Incubadoras com agitação orbital
Multitron Standard
Incubadoras com agitação orbital
Multitron Standard
Sua incubadora com agitação orbital ideal para aplicações microbianas
Inicie rapidamente a triagem e o aumento de escala com a incomparável facilidade de uso e as condições de crescimento confiáveis da incubadora com agitação orbital Multitron Standard.
Vantagens
Esse shaker proporciona uniformidade na distribuição da temperatura em toda a bandeja e fornece resultados reproduzíveis do primeiro ao último experimento.
Nossa equipe de técnicos experientes e dedicados fornece as ferramentas proativas de que você precisa para minimizar o risco de tempo de inatividade do seu laboratório e manter seu shaker funcionando 24 horas por dia, 7 dias por semana.
Esse shaker proporciona uniformidade na distribuição da temperatura em toda a bandeja e fornece resultados reproduzíveis do primeiro ao último experimento.
Nossa equipe de técnicos experientes e dedicados fornece as ferramentas proativas de que você precisa para minimizar o risco de tempo de inatividade do seu laboratório e manter seu shaker funcionando 24 horas por dia, 7 dias por semana.
Especificações do produto
- Disponível como um sistema empilhado simples, duplo ou triplo, cada unidade pode ser configurada de modo exclusivo.
- Altura de trabalho confortável com uma área de ocupação geral pequena: 1070 x 860 x 1710 mm (unidades de empilhamento triplo com base baixa)
- Alta velocidade e eixo de agitação: 20 a 400 rpm, 25 e 50 mm, com unidade superior de 3 bandejas, máx. 350 rpm
Downloads dos produtos
Publicações relacionadas
Todas as publicaçõesResearchers from the Laboratory of Process Technology (NeptunLab), Department of Microsystems Engineering (IMTEK), University of Freiburg (Germany) developed a new way to produce bioactive glass microscaffolds for tissue engineering using advanced 3D printing technology. During in vitro mineralization studies, samples were incubated in the INFORS HT Minitron incubator shaker, where the material demonstrated strong bioactivity. The scaffolds were also shown to be compatible with human mesenchymal stromal cells and supported osteogenic differentiation, providing a new platform for studying scaffold design in tissue engineering.
Researchers from the KTH Royal Institute of Technology (Sweden) used enzyme-constrained genome-scale models (ecGEMs) to redesign the anaerobic metabolism of Saccharomyces cerevisiae for the co-production of 2,3-butanediol and glycerol. Seed cultures were prepared using the INFORS HT Minitron incubator shaker before fermentation experiments, enabling validation of model predictions through bioreactor cultivation and proteomic analysis. The study demonstrated that engineered yeast cells could achieve high glucose uptake rates by reallocating cellular resources toward glycolysis, highlighting the potential of ecGEMs as a powerful tool for metabolic engineering and strain development.
Researchers from the Department of Chemical & Biomolecular Engineering and the Department of Electrical and Computer Engineering at the University of Delaware (USA) developed a transcriptomic workflow called MemorySeq to identify stress-responsive biomarkers in Chinese hamster ovary (CHO) cells exposed to manufacturing-related stress conditions. Using the INFORS HT Minitron incubator shaker for controlled CHO cell cultivation, the study identified 199 genes with heritable transcriptional variability linked to stress adaptation, apoptosis regulation, and metabolic pathways. These findings provide new insights into engineering more stress-tolerant CHO cell lines for improved biopharmaceutical manufacturing performance.
Researchers from the Laboratory of Process Technology (NeptunLab), Department of Microsystems Engineering (IMTEK), University of Freiburg (Germany) developed a new way to produce bioactive glass microscaffolds for tissue engineering using advanced 3D printing technology. During in vitro mineralization studies, samples were incubated in the INFORS HT Minitron incubator shaker, where the material demonstrated strong bioactivity. The scaffolds were also shown to be compatible with human mesenchymal stromal cells and supported osteogenic differentiation, providing a new platform for studying scaffold design in tissue engineering.
Researchers from the KTH Royal Institute of Technology (Sweden) used enzyme-constrained genome-scale models (ecGEMs) to redesign the anaerobic metabolism of Saccharomyces cerevisiae for the co-production of 2,3-butanediol and glycerol. Seed cultures were prepared using the INFORS HT Minitron incubator shaker before fermentation experiments, enabling validation of model predictions through bioreactor cultivation and proteomic analysis. The study demonstrated that engineered yeast cells could achieve high glucose uptake rates by reallocating cellular resources toward glycolysis, highlighting the potential of ecGEMs as a powerful tool for metabolic engineering and strain development.
Researchers from the Department of Chemical & Biomolecular Engineering and the Department of Electrical and Computer Engineering at the University of Delaware (USA) developed a transcriptomic workflow called MemorySeq to identify stress-responsive biomarkers in Chinese hamster ovary (CHO) cells exposed to manufacturing-related stress conditions. Using the INFORS HT Minitron incubator shaker for controlled CHO cell cultivation, the study identified 199 genes with heritable transcriptional variability linked to stress adaptation, apoptosis regulation, and metabolic pathways. These findings provide new insights into engineering more stress-tolerant CHO cell lines for improved biopharmaceutical manufacturing performance.
Artigos relacionados
BlogMoving a mammalian cell culture process from shake flask to bioreactor is more than a scale-up exercise. Each transition introduces new challenges in oxygen transfer, pH control, CO₂ management, mixing, and data reproducibility. This practical guide explores the key stages of cell culture process development, explains why process transfer often fails, and shows how integrated bioreactor control and data management help create scalable, reproducible processes from screening through scale-up.
Buying used laboratory equipment can reduce upfront costs and improve short-term flexibility. However, when evaluating a used incubator shaker, laboratories must consider contamination risk, service history, manufacturer support status, and long-term cost of ownership. A structured assessment ensures that short-term savings do not introduce long-term operational instability.
Contamination remains a persistent risk in incubation workflows, with the potential to compromise experimental results, delay timelines, and require costly repeat work. Even brief exposure during routine handling or access can introduce unwanted particles that affect culture integrity and reproducibility. The Multitron Incubator Shaker with the integrated HEPA filtration system is designed to help laboratories maintain consistent air quality throughout incubation. By providing continuous air purification and measurable performance, INFORS HT supports reliable cultivation conditions that reduce the risk of contamination-related interruptions and help keep research on track.
Moving a mammalian cell culture process from shake flask to bioreactor is more than a scale-up exercise. Each transition introduces new challenges in oxygen transfer, pH control, CO₂ management, mixing, and data reproducibility. This practical guide explores the key stages of cell culture process development, explains why process transfer often fails, and shows how integrated bioreactor control and data management help create scalable, reproducible processes from screening through scale-up.
Buying used laboratory equipment can reduce upfront costs and improve short-term flexibility. However, when evaluating a used incubator shaker, laboratories must consider contamination risk, service history, manufacturer support status, and long-term cost of ownership. A structured assessment ensures that short-term savings do not introduce long-term operational instability.
Contamination remains a persistent risk in incubation workflows, with the potential to compromise experimental results, delay timelines, and require costly repeat work. Even brief exposure during routine handling or access can introduce unwanted particles that affect culture integrity and reproducibility. The Multitron Incubator Shaker with the integrated HEPA filtration system is designed to help laboratories maintain consistent air quality throughout incubation. By providing continuous air purification and measurable performance, INFORS HT supports reliable cultivation conditions that reduce the risk of contamination-related interruptions and help keep research on track.
Ofertas ideais para otimizar ainda mais seu fluxo de trabalho de bioprocessos
Aumente o desempenho de seu shaker, minimize o tempo de inatividade e maximize a segurança.
Aprimore seu shaker de laboratório com uma ampla variedade de bandejas, suportes e tapetes adesivos.
Minimize as interrupções e garanta a produtividade ideal em cada etapa do seu bioprocesso.
Aumente o desempenho de seu shaker, minimize o tempo de inatividade e maximize a segurança.
Aprimore seu shaker de laboratório com uma ampla variedade de bandejas, suportes e tapetes adesivos.
Minimize as interrupções e garanta a produtividade ideal em cada etapa do seu bioprocesso.
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