The development of a novel on-line system for the monitoring and control of fermentation processes
dc.contributor.author | Wang, Yu | en |
dc.date.accessioned | 2016-05-26T12:18:50Z | en |
dc.date.available | 2016-05-26T12:18:50Z | en |
dc.date.issued | 1995-07 | en |
dc.identifier.citation | Wang, Y. (1995) 'The development of a novel on-line system for the monitoring and control of fermentation processes'. PhD Thesis. University of Luton. | en |
dc.identifier.uri | http://hdl.handle.net/10547/610796 | en |
dc.description | A thesis submitted to the University of Luton for the degree of Doctor of Philosophy | en |
dc.description.abstract | This thesis describes the development of a computer controlled on-line system for fermentation monitoring and control. The entire system consists of a laboratory fermenter, flow injection system (four channels), a newly designed on-line filter, biomass analysis channel, pH and oxygen controllers as well as a spectrophotometer. A new design of gas driven flow injection analysis (FIA) allows a large number of reagents to be handled. The computer-controlled four channel PIA system is well suited for sequential analysis, which is important for fermentation on-line mOnitoring. The system can change the wavelength of the spectrophotometer automatically for each PIA channel, which makes the system powerful and flexible. A high frequency, low energy ultrasonic filter was modified and applied to the system for on-line mammalian cell culture sampling without breaking the sterile barrier. The results show that this novel application of ultrasonic filter technology results in higher efficiency and reliability and a longer life cycle than other types of filter. All the operations of the analytical system are controlled by a Macintosh computer (Quadra 950). The control program was written in LabVIEW which is a graphical programming language and well applicable to fermentation control. The software communicates with detectors, data acquisition, data analysis and presentation. The system can programmatically control up to 50 devices. Mammalian cell batch culture was used as an example of the application of the system. The system consists of a laboratory fermenter with a continuous sample withdrawal filter and an analysis system where glucose, lactate and ammonia, lactate dehydrogenase and biomass were measured. Cell viability was estimated by microscopic assay with trypan blue. pH and Oxygen were also measured. The system response was fast and yields a large number of reliable and precise analytical results which can be of great importance in the monitoring and control of mammalian cell culture conditions. | |
dc.language.iso | en | en |
dc.publisher | University of Bedfordshire | en |
dc.subject | C790 Molecular Biology, Biophysics and Biochemistry not elsewhere classified | en |
dc.subject | fermentation | en |
dc.subject | monitoring | en |
dc.subject | flow injection analysis | en |
dc.subject | cell culture | en |
dc.title | The development of a novel on-line system for the monitoring and control of fermentation processes | en |
dc.type | Thesis or dissertation | en |
dc.type.qualificationname | PhD | en_GB |
dc.type.qualificationlevel | PhD | en |
dc.publisher.institution | University of Bedfordshire | en |
refterms.dateFOA | 2020-05-13T15:48:54Z | |
html.description.abstract | This thesis describes the development of a computer controlled on-line system for fermentation monitoring and control. The entire system consists of a laboratory fermenter, flow injection system (four channels), a newly designed on-line filter, biomass analysis channel, pH and oxygen controllers as well as a spectrophotometer. A new design of gas driven flow injection analysis (FIA) allows a large number of reagents to be handled. The computer-controlled four channel PIA system is well suited for sequential analysis, which is important for fermentation on-line mOnitoring. The system can change the wavelength of the spectrophotometer automatically for each PIA channel, which makes the system powerful and flexible. A high frequency, low energy ultrasonic filter was modified and applied to the system for on-line mammalian cell culture sampling without breaking the sterile barrier. The results show that this novel application of ultrasonic filter technology results in higher efficiency and reliability and a longer life cycle than other types of filter. All the operations of the analytical system are controlled by a Macintosh computer (Quadra 950). The control program was written in LabVIEW which is a graphical programming language and well applicable to fermentation control. The software communicates with detectors, data acquisition, data analysis and presentation. The system can programmatically control up to 50 devices. Mammalian cell batch culture was used as an example of the application of the system. The system consists of a laboratory fermenter with a continuous sample withdrawal filter and an analysis system where glucose, lactate and ammonia, lactate dehydrogenase and biomass were measured. Cell viability was estimated by microscopic assay with trypan blue. pH and Oxygen were also measured. The system response was fast and yields a large number of reliable and precise analytical results which can be of great importance in the monitoring and control of mammalian cell culture conditions. |