance of growth.
Feeding strategy is one of the most influential variables in any bioprocess. Whether you’re working with bacterial, yeast, fungal, or mammalian cell cultures, how you supply nutrients affects everything from growth rates and yields to oxygen demand and product quality. The choice between batch, fed-batch, and continuous culture depends on your organism, application, and production goals. Fortunately, modern bioreactor systems like those from INFORS HT make it easy to implement any of these strategies at lab or pilot scale.
Produits complémentaires pour optimiser votre bioprocédé
Maintenez les performances de vos bioréacteurs et augmentez leur durée de vie grâce à notre offre de services et d’assistance.
Notre gamme complète d’accessoires et de consommables vous permet d’optimiser votre bioréacteur ou votre système de fermentation.
Le logiciel eve® rassemble les processus, les appareils, les données des bioprocédés et des fonctions Big Data dans une plateforme web très intuitive.
Maintenez les performances de vos bioréacteurs et augmentez leur durée de vie grâce à notre offre de services et d’assistance.
Notre gamme complète d’accessoires et de consommables vous permet d’optimiser votre bioréacteur ou votre système de fermentation.
Le logiciel eve® rassemble les processus, les appareils, les données des bioprocédés et des fonctions Big Data dans une plateforme web très intuitive.