microaerobic fermentation of lactobacillus acidophilus within gut microbiome ... · 2019. 8....

1
Microaerobic Fermentation of Lactobacillus acidophilus within Gut Microbiome Physiological Conditions by BioFlo ® Bioprocess Control Stations Ying Yang 1 , Zachary Greenleaf 1 , William Kann 2 , and Ma Sha 1 1 Eppendorf, Inc., Enfield, CT, USA 2 Eppendorf Manufacturing Corporation, Enfield, CT, USA Contact: [email protected] Abstract There is a growing interest among food & feed and biofuel industries for microaerobic fermentation, a fermentation process at close to anaerobic condition but still requiring small amounts of oxygen. The dissolved oxygen level is rather low, often less than 5 %. Also, there is a huge interest in probiotics production due to their great health benefits, and many probiotics are beneficial bacteria that naturally thrive in the human gut microbiome under microaerobic conditions. In this application note, we successfully performed microaerobic fermentation of a probiotic strain, Lactobacillus acidophilus, at a very low oxygen level (< 1 %, representing the natural physiological condition of human gut microbiome) using BioFlo ® 120 and 320 control stations. The microaerobic fermentation was carried out in BioBLU ® 3f Macrosparge Single-Use Vessels. Through automatic gas mix and control, we demonstrated the feasibility of precisely controlling the dissolved oxygen (air saturation) at 4 % throughout the fermentation process by both BioFlo 120 and 320. We showed robust growth of Lactobacillus acidophilus which reached a biomass concentration of 3.13 x 10 9 CFU/mL by BioFlo 120 and 3.73 x 10 9 CFU/mL by BioFlo 320. www.eppendorf.com Eppendorf ® , the Eppendorf Brand Design, and BioBLU ® are registered trademarks of Eppendorf AG, Germany. BioFlo ® is a registered trademark of Eppendorf, Inc., USA. All rights reserved, including graphics and images. Copyright © 2019 by Eppendorf AG. > The BioFlo 120 and BioFlo 320 control stations are feasible to maintain dissolved oxygen level at 4 % which equals an oxygen concentration of 0.8 %. > L. acidophilus showes a robust growth under both control stations, yielding in a maximum biomass of 3.13 x 10 9 CFU/mL and 3.73 x 10 9 CFU/mL, respectively. > Probiotics available on the market are often packed with 20 to 40 billion CFU per capsule. With the assumption of 30 billion Lactobacillus CFU per capsule and L. acidophilus is the only strain, one single run produced 313 capsules per BioBLU 3f vessel controlled by BioFlo 120, and 373 capsules by BioFlo 320. This application note shows a detailed example of precisely controlling the DO at 4 % to support microaerobic fermentation, and will be very helpful for peers in the field of microbiome to apply to their specific bioprocesses. Conclusion Parameter Configuration Vessel BioBLU 3f Inoculation density 1 % (v/v), 30 mL inoculum to a 3 L working volume Dissolved oxygen (DO) 4 % air saturation, ~ 0.8 % oxygen environment Agitation Magnetic drive, 150 rpm Gassing Automatic gas flow and mix Temperature 37 °C, cooling controlled by a single stainless-steel cooling finger pH 6.5 ± 0.1 for the first 4 hours, then 5.0 ± 0.1 for the remaining of the culture, controlled by external 4 mol/L sterile sodium hydroxide solution and 2 mol/L sterile hydrochloric acid solution Impeller Three Rushton impellers Sparger Macrosparger B Mode A 0 100 200 300 400 500 600 700 0 2 4 6 8 10 12 14 16 CFU x10 7 /mL OD600 y= 39,633x R²= 0,9977 0,00 0,50 1,00 1,50 2,00 2,50 3,00 3,50 4,00 0,0 1,0 2,0 3,0 4,0 5,0 6,0 7,0 8,0 9,0 10,0 0 5 10 15 20 25 30 35 CFU (x 10 9 /mL) OD 600 Time (h) BioFlo 120 BioFlo 320 Figure 1: Serial dilution of the Lactobacillus acidophilus suspension for colony forming units (CFU) counting. The CFUs appeared visible 48 hours post inoculation Scope Providing a good reference for probiotic and microbiome studies under microaerobic conditions. Process Parameter and Set-up Table 1: Bioprocess control stations set-up. Figure 6: Standard curve correlating OD 600 and CFU of Lactobacillus acidophilus . > Number of CFU (N) on each agar plate are counted > Volumetric CFU calculation: colony-forming units per milliliter = N x 10 6 / 0.1 mL = N x 10 7 CFU/mL. > The calculated correlation is: CFU/mL = 39.63 x OD 600 x 10 7 . Figure 2: BioFlo ® 120 control station with a BioBLU 3f Single- Use Vessel. Figure 3: BioFlo ® 320 control station with a BioBLU ® 3f Single- Use Vessel. B A Results Figure 4: DO (A) and sparge (B) parameter setup in BioFlo 120. Figure 5: DO (A) and sparge (B) parameter setup in BioFlo 320. Figure 8: Growth curves of Lactobacillus acidophilus . > Exponential growth phase between 8 and 12 h for both runs. > Maximum OD 600 at t=14 h, with an OD 600 of 7.9 for the BioFlo 120 and an OD 600 of 9.4 for the BioFlo 320 control station. Figure 7: Trends for the first 24 hours after inoculation: > pH adjustment form 6.5 to 5.0 at t= 4h > DO-level was maintained at 4 % > Thanks to the 4 integrated TMFCs, DO control of the BioFlo 320 was more stable and precise > The DO peaks for BioFlo 120 is due to that PID (proportional-integral-derivative) modulates the combined impact of control through a single TMFC of nitrogen and air. BioFlo ® 120 BioFlo ® 320 L. acidophilus strain: ATCC ® 4356™

Upload: others

Post on 22-Jan-2021

8 views

Category:

Documents


0 download

TRANSCRIPT

Page 1: Microaerobic Fermentation of Lactobacillus acidophilus within Gut Microbiome ... · 2019. 8. 29. · Microaerobic Fermentation of Lactobacillus acidophilus within Gut Microbiome Physiological

Microaerobic Fermentation of Lactobacillus acidophilus within Gut Microbiome Physiological Conditions by BioFlo® Bioprocess Control StationsYing Yang1, Zachary Greenleaf1, William Kann2, and Ma Sha1 1Eppendorf, Inc., Enfield, CT, USA 2Eppendorf Manufacturing Corporation, Enfield, CT, USA

Contact: [email protected]

Abstract

There is a growing interest among food & feed and biofuel industries for microaerobic fermentation, a fermentation process at close to anaerobic condition but still requiring small

amounts of oxygen. The dissolved oxygen level is rather low, often less than 5 %. Also, there is a huge interest in probiotics production due to their great health benefits, and many

probiotics are beneficial bacteria that naturally thrive in the human gut microbiome under microaerobic conditions. In this application note, we successfully performed microaerobic

fermentation of a probiotic strain, Lactobacillus acidophilus, at a very low oxygen level (< 1 %, representing the natural physiological condition of human gut microbiome) using

BioFlo® 120 and 320 control stations. The microaerobic fermentation was carried out in BioBLU® 3f Macrosparge Single-Use Vessels. Through automatic gas mix and control, we

demonstrated the feasibility of precisely controlling the dissolved oxygen (air saturation) at 4 % throughout the fermentation process by both BioFlo 120 and 320. We showed robust

growth of Lactobacillus acidophilus which reached a biomass concentration of 3.13 x 109 CFU/mL by BioFlo 120 and 3.73 x 109 CFU/mL by BioFlo 320.

Your local distributor: www.eppendorf.com/contact · Eppendorf AG · Barkhausenweg 1 · 22339 Hamburg · Germany · www.eppendorf.com

www.eppendorf.comEppendorf®, the Eppendorf Brand Design, and BioBLU® are registered trademarks of Eppendorf AG, Germany. BioFlo® is a registered trademark of Eppendorf, Inc., USA. All rights reserved, including graphics and images. Copyright © 2019 by Eppendorf AG.

> The BioFlo 120 and BioFlo 320 control stations are feasible to maintain dissolved oxygen level at 4 % which equals an oxygen concentration of 0.8 %. > L. acidophilus showes a robust growth under both control stations, yielding in a maximum biomass of 3.13 x 109 CFU/mL and 3.73 x 109 CFU/mL, respectively. > Probiotics available on the market are often packed with 20 to 40 billion CFU per capsule. With the assumption of 30 billion Lactobacillus CFU per capsule and L. acidophilus is the only strain, one single run produced 313 capsules per BioBLU 3f vessel controlled by BioFlo 120, and 373 capsules by BioFlo 320.

This application note shows a detailed example of precisely controlling the DO at 4 % to support microaerobic fermentation, and will be very helpful for peers in the field of microbiome to apply to their specific bioprocesses.

Conclusion

Parameter ConfigurationVessel BioBLU 3f

Inoculation density 1 % (v/v), 30 mL inoculum to a 3 L working

volumeDissolved oxygen (DO) 4 % air saturation, ~ 0.8 % oxygen environmentAgitation Magnetic drive, 150 rpmGassing Automatic gas flow and mix

Temperature 37 °C, cooling controlled by a single stainless-steel

cooling finger

pH

6.5 ± 0.1 for the first 4 hours, then 5.0 ± 0.1 for the

remaining of the culture, controlled by external

4 mol/L sterile sodium hydroxide solution and 2

mol/L sterile hydrochloric acid solutionImpeller Three Rushton impellersSparger Macrosparger

BMode

A

0

100

200

300

400

500

600

700

0 2 4 6 8 10 12 14 16

CFU

x1

0 7 /m

L

OD600

y= 39,633xR²= 0,9977

0,00

0,50

1,00

1,50

2,00

2,50

3,00

3,50

4,00

0,0

1,0

2,0

3,0

4,0

5,0

6,0

7,0

8,0

9,0

10,0

0 5 10 15 20 25 30 35

CFU

(x

109

/mL)

OD

60

0

Time (h)

BioFlo 120 BioFlo 320BioFlo 320

Figure 1: Serial dilution of the Lactobacillus acidophilus suspension for colony forming units (CFU) counting. The CFUs appeared visible 48 hours post inoculation

Scope

Providing a good reference for probiotic and microbiome studies under microaerobic conditions.

Process Parameter and Set-up

Table 1: Bioprocess control stations set-up.

Figure 6: Standard curve correlating OD600 and CFU of Lactobacillus acidophilus. > Number of CFU (N) on each agar plate are counted > Volumetric CFU calculation: colony-forming units per milliliter = N x 106 / 0.1 mL = N x 107 CFU/mL. > The calculated correlation is: CFU/mL = 39.63 x OD600 x 107.

Figure 2: BioFlo® 120 control station with a BioBLU 3f Single-Use Vessel.

Figure 3: BioFlo® 320 control station with a BioBLU® 3f Single-Use Vessel.

BA

Results

Figure 4: DO (A) and sparge (B) parameter setup in BioFlo 120. Figure 5: DO (A) and sparge (B) parameter setup in BioFlo 320.

Figure 8: Growth curves of Lactobacillus acidophilus. > Exponential growth phase between 8 and 12 h for both runs. > Maximum OD600 at t=14 h, with an OD600 of 7.9 for the BioFlo 120 and an OD600 of 9.4 for the BioFlo 320 control station.

Figure 7: Trends for the first 24 hours after inoculation:

> pH adjustment form 6.5 to 5.0 at t= 4h > DO-level was maintained at 4 % > Thanks to the 4 integrated TMFCs, DO control of the BioFlo 320 was more stable and precise > The DO peaks for BioFlo 120 is due to that PID (proportional-integral-de rivative) modulates the combined impact of control through a single TMFC of nitrogen and air.

BioFlo® 120 BioFlo® 320

L. acidophilus strain: ATCC® 4356™