Lactobacillus

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Omega Yeast Labs OYL-605 Lactobacillus Blend; photo by Stephen Little.

Lactobacillus (often referred to as Lacto) is a genus of Gram-positive, rod-shaped lactic acid bacteria (LAB) which produces acidity and sour flavors in the form of lactic acid (and sometimes acetic acid) found in lambics, Berliner Weiss, sour brown ales, and gueuze. All Lactobacillus species are aerotolerant anaerobes, which means they grow anaerobically but can also grow in the presence of oxygen [1]. There are more than 100 species, many of which are found in the human gastrointestinal track [2][3]. In addition to beer, some species of Lacto are also used to ferment yogurt, cheese, sauerkraut, pickles, wine, cider, kimchi, cocoa, and kefir [4]. Lacto can form a pellicle (need reference). See Pediococcus, Brettanomyces, Saccharomyces, and Mixed Cultures charts for other commercially available cultures. See the Sour Worting and Mixed Fermentation pages for brewing techniques with Lactobacillus. See the Alternative Bacteria Sources section for culturing Lactobacillus from grains, yogurt, probiotics, and other sources.

Commercial Lactobacillus Cultures

Culture Charts

Name Mfg# Taxonomy CO2 Producer (Het/Hom) Starter Note Fermentation/Other Notes
Brewing Science Institute L. delbrueckii Lactobacillus delbrueckii A Lactobacillus bacteria that produces a clean lactic sourness.
White Labs WLP677 L. delbrueckii (potentially misidentified) Heterofermentative [5][6] no stir plate, room temp Incubate at > 90°F and < 117°F for 5-7 days for greater lactic acid production.
White Labs WLP672 L. brevis Heterofermentative [5][7] No stir plate, room temp Produced by The Yeast Bay. More hop tolerant than other Lacto strains, however TYB advises to use wort with less than 10 IBU. Temperature range: 70-95°F; 80% attenuation (this may not reflect actual attenuation of wort in a real brewery; see reference [8]). [9]
Wyeast 5335 L. buchneri Heterofermentative [5] 1L starter, 1.020 DME sterile wort, no stir plate, no O2, starter at 90°F if possible 5-7 days Incubate at 90°F for 5-7 days for greater lactic acid production.
Wyeast 5223-PC L. brevis Heterofermentative [5][7] no stir plate, room temp is fine Heterofermentative (produces lactic acid, ethanol and CO2), more hop tolerant. Does well at room temperature. AVAILABLE ONLY FROM JULY THROUGH SEPTEMBER 2014 (Michael Dawson from Wyeast indicated that this culture may return at some point). Jamie Daly indicated on MTF that he got almost no sourness after 24 hours at 100°F (37.8°C). He lowered the temperature to 90°F-95°F (32.2°C-35°C) for 36 hours, and the pH of the wort went down to 3.29. Thus, Jamie recommends 90°F-95°F (32.2°C-35°C) for 60 hours for better souring; avoid warmer temperatures. He also aerated his starter of L. (brevis 2L starter of 1.020 dme) and set it on a stir plate at 95°F [10]. The beer wort was not aerated, and the fermenter was flushed with CO2. These methods need verification.
Omega Yeast Labs OYL-605 L. brevis, delbrueckii, and plantarum blend Hetero/Hetero [5] 1 liter starter at room temperature for 24-48 hours. no stir plate Quick souring. Pitch into 65°F-90°F. Holding temperature is not required. No longer contains delbruekii [11]. Don't use any hops if possible. 2 IBU is a good target if hops must be used [12].
GigaYeast GB110 L. delbrueckii?[13] Heterofermentative Use 2 liters at 1.040 with high quality yeast nutrient. Keep as close to 86°F (30°C) as possible for 3-4 days with frequent rousing (no stir plate) [14]. Lactic Acid Bacteria are inhibited by hops, high gravity and low temperatures. You can adjust sourness by increasing or decreasing these variables. More than 7 IBU, gravity above 1050 or temps below 65 F will increase the time to sour or lead to reduced overall souring.

We recommend brewing with GB110 in one of three ways. I) “Hot Start”: Pitch GB110 to wort at 98 F with little or no hops for 48-72 hrs. Wort may be soured before kettle boil or after. If soured before kettle boil, boil with hop additions as usual. If soured after kettle boil cool wort and pitch yeast. II) “Co-Pitch”: Pitch GB110 into a primary with yeast of your choice at 68-72 F. Wort that is less than 1050 and 7 IBU will typically be very sour in 2-3 weeks. III) “Secondary”: Pitch GB110 after primary fermentation for an aged sour. Souring by this method typically requires several months. Adding simple sugars or fruit etc. will enhance souring in the secondary [15]. Sometimes referred to as GigaYeast's "Fast Acting Lacto". This strain is hop sensitive [16].

RVA Yeast Labs RVA 600 L. rhamnosus GG Homofermentative No starter necessary Homofermentative Lacto strain found in probiotics; sensitive to hops; does well at room temperature.
SouthYeast Labs Lactobacillus 1 Unknown Heterofermentative Source: Spontaneously infected beer (South Carolina). Best suits Light sours, gose, farmhouse saison (medium/high acidity).
SouthYeast Labs Lactobacillus 2 Unknown Homofermentatative Source: Prickly pear fruit (South Carolina). Best suits strong sours, and lambic (high acidity).
Inland Island Brewing & Consulting INISBC-991 L. brevis Heterofermentative Produces more lactic acid at higher temperatures and in low hop worts. 70-95 F Temperature Range
Inland Island Brewing & Consulting INISBC-992 L. delbruekii Homofermentative Produces more lactic acid at higher temperatures and in low hop worts. 70-95 F Temperature Range
Inland Island Brewing & Consulting INISBC-932 L. fermentum Heterofermentative

Manufacturer Tips

Omega Yeast Labs on OYL-605

The following is a statement by Lance Shaner, owner of Omega Yeast Labs:

Lance Shaner: Full disclosure: I own Omega Yeast Labs. Pitching at 120F is a bad idea with this blend. The bug doing most of the work in this blend is Lactobacillus plantarum. The best temp for plantarum is 80-90F. It does not work [as well] over 100F. Also, we regularly make a 1 liter starter with the Lacto blend for faster souring. Simply pitch the contents of the pouch into 1 liter of sterile 1.040 wort and let sit for 24 hours at 70-80F before pitching (no need to stir). Adi Hastings mentioned the imperial stout we just kettle soured. We previously brewed a Berliner using the same method. At 17 hours, pH was at 3.42 and temp was 75F (original pitch temp was 85F). At 40 hours, pH was 3.24, at which time we boiled. Lower pH in the Berliner compared to the stout at 17 hours likely has to do with different buffering capacities in different worts.

Wyeast on 5335

The following is an excerpt with Jess Caudill, Brewer/Microbiologist, at Wyeast Laboratories, Inc. concerning usage of Wyeast 5335 and making a Berliner Weissbier.

  1. Use 5335.
  2. If using our 5335, don’t use ANY hops. You can always blend in some IPA or hopped wort after souring takes place if you really need some bitterness or hop flavor/aroma in the beer.
  3. From one 5335 pack, make a 1L starter with 1.020 DME sterile wort. No O2! Incubate at 90°F if possible for 5-7 days.
  4. Brew your 5 gallons of wort. Again… no hops. Sterilize the wort. (No need for sour mashes). Cool to 90°F and add 1L 5335 starter. No O2. Try to maintain 90°F for 5-7 days depending on how sour you want the beer.
  5. After 5-7 days, cool wort to around 68. Pitch with a low pH tolerant strain such as 1007 or 2124. No O2. Ferment for around 1-2 weeks… until you hit terminal.
  6. Package beer. If bottle conditioning, use 4021 as a bottling strains. Very tolerant to low pH.

RVA Yeast Labs on RVA 600

A great lactic acid bacterial strain that will add a pleasant tangy sourness. RVA 600 is a pure culture of Lactobacillus rhamnosus GG which is found in many commercial probiotic products which have been shown in clinical studies to have many beneficial effects. These are homofermentative (only produces lactic acid, no carbon dioxide or ethanol) and are hop-sensitive. For more pronounces souring add before you add your yeast. You can sour to taste then add a yeast strain to outcompete the bacteria. Again, hop sensitive so easy on them…or dry hop the heck out of it! You may also want to experiment with blending sour low hop beer with an ale strain beer. [17]

... the amount of bacteria in our homebrew units should eliminate the use of a starter. Pitching on the warm side will speed up the souring but RVA 600, a pure culture of Lactobacillus rhamnosus GG, the first commercially available probiotic propagated for use in brewing, does just fine at room temp. We had originally developed RVA 600 as a mix but fell in love with the pure strain.[18]

SouthYeast Labs on Lactobacillus 1 and 2

The L2 strain grows best at 86°F-100°F (30°C-37.7°C), and does not work well over 100°F. Keep IBU's low to none. L1 will likely be discontinued due to high amounts of acetic acid production [19].

White Labs on WLP672

"It is intended for secondary, so you only need to do a starter if you are doing a primary fermentation with it. DME would be the best substrate... Since its a Lacto species, you don't really want to aerate it. A slow stir-plate would be good, to keep it moving, but not much more than that." - Sarah Neel, White Labs, Sales and Customer Service (quoted with permission).

General Advice

Starters and Pitching Rate

In addition to the starter information given in the Manufacturer Tips above, this section includes general advice for Lactobacillus starters for homebrewers and brewers without access to MRS media. MRS media is much more expensive than the materials required for the method below (DME, apple juice, chalk, and yeast nutrients). See External Resources for additional starter guides.

Pitching ~0.5-1 liter per ~20 liters of wort (~0.75-1 gallon per barrel) of Lactobacillus starter is the general guideline. The exact advisable pitching rates of commercial cultures may differ from manufacture to manufacturer. [20]. Counting the exact number of cells can be difficult to achieve due to the small size of bacteria cells, so starter volumes are generally used instead when talking about pitching rates for Lactobacillus [21].

Starter mediums that brewers have used include unhopped DME wort starters and apple juice starters. These tend to be adequate for many brewers. However, Samuel Aeschlimann from Eureka Brewing Blog showed that using DME with a little bit of apple juice, chalk, and yeast nutrients provides close to optimal cell densities that match cell densities of using expensive MRS media.

Samuel Aeschlimann's Starter Procedures:
  1. Make a 1 liter starter of 1.040 SG (10°P) Dried Malt Extract wort with 10% apple juice + 20 grams of chalk (CaCO3) + yeast nutrients for growth results that are close to MRS media growth results (as per Samuel Aeschlimann from Eureka Brewing Blog). The chalk won't dissolve into solution; don't worry about it. [22].
  2. Best practice is that starters should not be aerated, although there may be an exception to this for L. brevis [10]. Some people prefer to stir their starter with an airlock in order to keep the bacteria in suspension, others do not use a stir plate and keep the starter still.
  3. The starter should be held at the temperature best suited for the culture as shown in the Culture Charts.
  4. Reference the above Culture Charts for how long the starter should be incubated for before pitching. If a stir plate is not used, one indication that the starter is done will be when the top of the starter begins to clear [23].
  5. The chalk is not desirable to pitch into the beer because of its buffering effect. The chalk will sediment much sooner than the Lacto due to the chalk particles being much larger [23]. After the chalk sediments, pour all of the liquid from the top of the starter into the wort/beer, and leave the chalk sediment behind. Avoid cold crashing because it can have an adverse effect on the bacteria's health [24][22].

See Lacto Starters, by Bryan Heit of Sui Generis blog for additional information on Lactobacillus starters.

Cell Growth

"I typically grow it by itself anaerobically in MRS media. Seems to work very well and results in good growth. I've personally had the best success with MRS media and in an anaerobic environment, though I know some Lactobacillus strains grow aerobically just fine. The problem with growing lactic acid bacteria is the acid they produce will eventually inhibit their own growth. MRS contains a buffer to help combat the drop in pH as a result of LAB metabolism, which keeps the pH around 6-6.5 (I think) for optimal growth. I usually grow them at 35 C, but sometimes incubator space is at a premium (like right now) and I just [use a stir plate with an airlock]" [25]. - Nick Impellitteri from The Yeast Bay on general Lactobacillus cell growth

Hop Tolerance

"There is a fair bit of research into hop tolerance out there; its not a simple topic as a number of factors come into play to produce hop tolerance. To make things even more complicated, hop tolerance is an inducable trait in many Lacto species - meaning that a seemingly susceptible strain can become resistant by culturing in ever-increasing doses, and a seemingly resistant strain can become susceptible after a generation or four in a hop-free media.

I've been trying to generate a permanently high-alpha acid resistant lacto strain for a few months now. I've been culturing L. brevis in escalating IBU wort (starting at 10, currently at 25). Every 4th generation (1 generation = a subculture of a stationary-phase lacto culture, not as in # cell divisions) I pass it through 2 generations of an IBU-free media to try and select for strains which maintain this resistance. This seems to have worked upto ~18 IBU, but past that point the resistance appears to remain inducable. I'm hoping a few more generations will provide me with a permanently tolerant strain.

There are some other option; I've purified (but didn't keep - doh) some pretty resistant strains from grain by by making plates where you half-fill a plate, on an angle, with a high-IBU wort, and then overlay that with a no-IBU wort. This gives you a gradient plate, with low-IBUs on the end where the hopped-wort layer is thinnest and high IBUs where it is thickest. Some of those strains were resistant to over 30IBU, but being early in my yeast farming days I didn't bother keeping those." - Bryan Heit of Sui Generis Brewing blog on Lactobacillus and Hop Tolerance [26]

Storage

Regarding dry Lactobacillus, such as probiotics or Dry Yeast for Sour Ales BlackManYeast products: "Yes, refrigerate them. In the lab course I run we compare probiotics stored at room temp versus in the fridge - viable bacterial numbers dip off ~80x faster in non-refrigerated samples."

In regards to liquid cultures and storage: "I'm not sure about the liquid cultures - I freeze mine at -80°C (lab freezer with 20% glycerol), which (stores) indefinitely. As a rule refrigerated liquid cultures should last longer... but there is anecdotal evidence (for some species) of poorer survival of refrigerated versus room temp in liquid cultures. IMO, stable temps are likely more important for non-frozen stocks than hitting an 'ideal' temperature." [27] - Bryan Heit of Sui Generis Brewing blog.

It is also recommended to store liquid cultures of Lacto with a few grams of a buffering chemical such as potassium phosphate, calcium sulfate (gypsum), or calcium hydroxide (pickling lime). The exact amounts should be adjusted to reach a pH of about 4.0 for the entire solution (begin with 1 or 2 grams per liter, and adjust as needed) [28].

Commercially available Lactobacillus strains and their pH change over time

All data provided by Matt Humbard. Similar results were reported by Lance Shaner's 100% Lactobacillus Fermentation experiment.

pH change at 86°F

pH change of Lactobacillus at 86°F. Data provided by: Matt Humbard
Time (hours) Wyeast Lactobacillus buchneri White Labs Lactobacillus brevis White Labs Lactobacillus delbrueckii Omega Lactobacillus plantarum
0 5.9 5.9 5.9 5.9
6 5.57 5.13 5.59 4.81
18 4.4 3.94 4.62 3.6
24 4.2 3.78 4.6 3.45
75.5 3.88 3.44 4.46 3.27
120 3.85 3.4 4.4 3.25

pH change at 98°F

pH change of Lactobacillus at 98°F. Data provided by: Matt Humbard
Time (hours) Wyeast Lactobacillus buchneri White Labs Lactobacillus brevis White Labs Lactobacillus delbrueckii Omega Lactobacillus plantarum
0 5.9 5.9 5.9 5.9
6 5.61 5.05 5.55 5.02
18 4.15 3.74 4.54 3.22
24 4.05 3.67 4.54 3.2
75.5 3.5 3.31 4.32 3.22
120 3.5 3.29 4.3 3.21

pH change at 102°F

pH change of Lactobacillus at 102°F. Data provided by: Matt Humbard
Time (hours) Wyeast Lactobacillus buchneri White Labs Lactobacillus brevis White Labs Lactobacillus delbrueckii Omega Lactobacillus plantarum
0 5.9 5.9 5.9 5.9
6 5.45 5.02 5.5 5.11
18 4.13 3.73 4.61 3.4
24 4.06 3.6 4.58 3.29
75.5 3.72 3.33 4.47 3.23
120 3.68 3.3 4.4 3.2

pH change at 108°F

pH change of Lactobacillus at 108°F. Data provided by: Matt Humbard
Time (hours) Wyeast Lactobacillus buchneri White Labs Lactobacillus brevis White Labs Lactobacillus delbrueckii Omega Lactobacillus plantarum
0 5.9 5.9 5.9 5.9
6 5.6 4.95 5.51 4.99
18 4.49 3.71 4.8 3.54
24 4.37 3.52 4.6 3.45
75.5 4.33 3.35 4.62 3.34
120 4.29 3.3 4.51 3.3

Metabolism

Editor's note: the following section was reviewed for accuracy by MTF members Bryan Heit, Matt Humbard, Lance Shaner, and Richard Preiss.

Types of Metabolism

Homolactic and Heterolactic pathways [29]

All metabolism by Lactobacillus, including growth, will require sugar to be consumed and lactate (lactic acid) to be produced. Two categories of metabolism exist, homolactic and heterolactic. In summary, homolactic fermentation produces only lactic acid, while heterolactic fermentation produce lactic acid, CO2, and ethanol/acetic acid [30].

Homolactic

Homolactic metabolism is described as the cell catabolizing one molecule of glucose to yield two molecules of pyruvate, which is then further reduced to two molecules of lactate (lactic acid). Homolactic fermentation only allows the fermentation of hexoses (glucose, mannose, etc.). Homolactic metabolism follows the Embden-Meyerhof-Parnas pathway [29].

Heterolactic

Heterolactic metabolism is described as the cell catabolizing one molecule of glucose into one molecule of CO2, one molecule of glyceraldehyde phosphate, and one molecule of acetyl phosphate. The molecule of glyceraldehyde phosphate is reduced to one molecule of lactate, and the acetyl phosphate is reduced to one molecule of ethanol (or one molecule of acetic acid instead of ethanol, depending on its growing environment [31]). Heterolactic fermentation allows the fermentation of hexoses and pentoses [32]. Heterolactic fermentation follows the pentose phosphate pathway, or also called the phosphogluconate pathway [29].

Categories of Lactobacillus

There are three categories of Lactobacillus based on the type of fermentation they are capable of (homolactic, heterolactic, or both).

  1. Obligatory homofermentative Lactobacillus only perform homolactic fermentation, and thus only produce lactic acid [29].
  2. Obligatory heterofermentative Lactobacillus only perform heterolactic fermentation, and thus produce lactic acid, CO2, and ethanol (or sometimes acetic acid instead of ethanol) [29].
  3. Facultatively heterofermentative Lactobacillus generally are homolactic when there is an abundance of carbohydrates, but can also perform heterolactic fermentation when carbohydrates are not abundant [29].

Other factors can determine if a facultative heterofermentative species uses homolactic or heterolactic fermentation. For example, L. plantarum, which is a facultatively heterofermentative species, is homolactic without the presence of oxygen. In the presence of oxygen, however, it performs heterolactic fermentation, and produces acetic acid [33][34].

Obligatory Homofermentative [35] Obligatory Heterofermentative Facultatively Heterofermentative
L. acidophilus L. brevis L. casei
L. delbruekii L. buchneri L. curvatus
L. helveticas L.fermentum L. plantarum
L. salivarius L. reuteri L. sakei
L. rhamnosus [36] L. pontis

100% Lactobacillus Fermentation

The amount of CO2 produced is very small in heterofermentative species. Lance Shaner of Omega Yeast Labs noted that although L. brevis is classified as obligatory heterofermentative, the human eye cannot detect any CO2 production in the Omega Yeast Lactobacillus blend (OYL-605). Lance still needs to test this blend to see if it produces any CO2 at all. It is clear though that any type of Lactobacillus, regardless of whether it is heterofermentative or homofermentative, cannot produce a krausen. Krausens are sometimes seen with the use of commercially available Lactobacillus cultures. If a krausen develops in wort when it is the only culture that is pitched, this is indicative of cross contamination of Saccharomyces or Brettanomyces in either the wort, or the Lactobacillus culture itself [37]. In addition to this, heterolacti' fermentation by Lactobacillus can only produce 10-20% of the ethanol that Saccharomyces can produce [38], therefore a high level of attenuation cannot be achieved by Lactobacillus and is again a sign of cross contamination by yeast.

Lance Shaner's experiment on testing 100% Lactobacillus Fermentation showed that pure cultures of WLP677, WLP672, Wyeast 5335, Wyeast 5223-PC, and the L. plantarum from Omega Yeast OYL-605, could not fully attenuate a 1.037 SG wort. The most attenuative Lacto culture, WLP677, was only able to attenuate down to 1.03255 SG. It is likely that all species and strains of Lactobacillus available to brewers cannot fully attenuate wort. In addition, this study showed at most a 0.29% ABV in 100% Lacto fermentations (attributed to WLP677). See 100% Lactobacillus Fermentation for more information. If a higher attenuation is achieved, cross contamination of yeast is most likely the cause.

Sugar Utilization and Secondary Metabolites

For a chart and in depth discussion on what types of sugars are fermentable by different species of Lactobaccilus, as well as charts on secondary metabolites, see Matt Humbard's Physiology of Flavors in Beer – Lactobacillus Species blog article.

In summary:

  • Different species of Lactobacillus are capable of fermenting different types of sugars, including sugars that Saccharomyces may not be able to ferment.
  • All types of Lactobacillus produce different levels of secondary metabolites (compounds that are not required for the organism to live [39]) in addition to the primary metabolites discussed above. These include acetaldehyde, diacetyl, fusel alcohols, and many more compounds (see Matt's article for more details).

Foam Degradation

Some species/strains of Lactobacillus can create their own amino acids (this is to say they are prototrophic), whereas other species/strains cannot (this is to say they are autotrophic). Autotrophic Lacto can break down proteins, including foam forming proteins in beer, through a process called proteolysis [30], the breakdown of various proteins into smaller polypeptides or amino acids through the use of various enzymes [40][41][42]. Both homofermentative and heterofermentative species have been observed to have proteolytic activity [43]. This process is a large part of cheese and yogurt fermentation. Lactobacillus species that have been identified as breaking down proteins (mostly in cheese or yogurt) include Lactobacillus bulgaricus, Lactobacillus rhamnosus, Lactobacillus casei, Lactobacillus paracasei, Lactobacillus helveticus, Lactobacillus delbrueckii, Lactobacillus brevis, Lactobacillus cellobiosus, Lactobacillus fermentum, and Lactobacillus plantarum [41]. Results of using various species/strains appears to demonstrate that different species/strains are worse for degrading head retention proteins than others. For example, it's been reported that B.H. Meyer says that souring with L. delbruekii creates better head retention than souring with other species such as L. brevis. [44][45]. Different strains of the same species may also have different levels of proteolytic activity [46].

Proteolytic activity has been shown to decrease as pH falls below 5.0 for some species of Lactobacillus [41]. In order to combat poor head retention in beers that are soured with Lacto, it has been suggested by German brewing scientist, Burghard Hagen Meyer, to lower the pH of the wort to 4.5-4.8 with food grade lactic acid or phosphoric acid before pitching Lactobacillus [47][48][49]. Although the lowering of the wort's pH inhibits the proteolytic activity of Lacto, it does not stop it completely, so continued exposure to Lactobacillus over time may still degrade the available head formation proteins. Additionally, ingredients that increase head retention such as unmalted chit, malted wheat, and carafoam have been used to help combat poor head retention in beers soured by Lactobacillus [47][50]. Professional brewer Kristen England of Bent Brewstillery tested Hexa Iso Hop Extract by dosing at 4 times the recommended dosage and found that it greatly increased head retention in a Berliner Weisse (3.5% abv, pH 3.1, TA ~1, BU 5), with a minor taste difference. Kristen recommends experimenting with lower dosages to avoid too much flavor impact.

Another method that has been reported to help with head retention when Sour Worting (kettle souring) is to add a pound of DME per 5 gallons of wort during the heat pasteurization process (after the wort has been soured with Lactobacillus). One could also steep specialty grains such as wheat malt, chit malt, carafoam, or carapils, and add the extract into the kettle during the heat pasteurization or boiling process. This will add back head formation proteins that were lost during the Lacto fermentation [51][52].

See also This discussion with Gareth Young on MTF.

Kristen England of Bent Brewstillery's Hexa Iso Hop Extract results (Hop Iso added to the left beer, nothing added to the right)

See Also

Additional Articles on MTF Wiki

External Resources

References

  1. Lactic Acid Bacteria. Todar's Online Texbook of Bacteriology. Kenneth Todar, PhD. Pg 1. Retrieved 08/09/2015.
  2. Lactic Acid Bacteria. Todar's Online Texbook of Bacteriology. Kenneth Todar, PhD. Pg. 4. Retrieved 07/28/2015.
  3. Nutrition and Growth of Bacteria. Todar's Online Texbook of Bacteriology. Kenneth Todar, PhD. Retrieved 07/28/2015.
  4. Lactobacillus. Wikipedia. Retrieved 07/28/2015.
  5. 5.0 5.1 5.2 5.3 5.4 Milk The Funk Wiki. 100% Lactobacillus Fermentation Test by Lance Shaner.
  6. Commercial Brettanomyces, Lactobacillus, and Pediococcus Descriptions. The Mad Fermentationist Blog. Michael Tonsmeire. Retrieved 3/4/2015.
  7. 7.0 7.1 Conversation with Nick Impellitteri from The Yeast Bay on the MTF Facebook Group. 3/4/2015.
  8. Conversation with Michael Soo and Nick Impellitteri on the Milk The Funk Facebook Group. 3/5/2015.
  9. The Yeast Bay website. Retrieved 3/2/2015.
  10. 10.0 10.1 Growth Response of Lactobacillus brevis to Aeration and Organic Catalysts. J. R. Stamer and B. O. Stoyla. Appl Microbiol. Sep 1967; 15(5): 1025–1030.
  11. Conversation with Raymond Wagner of Oso Brewing Co on Milk The Funk. 4/30/2015.
  12. Conversation with Lance Shaner on MTF in regards to IBU tolerance of OYL-605. 6/15/2015.
  13. From Gigayeast, Inc. on Facebook, 12/3/2014: "Appears to be L. delbrueckii."
  14. Personal Communication with Jim Thompson.
  15. GigaYeast Webpage. Retrieved 7/22/2015.
  16. Conversation with Steve Smith of GigaYeast on MTF. 05/08/2015.
  17. From RVA Yeast Lab's Website
  18. Discussion on Milk The Funk Facebook group with Malachy McKenna
  19. Conversation with David Thorton on MTF Facebook Group. 2/27/2015.
  20. MTF thread started by Brad Primozic. 5/29/2015.
  21. Conversation on MTF with Bryan Heit. 5/6/2015.
  22. 22.0 22.1 Evaluate starter media to propagate Lactobacillus sp., Eureka Brewing Blog, by Samuel Aeschlimann.
  23. 23.0 23.1 Conversation with Sam Aeschlimann of Eureka Brewing Blog on MTF. 08/20/2015.
  24. Heit, Bryan. Lacto Starters. Sui Generis Blog. Retrieved 6/15/2015.
  25. Conversation with Nick Impellitteri on Milk The Funk Facebook group. 3/5/2015.
  26. Conversation with Bryan Heit on Milk The Funk. 01/19/2015.
  27. Conversation with Bryan Heit on Milk The Funk. 05/04/2015.
  28. Conversation with Adi Hastings on MTF. 6/20/2015.
  29. 29.0 29.1 29.2 29.3 29.4 29.5 Fermentation: Effects on Food Properties. Bhavbhuti M. Mehta, Afaf Kamal-Eldin, Robert Z. Iwanski. CRC Press, Apr 12, 2012. Pg 76,77.
  30. 30.0 30.1 Todar's Online Texbook of Bacteriology. Kenneth Todar, PhD. Retrieved 05/06/2015.
  31. Lactic Acid Bacteria. Raunak Shrestha. Retrieved 6/7/2015.
  32. Handbook of Dough Fermentations. Karel Kulp, Klaus Lorenz. CRC Press, May 20, 2003. Pg 33.
  33. Lactobacillus plantarum and its biological implications. Microbe Wiki. Retrieved 6/7/2015.
  34. Conversation with Lance Shaner about L. plantarum on MTF. 6/7/2015.
  35. Lactic Acid Bacteria: Microbiological and Functional Aspects, Fourth Edition. Sampo Lahtinen, Arthur C. Ouwehand, Seppo Salminen, Atte von Wright. CRC Press, Dec 13, 2011. Pg 80.
  36. Complete Genome Sequence of the Probiotic Lactic Acid Bacterium Lactobacillus Rhamnosus. Samat Kozhakhmetov, Almagul Kushugulova, Adil Supiyev, Indira Tynybayeva, Ulykbek Kairov, Saule Saduakhasova, Gulnara Shakhabayeva, Kenzhebulat Bapishev, Talgat Nurgozhin, Zhaxybay Zhumadilov. 2013.
  37. Discussion with Lance Shaner on MTF. 6/7/2015.
  38. Humbard, Matt. Physiology of Flavors in Beer – Lactobacillus Species. Retrieved 6/14/2015.
  39. Secondary Metabolite. Wikipedia. Retrieved 6/9/2015.
  40. Texture, proteolysis and viable lactic acid bacteria in commercial Cheddar cheeses treated with high pressure. Cheryl Wick, Uwe Nienaber, Olga Anggraeni, Thomas H Shellhammer and Polly D Courtney. 2002. Retrieved 7/7/2015.
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  52. Conversation with Paul Finney on MTF in regards to head retention of Berliner Weisse. 08/29/2015.