From September 11-13, the 12th Industrial Microorganisms Conference, hosted by the Chinese Food Fermentation Industry Research Institute, the China Industrial Microorganisms Preservation Management Center (CICC), and the Industrial Microorganisms Professional Committee of the Chinese Microbiology Society, was held successfully in Beijing Friendship Hotel. The conference focused on biological manufacturing, microbial resource utilization, and safety control technology, deeply integrating new-generation information technology, biotechnology, and other strategic emerging industries, accelerating the formation of new-quality production, and promoting the high-quality development of the industrial microorganisms industry. Dynaflow was invited to attend with the "PPMI Sub-Directional Microbial Detection Device" and "Simulated Microgravity Device".
At the Industrial Microorganisms High-tech Platform and Equipment Exhibition, Dynaflow R&D Deputy General Manager Xi Xiaopeng gave a presentation on the PPMI Sub-Directional Microbial Detection Device and Simulated Microgravity Device. He introduced in detail the sub-directional precision microbial identification technology independently created by Dynaflow (PPMI), and through the self-developed high-precision collection and enrichment technology and the application of artificial intelligence technology in Raman detection technology, it achieves rapid detection of microorganisms, bacteria, and viruses in the air and liquid, with results obtainable in 7-10 minutes. This solves the problems of complex air microorganism sampling operations, long detection cycles, and high costs in traditional methods.
The Simulated Microgravity Device uses digital control technology, and through motion control algorithms, it adjusts the rotation speed of the double axis in real-time, randomly changing the direction of the gravity vector of the sample, and simulates the microgravity environment. The device can quickly match carbon dioxide incubators, biological safety cabinets, scientific gloves, and intelligent scene experiment laboratories, realizing ground microgravity environment simulation experiments. It can be widely applied in life sciences and materials sciences.
During the event, representatives and industry partners showed great interest in Dynaflow's "PPMI Sub-Directional Microbial Detection Device" and "Simulated Microgravity Device" product lines. They discussed in depth the principles and technologies of the equipment, the applications of microorganisms in the field, and the high-end microorganism experimental platform and other aspects.
Dynaflow's independently created sub-directional precision microbial identification (PPMI) technology, through the self-developed high-precision collection and enrichment technology and the application of artificial intelligence technology in Raman detection technology, achieves rapid detection of microorganisms, bacteria, and viruses in the air and liquid, with results obtainable in 7-10 minutes; this solves the problems of complex air microorganism sampling operations, long detection cycles, and high costs in traditional methods.
The D-ray Microbial Detection Device realizes full-process detection automation, with high sensitivity, fast speed, and low detection cost. The compact design allows for flexible application in various scenarioses requiring rapid detection and real-time monitoring of microorganisms. It can be widely used in customs, pharmaceuticals, food, medical, epidemic prevention, and petroleum and chemical industries.
The Simulated Microgravity Device uses motion control algorithms to adjust the rotation speed of the double axis in real-time, randomly changing the direction of the gravity vector of the sample, and simulates the microgravity environment in the 10-1g~10-5g range. It can be applied to cell therapy, biopharmaceuticals, regenerative medicine, protein structure analysis, breeding, and other research fields. Current experiments have been completed in cell types (bone marrow cells, stem cells) and plant types (hyacinth, construction trees) simulating gravity environments for growth. Significant progress has been made.
From September 11-13, the 12th Industrial Microorganisms Conference, hosted by the Chinese Food Fermentation Industry Research Institute, the China Industrial Microorganisms Preservation Management Center (CICC), and the Industrial Microorganisms Professional Committee of the Chinese Microbiology Society, was held successfully in Beijing Friendship Hotel. The conference focused on biological manufacturing, microbial resource utilization, and safety control technology, deeply integrating new-generation information technology, biotechnology, and other strategic emerging industries, accelerating the formation of new-quality production, and promoting the high-quality development of the industrial microorganisms industry. Dynaflow was invited to attend with the "PPMI Sub-Directional Microbial Detection Device" and "Simulated Microgravity Device".
At the Industrial Microorganisms High-tech Platform and Equipment Exhibition, Dynaflow R&D Deputy General Manager Xi Xiaopeng gave a presentation on the PPMI Sub-Directional Microbial Detection Device and Simulated Microgravity Device. He introduced in detail the sub-directional precision microbial identification technology independently created by Dynaflow (PPMI), and through the self-developed high-precision collection and enrichment technology and the application of artificial intelligence technology in Raman detection technology, it achieves rapid detection of microorganisms, bacteria, and viruses in the air and liquid, with results obtainable in 7-10 minutes. This solves the problems of complex air microorganism sampling operations, long detection cycles, and high costs in traditional methods.
The Simulated Microgravity Device uses digital control technology, and through motion control algorithms, it adjusts the rotation speed of the double axis in real-time, randomly changing the direction of the gravity vector of the sample, and simulates the microgravity environment. The device can quickly match carbon dioxide incubators, biological safety cabinets, scientific gloves, and intelligent scene experiment laboratories, realizing ground microgravity environment simulation experiments. It can be widely applied in life sciences and materials sciences.
During the event, representatives and industry partners showed great interest in Dynaflow's "PPMI Sub-Directional Microbial Detection Device" and "Simulated Microgravity Device" product lines. They discussed in depth the principles and technologies of the equipment, the applications of microorganisms in the field, and the high-end microorganism experimental platform and other aspects.
Dynaflow's independently created sub-directional precision microbial identification (PPMI) technology, through the self-developed high-precision collection and enrichment technology and the application of artificial intelligence technology in Raman detection technology, achieves rapid detection of microorganisms, bacteria, and viruses in the air and liquid, with results obtainable in 7-10 minutes; this solves the problems of complex air microorganism sampling operations, long detection cycles, and high costs in traditional methods.
The D-ray Microbial Detection Device realizes full-process detection automation, with high sensitivity, fast speed, and low detection cost. The compact design allows for flexible application in various scenarioses requiring rapid detection and real-time monitoring of microorganisms. It can be widely used in customs, pharmaceuticals, food, medical, epidemic prevention, and petroleum and chemical industries.
The Simulated Microgravity Device uses motion control algorithms to adjust the rotation speed of the double axis in real-time, randomly changing the direction of the gravity vector of the sample, and simulates the microgravity environment in the 10-1g~10-5g range. It can be applied to cell therapy, biopharmaceuticals, regenerative medicine, protein structure analysis, breeding, and other research fields. Current experiments have been completed in cell types (bone marrow cells, stem cells) and plant types (hyacinth, construction trees) simulating gravity environments for growth. Significant progress has been made.
