Taking (some) guesswork out of brewing beer

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Alshain - Brewing beer with Pica Photometry System

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Brewing beer with Pica Photometry System

Using Pica to monitor fermentation<br>Alshain Pica is an easy yet powerful tool for using optical backscattering in monitoring bioprocesses such as yeast-based fermentations.<br>Backscattering measurements are non-invasive (essentially contamination risk free) because they are done through side of a transparent<br>vessel or through a window in a tank.<br>Pica sensors are designed to be mounted on exisiting flasks and tanks to make the system more cost-efficient.

Benefits:

Detect immediately if yeast stops to grow or behaves unexpectedly

No unnecessary delays due to manual sampling

Comparing batches to ensure repeatability

Estimate total carbohydrates (sugars etc.) in liquid

Easy to use, from box to measurements in less than 5 minutes

For more information about Pica Photometry System, see:

Pica product page

Pica Brewer's Kit and Pica Brewer's Kit plus (for measuring carbohydrates)

Brief introduction to backscattering measurements

Tutorial: Simple batch fermentation

Alshain Pica oluen valmistamisen apuna (same article in Finnish)

Example setup

All measurements in this article have been done using an Erlenmeyer flask with a magnetic stirrer.

These measurements can also be done using other glassware or setups such as a transparent containers or tanks/reactors with a window.

Main requirement is that backscattering measurements need an unobstructed view of the liquid.

Yeast growth curves

Comparison of two yeast cultivations using same recipe (amount of nutrients, temperatures, initial yeast amount etc.), one successful and one with bad yeast cell viability (figure above).

Monitoring yeast growth in real time gives ability to quickly detect changes in the process (and acting on them),<br>to have a broader understanding of growth dynamics and having tools to aid in product development.

Examples:

Continuous growth rate and cell density monitoring (is cell density suitable for pitching etc.)

Detecting when growth stops or if it stalls at some point

Comparing curves between batches

Process optimisation

Quality assurance

Calibrating growth curves

Backscattering signal is linearily related to density of scatteres such as cells meaning that relative changes in signal corresponds to similar changes in density of cells in the liquid.<br>This makes calibration simple as it can be done without any extra equipment.

Steps:

Start measuring before adding the yeast to determine the background signal

Add a know amount of yeast (note: sensor measures cell density, not absolute amount)

Take note how much signal increases from the yeast

Converting signal into yeast concentration: C(t) = (Signal - Y0)/(Y1 - Y0) * C0, where:

C(t) = yeast concentration

Signal = measured value from Pica photometer

Y0 = background signal value before yeast

Y1 = signal just after adding the yeast

C0 = how much yeast was added (amount of yeast per volume)

Similar method can be used with an optical density (OD600) meter and manual sampling.

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Measuring carbohydrates

Standard Pica sensor head uses near-infrared light to detect cells and is unaffected by the colour of the liquid or presense of most of biochemical compounds such as sugars.<br>Adding a second sensor head (with 460nm wavelength i.e. blue) opens up possibility to estimate the amount of carbohydrates in the liquid as many organic compounds have parts of their spectral absorption lines in 430nm - 490nm range. These are for example:

Starches, dextrins

Sugars (fermentable and non-fermentable)

Some simple sugars have their absorption lines deep in the ultraviolet and are not detected

Other compounds like carotenoids and chlorophyll

Measurements are done by measuring backscattering at both wavelengths (near-infrared and blue) and comparing results as yeast cells reflect both but the blue light is attenuated by the carbohydrates (and other similar compounds).<br>Comparing signals to each other gives an estimate on how much blue light is absorbed by the liquid and therefore the amount of carbohydrates present.

Interfacing two sensor heads with one Pica Readout requires a signal multiplexer, available at Alshain Store .

Carbohydrate curves can be used also without calibration to determine when yeast stops consuming sugars etc.

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Calibrating carbohydrate curves

Carbohydrate concentration estimates can be calibrated similarly to the yeast growth curves with some caveats. Unlike the growth curves, carbohydrate estimates require that the liquid already has scatteres (i.e. yeast cells) in it so that a proper signal can be acquired from both sensors.

Steps:

Prepare a solution (this can contain most of the malt extract and sugars needed)

Measure the background signal from sensors

Using the yeast, do the growth curve calibration for both...

yeast pica signal growth curves carbohydrates

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