Whole-genome sequencing is a common tool for outbreak detection and investigation.

No trend has been reported as being more impactful than the increase in the amount of analytical testing being conducted—especially the increase in testing for microorganisms.

A new approach for significantly improving detection probabilities and reducing the need for manual verification of foreign material contamination of food products is described.

Shiga toxin-producing Escherichia coli strains can cause foodborne illness, necessitating the expansion of testing for these organisms.

The ability to rapidly detect the presence of viable pathogens along the production chain is essential for determining intervention and control strategies.

Transgenic methods have been used for over 25 years to incorporate well-characterized genes from a foreign (different plant or nonplant species) donor into a plant host that endows it with some desirable trait.

As a result of the changing regulatory landscape, there is need for more accurate identification and quantification of contaminants in environmental and food-related samples.

Most physical contaminants of foods, such as pieces of hard plastic or wood, can cause consumers immediate injury; this includes all types of foods, including beverages, bottled water, and nutritional and functional products.

This new sensing mechanism can detect very faint traces of foodborne viruses that can help prevent epidemics and further transmission.

The way processors view their responsibilities regarding microbiological testing is changing. Regulatory pressure and a focus on food safety are causing changes in where processors do their testing.