This week I take a look at how you can harvest and reuse brewing yeast from one batch to pitch
slurry
When it comes to brewing delicious beer, there are few aspects more important than the yeast. A healthy fermentation allows the malt, hops, and adjuncts to shine. Pitching the right amount of healthy cells helps ensure that the finished beer has the intended alcohol, expected residual sweetness, and appropriate yeast character.
Over the last four years at Sapwood Cellars we've slowly improved our yeast handling. We've noticed improved fermentation consistency, and better tasting beers. Most of our process is excessive for a homebrewer, but it might give you some ideas!
Harvesting Yeast
We harvest yeast from moderate gravity beers when possible as these cells are less stressed and healthier as a result. Our general rhythm is to brew a pale ale with a fresh pitch, and harvest from that tank for an IPA and DIPA the following week. Once the pale ale fermentation is complete (repeated gravity readings, and no diacetyl or acetaldehyde sensory) we can and soft-crash to 56-58F (13-14C). Cold and dissolved CO2 encourage the yeast to settle out. Specific temperature and time are strain and tank dependent, but that works for most of the English-leaning strains we use (Boddington's, Conan, Whitbread, and the Thiolized-variants).
Once the beer has been cold for 24 hours, we attach a 1/2 bbl brink to the bottom of the tank and pasteurize through the line and brink with 180F (82C) water from our on-demand. 25 minutes hot ensures there aren't any stray microbes that will be passed onto the subsequent batches. After pushing out the water with CO2 pressure we spray the brink with cold water then pressurize it and the tank to ~10 PSI.
We then dump about a gallon (4L) from the T until the yeast looks good (creamy, off-white) and then begin collecting into the brink. You don't need to dump a large volume of yeast. By keeping steady pressure on the tank and slowly releasing pressure on the brink through the valve at the top we ensure that the yeast won't come out of the cone too quickly (which could punch through pulling in more beer than yeast) and won't foam up in the brink. It takes 10-15 minutes to fill the brink. Usually we are able to collect 110-130 lbs (50-60 kg) before yeast starts coming out the top of the brink.
We collect yeast before dry hopping to avoid having hops mixed in with the yeast. We also prefer the "less rough" flavor we achieve by dry hopping cold. If you dry hop early-mid fermentation and want to harvest, drop as much of the hops out as you can before crashing and harvesting.
Yeast Storage
Whenever possible we pitch within 72 hours of harvest. Larger yeast cultures generate more heat and thus tend to lose viability more rapidly. Store the yeast as cold as possible, which for us is ~36F (2C) in our walk-in. Ideally that would be closer to 32F (0C) to further slow its metabolism. Shake twice a day to dissipate hot-spots and vent down the pressure to knock-out CO2. If storing the yeast for more than a few days, attach a blow-off line to prevent pressure from building.
There are studies about various additives for maintaining high yeast viability. We've added phosphate buffer to prevent a drastic pH drop. It's difficult to tell from a single data point, but viability dropped from 95% to 89% after a week of storage. We've seen closer to 10% reductions the handful of times we've stored yeast that long previously.
We generally won't harvest and repitch beyond three generations (although recently we went to five). That's because with our limited number of tanks, variety of yeast strains, and canning schedule we'd eventually have to hold onto yeast for a couple of weeks before pitching or harvest from a strong beer.
Determining Cell Count and Viability
There are plenty of successful brewers who pitch a standard weight by barrel/gravity, but knowing how many live cells you actually have is a great way to improve consistency. It's especially valuable if you use a variety of strains or want to bring in a new strain. Our harvests of the same strain can vary by as much as three times in terms of live cells per g of slurry (~.5-1.5 billion cells). The cost of all of the equipment required is ~$500, less than a single commercial 10 bbl yeast pitch from some labs.
Start by shaking the brink to homogenize the culture. Then run a cup of yeast out, dump it (to avoid counting the cells packed around the port) and then pull a sample. The next step is to dilute the culture to a "workable" concentration - 1:100 for us. Too many cells packed together makes for a culture that is impossible/laborious to count, while too few raises the chances luck will throw-off the count. For a long time I diluted by volume, performing two sequential 10X dilutions with a micropipette. This had two drawbacks. First getting an accurate volume of yeast slurry is tricky because it is foamy and has small bits of trub that can plug-up the pipette. Second, we pitch by weight, so there was always some estimation when it came to converting the volume to a weight or the extra step of determining the physical density of the slurry by mixing with water in a graduated cylinder on a scale. What we do now is dilute by weight, which gives us cells per gram rather than cells per milliliter.
Our scale is accurate to .2 g, so weighing 1 g of yeast into 99 g of water has a ~20% margin of error. As a result I do 490 g of water with 5 g of the yeast slurry. This reduces the maximum margin of error to ~4%. After pouring the diluted culture back and forth to mix, I take 9.9 mL of the diluted culture with the micropipette and add .1 mL of a stock dye solution of Erythrosin B and phosphate buffer (1 g in 50mL of buffer). This results in a total dilution of 100X. You could go even further, a 10X dilution by weight (50 g yeast with 450 g of water) followed by a 10X dilution by volume (1 mL of the diluted culture with 8.9 mL water and .1 g of dye). Live cells are able to expel the Erythrosin B so they won't be stained, meaning any red yeast cells are dead. You can use a variety of other stains, but Erythrosin B is a food coloring and much safer to handle than methylene blue or trypan blue. Here's a post from Escarpmant Labs on using it inspired by my Tweet (which was in turn inspired by this).
Luckily the Boddingtons-type strain we use for most of our batches isn't "excessively" flocculent. When we fermented a run with Whitbread we ran into issues with the cells being too clumpy to count. Luckily BrewKaiser has a whole post on additions you can add to help. Phosphoric acid worked OK, but a local brewer suggested disodium EDTA, which I plan to buy before we do another run with a similar strain.
Next, place a couple drops on the diluted culture a hemocytometer, apply the slide cover, and stick it under a microscope (we have an Omax). Count the live and dead cells in five squares (each made up of 25 small squares) - four corners, and center. This provides a large enough sample size to avoid undue randomness. A small tally counter helps keep track. The standard rule is to count cells touching the left and top lines, but not the right or bottom. Count connected cells as two only if the daughter cell is more than half the size of the mother. Then I plug the totals into Inland Island's Yeast Cell Count Calculator. Usually our harvests are 80-90% viable off a fresh pitch, and they tend to go up from there on subsequent generations (90-95%). If your viability isn't great it could either be that the yeast isn't getting enough nutrients/oxygen, your initial pitching rate was too high or low, or that you are waiting too long to harvest.
There are automated solutions for yeast counting, but with some practice the whole processes will take less than 10 minutes.
To pitch, we attach the brink to a T inline during knock-out. With the brink on a scale we use CO2 to slowly push in the desired weight of yeast (calculated based on the cell count, wort gravity, and volume). We pitch during knock-out so the yeast mixes with the aerated wort as it goes into the fermentor. White Labs advocates using a pump to pitch their fresh yeast inline to achieve better mixing with the wort. Best practice is to do another cell count off the tank once knock-out is complete to validate your process (we did it a few times, but now trust our approach).
When we started brewing more double batches to fill our 20 bbl tanks, we were pitching enough cells for 20 bbls along with the first 10 bbls of wort. Our thought process was that the yeast wouldn't do much in the 3-4 hours before the second half of the wort went in. However, we found our fermentations were less reliable, often dragging towards terminal gravity, and the yeast from those batches had much lower viability than expected. Both of these issues improved significantly once we switched to pitching only enough cells for the initial knock-out volume. This allows for more growth and thus a higher proportion of younger yeast cells.
Hopefully this overview of our process is helpful for someone starting a new craft brewery, or looking to take their yeast management to the next level. As with anything in brewing, the more variables you can track and control the more consistency you'll have in your results. Yeast management isn't a "fun" topic, but it is one of the simplest things a brewery can do to increase consistency, improve flavor, and save money!
This week I’m going to cover the two major methods (in two parts) used to create sour beers at a home brew level. While sour beer brewing is considered a more advanced brewing technique, it is possible for even a beginning homebrewer to create great sour beers using these methods. Sour Beer Basics Sour beers […] 
Dr Chris White joins me from White Labs to discuss yeast pitch rates and starters for beer brewing as well as wine, mead and cider. Subscribe on iTunes to Audio version or Video version or Spotify or Google Play Download the MP3 File– Right Click and Save As to download this mp3 file. Your browser […] Chris White joins me this week to discuss how White Labs produces yeast for commercial brewers and home brewing. We discuss everything from his yeast bank to production and packaging. Subscribe on iTunes to Audio version or Video version or on Google Play Download the MP3 File– Right Click and Save As to download this […] I've brewed a surprising number of beers with ingredients grown on our .1 acres of Washington, DC. Including hops, cherries, juniper, ground ivy, mulberries... and recently fermented acorns! Rather than showcase a single ingredient though, I wanted to brew an estate beer with five ingredients grown and harvested on our land!
The extent of the influence of aged hops on sour beer is still a bit underestimated. While the generally stated goal is preventing rapid souring by Lactobacillus in a traditionally fermented lambic, what they add to the flavor and what particular characteristics of the hops best serve this isn't widely studied. There are a few studies that oxidation can boost certain fruity aromatics. Which has lead Scott to threaten to use old hops on the hot-side for a NEIPA... he promised to do a test batch before brewing a 10 bbl batch on the new Sapwood Cellars brewhouse.
I thought it would be fun to brew with aged Cascades from the bines in my backyard, especially because fresh they didn't have a huge aroma. They'd been sitting open in my basement since they were dried a few years before.
I don't have the space or effort to grow or malt grain, so I took the easy way out and brewed with wheat malt extract (a blend of 65% wheat malt 35% barley). I'd had good results from extract lambics previously, but this time in addition to maltodextrin I added wheat flour slurry to the boil. Mixing the flour with cold water prevents it from clumping when it touches the boiling wort. A turbid mash pulls starch from the unmalted wheat into the boil, which eventually feeds the various microbes in the late-stages of fermentation. The microbes must have enjoyed it as the resulting beers are completely clear.
Fruit was provided by our four berry trees/bushes. Sour cherry, blackberry, raspberry, and mulberry. To keep things easy I added roughly equal amount of each (other than the raspberries). I briefly froze most of the fruit, but I added the raspberries a small handful at a time as they ripen slower than the rest. I only had enough of each for one gallon of beer, as most of the rest of the fruit was spoken for. The leftover beer went onto local plums!
Video Review
Backyard Berries
Smell – Cherry and raspberry lead, not surprising as they are more distinct than the blackberry and mulberry. There is an underlining wine-iness that likely comes from the rest of the fruit. The base beer behind the fruit doesn't make itself known other than a subtle maltiness.
Appearance – Clear garnet on the first pour, a little haze when I emptied the bottle into the glass. Alright head retention thanks to the wheat.
Taste – Reminds of the nose with raspberry up front and cherry jam into the finish. Not as bright and fresh as it once was, but still reasonably fresh. The malt and hops don’t add a huge amount of character, but they support the fruit. The Wyeast lambic blend similarly stays mostly out of the way, adding edge complexity without trying to fight through the fruit.
Mouthfeel – Not a thick beer given the relatively low OG, and all of the simple sugars from the fruit. Solid carbonation, CBC-1 did a good job despite the acidity.
Drinkability & Notes – The combination of four berries works surprisingly well to my palate. They play together without becoming generic fruitiness. The base beer is unremarkable, but that’s fine in a beer where the fruit is the star.
Changes for Next Time – Would be nice to brew more than a gallon, but otherwise my only real changes would be to go all-grain.
Plum-Bus
The rest of the batch went onto a two varieties of local plums. I've brewed with plums before in a dubbel. I wasn't sure about plums in a pale beer, but after trying spectacular examples from Tilquin and Casey I was convinced!
Smell – Clear it isn’t a kettle-soured fruit-bomb, lots of lemon pith and mineral along with the moderate fruit contribution. Plums aren’t nearly as aromatic as the more common sour beer fruits, but they add a depth without covering up the base beer.
Appearance – Beer is more rusty-gold than purple. Clear despite the flour. Thin white head, but this bottle appears less carbonated than the last few I’ve opened.
Taste – Tangy plum skin, apricot, and lemon. Beautiful blend of fruit and beer. Wyeast Lambic Blend with dreg-augmentation again does a really nice job. Strong lactic acid without any vinegar or nail polish. Finish is moderate funk, hay, and overripe stone fruit.
Mouthfeel – Light, but not thin. Carbonation is too low, maybe the cap-job on this one wasn’t perfect.
Drinkability & Notes – Delicious. The plum could be a little juicier and fresher, but it works well. Sad I didn’t leave any of this half unfruited for comparison.
Changes for Next Time – I’d like to keep experimenting with other plum varieties in beer. Glad the pale base worked out well. Despite “plum” being a common descriptor for darker Belgians, actual plums don’t shine with all of that malt.
Recipe
Batch Size: 10.00 gal
SRM: 5.5
IBU: 5.3
OG: 1.046
FG: 1.006/1.006
ABV: 5.25%
Final pH: 3.45/3.45
Boil Time: 90 mins
Fermentables
----------------
92.3% - 9 lbs Breiss Bavarian Wheat DME
5.1% - .5 lbs Maltodextrin Powder
2.6% - .25 lbs King Arthur All Purpose Flour
Hops
-------
2.50 oz - Homegrown Cascade: Aged 3-4 Years (Whole, ~1.00% AA) @ 90 min
Yeast
-------
Wyeast Belgian Lambic Blend
or
Omega OYL-218 - All The Bretts
Omega OYL-057 - HotHead Ale
Notes
-------
Brewed 1/15/17
Hops were homegrown and aged open over several years.
Fermented and aged in 6 gallon BetterBottle without transfering. Added some various dregs over the course of fermentation.
7/21/17 Filled a 1 gallon jug with the Wyeast half onto 6 oz each homegrown sour cherries, blackberries, and mulberries (plus maybe an ounce of raspberries - maybe 4 oz total over a couple months). The remainder went onto 3 lbs of methly plums.
8/24/17 Added an additional 1.75 lbs of Castleton plums to the plum portion
12/14/17 Bottled the 2.75 gallons of the plum with 61 g of table sugar and rehydrated CBC-1. Bottled the .8 gallons of backyard fruit with 21 g of table sugar and CBC-1.
The extent of the influence of aged hops on sour beer is still a bit underestimated. While the generally stated goal is preventing rapid souring by Lactobacillus in a traditionally fermented lambic, what they add to the flavor and what particular characteristics of the hops best serve this isn't widely studied. There are a few studies that oxidation can boost certain fruity aromatics. Which has lead Scott to threaten to use old hops on the hot-side for a NEIPA... he promised to do a test batch before brewing a 10 bbl batch on the new Sapwood Cellars brewhouse.
I thought it would be fun to brew with aged Cascades from the bines in my backyard, especially because fresh they didn't have a huge aroma. They'd been sitting open in my basement since they were dried a few years before.
I don't have the space or effort to grow or malt grain, so I took the easy way out and brewed with wheat malt extract (a blend of 65% wheat malt 35% barley). I'd had good results from extract lambics previously, but this time in addition to maltodextrin I added wheat flour slurry to the boil. Mixing the flour with cold water prevents it from clumping when it touches the boiling wort. A turbid mash pulls starch from the unmalted wheat into the boil, which eventually feeds the various microbes in the late-stages of fermentation. The microbes must have enjoyed it as the resulting beers are completely clear.
Fruit was provided by our four berry trees/bushes. Sour cherry, blackberry, raspberry, and mulberry. To keep things easy I added roughly equal amount of each (other than the raspberries). I briefly froze most of the fruit, but I added the raspberries a small handful at a time as they ripen slower than the rest. I only had enough of each for one gallon of beer, as most of the rest of the fruit was spoken for. The leftover beer went onto local plums!
Video Review
Backyard Berries
Smell – Cherry and raspberry lead, not surprising as they are more distinct than the blackberry and mulberry. There is an underlining wine-iness that likely comes from the rest of the fruit. The base beer behind the fruit doesn't make itself known other than a subtle maltiness.
Appearance – Clear garnet on the first pour, a little haze when I emptied the bottle into the glass. Alright head retention thanks to the wheat.
Taste – Reminds of the nose with raspberry up front and cherry jam into the finish. Not as bright and fresh as it once was, but still reasonably fresh. The malt and hops don’t add a huge amount of character, but they support the fruit. The Wyeast lambic blend similarly stays mostly out of the way, adding edge complexity without trying to fight through the fruit.
Mouthfeel – Not a thick beer given the relatively low OG, and all of the simple sugars from the fruit. Solid carbonation, CBC-1 did a good job despite the acidity.
Drinkability & Notes – The combination of four berries works surprisingly well to my palate. They play together without becoming generic fruitiness. The base beer is unremarkable, but that’s fine in a beer where the fruit is the star.
Changes for Next Time – Would be nice to brew more than a gallon, but otherwise my only real changes would be to go all-grain.
Plum-Bus
The rest of the batch went onto a two varieties of local plums. I've brewed with plums before in a dubbel. I wasn't sure about plums in a pale beer, but after trying spectacular examples from Tilquin and Casey I was convinced!
Smell – Clear it isn’t a kettle-soured fruit-bomb, lots of lemon pith and mineral along with the moderate fruit contribution. Plums aren’t nearly as aromatic as the more common sour beer fruits, but they add a depth without covering up the base beer.
Appearance – Beer is more rusty-gold than purple. Clear despite the flour. Thin white head, but this bottle appears less carbonated than the last few I’ve opened.
Taste – Tangy plum skin, apricot, and lemon. Beautiful blend of fruit and beer. Wyeast Lambic Blend with dreg-augmentation again does a really nice job. Strong lactic acid without any vinegar or nail polish. Finish is moderate funk, hay, and overripe stone fruit.
Mouthfeel – Light, but not thin. Carbonation is too low, maybe the cap-job on this one wasn’t perfect.
Drinkability & Notes – Delicious. The plum could be a little juicier and fresher, but it works well. Sad I didn’t leave any of this half unfruited for comparison.
Changes for Next Time – I’d like to keep experimenting with other plum varieties in beer. Glad the pale base worked out well. Despite “plum” being a common descriptor for darker Belgians, actual plums don’t shine with all of that malt.
Recipe
Batch Size: 10.00 gal
SRM: 5.5
IBU: 5.3
OG: 1.046
FG: 1.006/1.006
ABV: 5.25%
Final pH: 3.45/3.45
Boil Time: 90 mins
Fermentables
----------------
92.3% - 9 lbs Breiss Bavarian Wheat DME
5.1% - .5 lbs Maltodextrin Powder
2.6% - .25 lbs King Arthur All Purpose Flour
Hops
-------
2.50 oz - Homegrown Cascade: Aged 3-4 Years (Whole, ~1.00% AA) @ 90 min
Yeast
-------
Wyeast Belgian Lambic Blend
or
Omega OYL-218 - All The Bretts
Omega OYL-057 - HotHead Ale
Notes
-------
Brewed 1/15/17
Hops were homegrown and aged open over several years.
Fermented and aged in 6 gallon BetterBottle without transfering. Added some various dregs over the course of fermentation.
7/21/17 Filled a 1 gallon jug with the Wyeast half onto 6 oz each homegrown sour cherries, blackberries, and mulberries (plus maybe an ounce of raspberries - maybe 4 oz total over a couple months). The remainder went onto 3 lbs of methly plums.
8/24/17 Added an additional 1.75 lbs of Castleton plums to the plum portion
12/14/17 Bottled the 2.75 gallons of the plum with 61 g of table sugar and rehydrated CBC-1. Bottled the .8 gallons of backyard fruit with 21 g of table sugar and CBC-1.
