INFORS HT has a long-standing reputation for delivering high-quality, durable products. Our incubator shakers are engineered to withstand the demands of continuous operation, ensuring reliability and consistent performance over extended periods.
INFORS HT incubator shakers provide the versatility required for a wide range of applications, from genetic research to routine lab tasks. With precise control over temperature and agitation, you can trust that your results will be consistent and reproducible every time.
From installation and training to ongoing maintenance, INFORS HT is committed to ensuring your incubator shakers operate at peak performance. Our dedicated service team provides timely and thorough support, allowing you to focus on your research with confidence.
INFORS HT has a long-standing reputation for delivering high-quality, durable products. Our incubator shakers are engineered to withstand the demands of continuous operation, ensuring reliability and consistent performance over extended periods.
INFORS HT incubator shakers provide the versatility required for a wide range of applications, from genetic research to routine lab tasks. With precise control over temperature and agitation, you can trust that your results will be consistent and reproducible every time.
From installation and training to ongoing maintenance, INFORS HT is committed to ensuring your incubator shakers operate at peak performance. Our dedicated service team provides timely and thorough support, allowing you to focus on your research with confidence.
Ensure contamination-free conditions without interrupting your research. With the HEPA filtration system providing continuous air purification, capturing 99.995% of airborne particles, you can maintain a clean environment that supports reliable, reproducible results. Class 10 (ISO 4) air quality is restored within 3 minutes of closing the door, keeping your cultures protected and your research on track without added downtime or decontamination cycles. The application note data confirms this protection during active use, showing contamination control in exposed media and internal surfaces during open-vessel bacterial and mammalian cell cultivation.
The Multitron incubator shaker, manufactured in Bottmingen Switzerland, is the first shaker to earn the ACT Label (Environmental Impact Factor Label), recognizing its sustainable design and environmental responsibility. Engineered for high performance with a reduced environmental impact, the Multitron sets new standards for sustainable lab equipment while ensuring full support for at least 10 years, including responsible disposal guidance.
* Use case: 37°C setpoint, 125 to 135 min-1, 25 mm throw, 23 h operation including heating-up; without cooling: 1 h standby; with cooling: 1 h at 10°C setpoint
Rui de Paula Vieira de CastroAssociate Scientist, Jefferson Institute of Bioprocessing (JIB)
Nicole Lapuyade-BakerSenior Research Associate at CytomX Therapeutics
Matthew HigginsDepartment of Biochemistry at the University of Oxford, UK
Manfred Sander, Dipl.-Ing. (FH)Specialist Department of Equipment Management, Universitätsklinikum Erlangen
Researchers from the University of São Paulo have developed an innovative two-stage anaerobic digestion process that enhances methane production from sugarcane vinasse. Their approach, which integrates a fermentative-sulfidogenic stage, boosts biogas quality, lowers costs, and eliminates the need for chemical additives. This promising solution could revolutionize bioenergy recovery in sugarcane biorefineries.
Researchers from the Institute of Bioprocess Engineering and Pharmaceutical Technology at the University of Applied Sciences Mittelhessen have made strides in chemoorganotrophic electrofermentation using Cupriavidus necator. By experimenting with different redox mediators, they identified ferricyanide as a key player in enhancing anodic respiration. With the INFORS HT Multitron providing precise environmental control, the team achieved remarkable current densities, offering a promising solution to the challenges of oxygen-driven fermentation systems.
Researchers from the University of Delaware, Departments of Chemical and Biomolecular Engineering and Electrical and Computer Engineering have made strides in enhancing the resilience of Chinese hamster ovary (CHO) cells used in biopharmaceutical production. By employing the INFORS HT Multitron incubator shaker, they exposed CHO cells to stress conditions commonly encountered during manufacturing, such as elevated levels of ammonia, lactate, and osmolality. Through comprehensive transcriptomic analysis, the team identified 199 genes exhibiting bistable expression, with seven emerging as prime candidates for engineering stress-resistant cell lines. This research holds promise for optimizing cell health and boosting productivity in large-scale bioreactor operations.
Researchers from the University of São Paulo have developed an innovative two-stage anaerobic digestion process that enhances methane production from sugarcane vinasse. Their approach, which integrates a fermentative-sulfidogenic stage, boosts biogas quality, lowers costs, and eliminates the need for chemical additives. This promising solution could revolutionize bioenergy recovery in sugarcane biorefineries.
Researchers from the Institute of Bioprocess Engineering and Pharmaceutical Technology at the University of Applied Sciences Mittelhessen have made strides in chemoorganotrophic electrofermentation using Cupriavidus necator. By experimenting with different redox mediators, they identified ferricyanide as a key player in enhancing anodic respiration. With the INFORS HT Multitron providing precise environmental control, the team achieved remarkable current densities, offering a promising solution to the challenges of oxygen-driven fermentation systems.
Researchers from the University of Delaware, Departments of Chemical and Biomolecular Engineering and Electrical and Computer Engineering have made strides in enhancing the resilience of Chinese hamster ovary (CHO) cells used in biopharmaceutical production. By employing the INFORS HT Multitron incubator shaker, they exposed CHO cells to stress conditions commonly encountered during manufacturing, such as elevated levels of ammonia, lactate, and osmolality. Through comprehensive transcriptomic analysis, the team identified 199 genes exhibiting bistable expression, with seven emerging as prime candidates for engineering stress-resistant cell lines. This research holds promise for optimizing cell health and boosting productivity in large-scale bioreactor operations.
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