DD254028A1 - METHOD FOR CONTROLLING AND CONTROLLING MICROBIAL FABRIC CONVERSION PROCESSES - Google Patents

Abstract

The method is used to control and control aerobic or anaerobic microbial metabolism and may be used for product and biomass production processes, such as recovery of fermentation products or baker's yeast. The basis of the control and control of the processes is the specific performance capability of the microorganisms, which correlates closely with the agglutination behavior with the addition of agglutination-inducing substances. According to the invention, the current rate of cell agglutination is determined, compared with a microorganism- and process-specific optimal value and, in the case of deviations, this is corrected by appropriate process-influencing measures.

Description

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Field of application of the invention

The invention relates to a method for controlling and controlling aerobic or anaerobic microbial metabolism. It can be used in all of the processes in which cell surface properties play a significant role in the performance of the microorganisms employed, such as preferably in the recovery of fermentation products such as ethanol, butanol, lactic acid and the like, but also in baker's yeast production and the like.

Characteristic of the known technical solutions

Processes for microbial metabolic conversion are known in large numbers and they are becoming increasingly important. They aim for the highest possible productivities, product concentrations and substrate yields. There are a variety of microbiological, technical and technological solutions (eg new microorganism strains, higher biomass concentrations, reduction of product inhibition, optimization of the technical system, etc.). Since these microorganisms are very easily subject to power fluctuations, high demands are placed on the control and control of such processes.

An essential criterion for the performance of the entire system of the metabolic transformation is the specific performance of the microorganisms used. This is dependent on a large number of biotic and abiotic factors (pH, temperature, limitations, irritations, etc.) and maximum performance is achieved only under optimal conditions. In addition, for economic reasons, it is necessary to use the microorganisms as often and as long as possible since their reinvestment causes additional costs. With the extension of the duration of use but decreases in microorganism-specific periods of performance. So it is necessary to constantly determine the specific performance, in order to recognize changes of the same and to be able to intervene in a timely manner. For example, the specific product formation rate is calculated based on several parameters, such as current biomass concentration, current product concentration, fermentor content, residence time, substrate currents, and the like. For some of these parameters there are gauges. Overall, the values are available only after a long time, and they have no current reference to the immediate course of the process, so that when a decrease in the specific power no direct process influence is possible.

Known methods for process control and control usually serve to maintain certain process conditions, which are previously determined to be particularly favorable for a high activity of the microorganisms (DE-OS 1080048, DE-OS 1442076, DE-OS 1953430, DE-OS 2217909).

The goal of current research is focused on process control set points, which provide important parameters such as e.g. correlate to the specific product formation rate. Thus, it has recently been known that there is a close correlation between the dehydrogenase activity and the product formation rate (WP-C 12 N / 289970). However, with a measurement method based thereon, only the potential product formation rate (e.g., the potential fermentation ability in ethanol production) can be determined. ,

Although this makes it possible to make a statement about the achievable performance of the microorganisms under certain conditions, the specific power actually achieved in the process can not be derived directly from this, since this depends on a large number of further influencing variables. Thus, the dehydrogenase activity as a reference variable for the process control is subject to a number of uncertainty factors and given a safe process control only in individual cases.

Object of the invention

The aim of the invention is the control and control of microbial material conversion processes by means of a method for the rapid and effective characterization of the process state in order to be able to influence immediately disturbances of the process.

Explanation of the essence of the invention

The invention has for its object to determine a characteristic that correlates with the current specific performance of the microorganisms and can be taken on the basis of influence on the course of the process. Microbial cells react with receptor-specific proteins, such as. As immune sera, natural antibodies and lectins, if on the cell surface, the corresponding receptors are present. The reaction can be described by quantitative determination of the rate of agglutination.

The specific performance of many industrially used microorganisms depends to a significant extent on transport lengths between the cell interior and the surrounding medium. Substrate entry and product leakage, and associated specific turnover rates and inhibition behavior, are strongly influenced by the nature of the cell surface.

It has been found that there is a close correlation between the agglutination rate of the microorganisms with the receptor-specific proteins determined under standardized conditions and their specific performance.

If, for example, aging phenomena of the cells or other influences, such as suboptimal fermentation parameters (pH, temperature, etc.), limitations, inhibitions, change the specific performance of the microorganisms, the rate of agglutination also changes.

According to the invention, the object has been achieved in that the agglutination behavior caused by the reaction of agglutination-inducing substances with the ZeMwand of the microorganisms used is selected as a direct measure of the current specific performance of microorganisms by determining the rate of cell agglutination and with a microorganism and process-specific optimal value is compared. This optimum value is a specific value for the particular microorganism and the process, which is achieved under optimum conditions and which corresponds to the maximum achievable specific performance under these conditions.

As agglutination-inducing substances immune sera, natural antibodies or lectins are used. In processes for aerobic biomass breeding or for aerobic or anerobic product formation, a process management is aimed at, which is directed to the constancy of the process-specific optimal values.

Depending on the receptor-specific proteins used for agglutination, the specific optimal value may be a maximum or a minimum.

Thus, the agglutination rate of, for example, a fermentation process microorganism cells removed by addition of a specific agglutination-inducing substance is determined immediately quantitatively. From this, due to the close correlation, current values for the specific performance of the microorganisms can be derived.

If it decreases, this can be determined immediately on the basis of the rate of agglutination, and on the basis of this signal it is possible to influence the process without delay by, for example, controlling the process. B. the activity of the biomass is brought by regeneration or partial replacement back to their specific optimal value.

Furthermore, on the basis of the determined agglutination rate, a decision is possible within which deviation from the specified control value, for example, a regeneration of the biomass is still useful.

This signal is also a key variable for batch processes. Thus, z. For example, the point in time at which a continuation is no longer effective due to the low specific performance is determined. Unnecessary extensions of the fermentation times, which also lead to losses in yield, can thus be avoided. The invention will be explained in more detail with the following examples.

embodiments example 1

In a stirred fermentor with a working volume of 51, a back yeast strain of the species Saccharomyces cerevisiae was aerobically bred with glucose as a carbon source. The glucose feed was controlled so that the extracellular ethanol concentration was below 3 g / L. The nutrient medium contains all the necessary mineral nutrients as well as vitamins in the form of yeast extract for a yeast yield of about 10 g of yeast dry matter-fHTS-l / i -.-. The yeast concentration was about 1 g HTS / l. The ~~ fermentation parameters were: pH = 4.5 T = 33 ⁰ C, aeration rate = 50 l / lh

The rate of agglutination of the baker's yeast during the reaction of its cell wall with lentil lectin was determined within 10 minutes after removal from the fermentor. In Fig. 1 the results are shown graphically, in addition to the agglutination rate 1, the ethanol concentration 2, the substrate concentration 3 and the biomass concentration 4 as a function of the duration of the experiment.

The rate of agglutination initially increases until the biomass 2 has reached a concentration of about 10 HTS / I. From this point in time, a decrease is recorded due to wasting of the nutrient solution and occurrence of nutrient imitation.

Point A indicates the minimum in the agglutination curve and the timing of nutrient additions to the fermentor.

After completion of the nutrient supply and abolition of Limitationsbedingungen the speed of the

Agglutination to a maximum value B again. *

The driving force of baker's yeast was determined at points a and B according to TGL 25111/05. The assignment of the measured values to the respective agglutination shows the correlation between the two variables:

Table 1: Correlation between agglutination and driving force of baker's yeast

Yeast motive agglutination rate

mlCO ₂ / 110min. (ΔΕ / min.).

A 51 0.14

B 87 0.17

Example 2

In the Rührfermentor described above, in each case after appropriate aerobic cultivation and using the cultivated baker's yeast as fermentation yeast according to quality A or B (see Example 1) successively two discontinuous ethanolic fermentations carried out. ,

Before the start of the fermentation each aeration is suppressed, the residual air displaced by CO ₂ gassing from the reactor, added in portions 135g glucose / I and nutrients for a yeast increase of about lOgHTS / linden fermentor. Table 2 summarizes the most important results of the two fermentation processes:

Table 2: Results of two fermentation processes with yeasts of different start agglutination

attempt Final gär ethanol agglutination 0 anaerobic yeast ethanol duration synthesis keis Conc. rate0 begin g EtOH / l H g EtOH / ΔΕ / min. 0.11 g HTS.h 0.135 A 60 8th 0.3 0.14 B 63 6 0.45 0.17

The results of both examples demonstrate the advantage of the measured variable agglutination rate and its suitability as a process variable: A high agglutination speed guarantees both a high driving force and a high fermentation activity and a short fermentation time during the fermentation process. A low agglutination rate signals sub-optimal aerobic seed conditions and the need for process corrections, such as, if necessary, yeast replacement in the fermentation process.

Example 3

In the stirred fermentor described above, continuous fermentation with yeast retention was carried out with a Saccharomyces cerevisiae fermentation feast strain, its maximum agglutination rate of 0.18 A / min (change in extinction per minute). The determination of the agglutination rate was carried out analogously to Example 1.

For Heferückhaltung the fermentor was equipped with a membrane module provided continuously a yeast-free, ethanol-containing filtrate, while a sucrose solution corresponding to a dilution rate of D = 0.25 h "was ¹ metered into the fermentor. The sucrose solution contained all the necessary nutrients and vitamins The yeast concentration was 30 g HTS / I and remained constant during the process with the aid of a special control technique, the pH was 4.5 and the temperature was 33 ° C.

FIG. 2 shows the course of the biomass concentration 2 of the agglutination rate 1, the ethanol concentration 3 and the specific ethanol synthesis rate 4.

The fermentation parameters could be kept constant over a period of 116h. Between the 116th and 117th hours there was a decrease in the rate of agglutination, which was used as an opportunity to exchange the entire yeast mass in the fermentor at time C for fresh yeast at an agglutination rate of 0.18 AU / min.

The fermentation yeast taken from the fermentor was fed to a regeneration fermenter where, with the aid of aerobic conditions and nutrient solution dosing, depending on the process variable agglutination, the yeast was regenerated, with the result that the measured agglutination rate at the end of the treatment was 0.135ΔΕ / min. The fermentation yeast could be fed with a good fermentation activity to another analog fermentation process.

Claims (2)

1. A process for the control and control of microbial fermentation processes, characterized in that the rate of cell agglutination of the microorganisms after addition of agglutinin-causing substances is determined under standardized conditions and compared with a predetermined, process-specific value and are carried out deviations from this value, process-influencing measures. 2. The method according to claim 1, characterized in that receptor-specific proteins such as antibodies, lectins or other agglutination-inducing substances are used for agglutination.