Menu
US
Cell Counting and Image Cytometry

Yeast in Biofuel

Section
Cellometer Applications
Celigo Applications
Cell Counting Method Selection
Cell Counting and Image Cytometry FAQs
Cell-based Assays for Bioprocessing
Cell-based Assays for Gene Therapy Development
Cellometer Applications
Modern Virology Assays
Sub Section
Cell Analysis for Breweries and Biofuels
Automated Analysis of Primary Cells
Brightfield Cell Analysis
Cell Analysis for Breweries and Biofuels
Cell Concentration and Viability for Blood-based Samples
Cell Counting with a Hemocytometer
Cell Viability for Clean and Messy Samples
Fluorescent Assays
Immuno-oncology Research Using Cellometer Instruments
Miscellaneous Cell Types
Topic
Yeast in Biofuel
Advanced Yeast Analysis
Ale and Lager Yeast
Yeast in Biofuel
Yeast in Brewing

Yeast in biofuel overview

In general, yeast used in the biofuel industry are in complex medium such as corn mash, corn stover, or sugar cane, which can serve as nutrients to produce bioethanol. These complex media increase the difficulties for automated counting using brightfield method due to the debris particles in the sample. Using a combination of acridine orange (AO) and propidium iodide (PI) can perform dual fluorescence detection of live and dead cells, respectively, which can specifically stain the live/dead cells to reliably determine the concentration and viability of the complex sample.

Fluorescence based image cytometry method for yeast concentration & viability measurement

pipette

1. Pipette 20 µl of sample mix

insert slide vision

2. Insert slide

Yeast complex - yeast viability results

3. Click count and get results

How does yeast count & viability by dual fluorescence work?

Corn mash sample for yeast viability

A highly viscous corn mash sample is mixed with a dilution buffer and stained with nucleus staining dyes.

Live nucleated yeast dual fluorescence

Live nucleated cells emit green fluorescence when excited by blue light.

Dead yeast cells dual fluorescence

Dead cells emit red light when excited by green light.

Live dead yeast cells distinguishable by color

Live and dead cells are then distinguishable by color and viability is generated as a percentage based on live/total cell count.

Yeasts used in biofuel industry

Yeast concentration & viability measurement

Below shows 3 complex samples of corn mash, corn stover, and sugar cane. The brightfield images contain many debris particles, but in the fluorescent images, only the yeast cells that fluoresce brightly will be automatically counted.

Yeast corn mash debris

Corn mash debris

Yeast corn stover debris

Corn stover debris

Yeast sugar cane debris

Measuring yeast viability using AOPI

Yeast AOPI

Identification of live and dead cells in a complex yeast sample

The images above show a brightfield, green (AO), and red (PI) images. Live cells in the green AO image are shown with a green arrow. Dead red PI positive cells are shown with a red arrow

Yeast AOPI graph

Multiple yeast samples were monitored during the ethanol fermentation process. All of the samples were counted using either the manual hemacytometer method or the automated Cellometer method. Early in fermentation the measured viability was shown to be at ~90 %. By the end of fermentation, at 55 hours, the measured viability was below 30 %. Both manual and automated methods showed great correlation to each other.

For research use only. Not for use in diagnostic procedures.

ON THIS PAGE