Using Doppler Ultrasound
To Understand Fescue Toxicosis
Tall fescue is the predominant grass used for grazing in the U.S. “Fescue Belt,” the transition zone between the temperate north and the subtropical south. Direct farm receipts for animals produced annually in the region are about $3.7 billion for cattle and calves, $620 million for horses and ponies, and $38 million for sheep and goat products.
Despite these impressive economic numbers attributed, at least in part, to this high-yielding grass, producers must be concerned for the safety of their animals when they consume it. That’s because more than 80 percent of the tall fescue in the transition zone is infected with an endophytic fungus—one that grows inside the plant, between the cells. This fungus imparts hardiness to the plant, but it also produces ergot alkaloid toxins that cause fescue toxicosis in grazing animals. Fescue toxicosis costs the livestock industry nearly $1 billion annually in lost production.
Though some partial solutions exist, few tools have been available for the real-time research needed to develop a complete solution to the fescue toxicosis problem. Now, Doppler ultrasound technology is being used by researchers at the ARS Forage Animal Production Research Unit—led by animal scientist Glen Aiken—to help better understand the causes of fescue toxicosis and to expedite development of management approaches to alleviate it.
Doppler technology is perhaps best known for its use by meteorologists to track thunderstorms. The “Doppler effect” is the change in the frequency of sound waves reflected by a moving object, and it can be used to estimate distance and speed. In this way, Doppler ultrasonography can estimate how fast blood flows in animals.
The ergot alkaloids in tall fescue constrict blood flow. Using Doppler technology, the ARS scientists found that blood flow decreases within 24 hours of feeding cattle ergot alkaloids. Results show that in cattle consuming diets containing ergot alkaloids, blood flow through the caudal artery, which supplies blood to the tail, can be reduced by as much as 50 percent relative to cattle on alkaloid-free diets. Constricted blood flow to peripheral tissues, such as the tail, reduces the animal’s ability to dissipate body heat, making it vulnerable to heat stress.
“This research has helped us better understand ergot alkaloids and the mechanisms by which they cause toxicosis,” says Aiken, who was assisted by research leader Jim Strickland during the project. “This knowledge will lead to improved forage and animal-management protocols that decrease exposure or enhance tolerance to the alkaloids of endophyte-infected tall fescue.”—By Alfredo Flores, Agricultural Research Service Information Staff.
Glen Aiken is in the USDA-ARS Forage Animal Production Research Unit, Agricultural Science Building North, Room N-220-F, University of Kentucky, Lexington, KY 40546; phone (859) 257-1647, fax (859) 257-3334.
"Using Doppler Ultrasound To Understand Fescue Toxicosis" was published in the October 2009 issue of Agricultural Research magazine.