Page 1 Page 2 Page 3 Page 4 Page 5 Page 6 Page 7 Page 8 Page 9 Page 10 Page 11 Page 12 Page 13 Page 14 Page 15 Page 16 Page 17 Page 18 Page 19 Page 20 Page 21 Page 22 Page 23 Page 24 Page 25 Page 26 Page 27 Page 28 Page 29 Page 30 Page 31 Page 32 Page 33 Page 34 Page 35 Page 36 Page 37 Page 38 Page 39 Page 40 Page 41 Page 42 Page 43 Page 44 Page 45 Page 46 Page 47 Page 48 Page 49 Page 50 Page 51 Page 5236 ELECTRICAL CONDUCTIVITY TEST HELPS DETERMINE VIGOUR CSAAC THE 68TH UNITED NATIONS General Assembly declared 2016 the International Year of Pulses. The idea of using pulses to increase food security, as well as improve crop rotations and soil fertility is not lost on the Canadian seed industry. Pulses are an important crop to Canadian farmers. Researchers have made important advances in breeding for characteristics such as reduced pod shattering, seed size, thinner seed coats and reduced dormancy. However, sometimes these same characteristics can create chal- lenges when it comes to seed vigour. These challenges may include: decreased shelf life, mechanical damage during handling, and increased damage from rain and frost prior to harvest. A great way to determine if a seed lot has suffered vigour loss is the electrical conductivity (EC) test. According to the Association of Official Seed Analysts (AOSA) Vigour Handbook 2009: “The test measures the leakage of solutes such as amino acids and inorganic ions from cell mem- branes. Low quality seeds have poor membrane structure that allows the outward diffusion of ions during imbibi- tion that can be detected by monitoring the electrolytes present in the steep water (Simon and Mills, 1983). As a result, high levels of leakage are characteristic of low vigour seed lots, even those with acceptable laboratory germination levels. Low or poor field emergences expected from these lots, particularly after exposure to less favour- able or stressful conditions. Seed lots with low electrolyte leakage during imbibition are considered of high vigour.” The test was used in seed testing as early as 1925. Extensive studies have been done on the test including research by Stan Matthews and Allison Powell, who chairs the International Seed Testing Association Vigour Committee. They related the test significantly to field emergence. The test has proven its ability to predict when seed lots with germinations over 80 per cent will have poor field performance in cold wet soils. Within the seed testing sector of the industry, this test has proven to be repeatable amongst laboratories all over the world. The test is published in the ISTA rules for use in some of the following crop kinds: Cicer arietinum (chickpea), Phaseolus vulgaris (field bean), Glycine max (soybean), and Pisum sativum (garden pea). The test is used unofficially in many other crop kinds. Put simply; four replicates of 50 seeds are weighed and then placed in a measured amount of deionized water. The seeds are soaked for 24 hours at 20 degrees Celsius. The leachate of the water is measured by an electrical conductivity meter. As with all vigour tests, great care must be taken to measure the precision of all steps and supplies in the laboratory. The result is given a measurement in uScm-1g-1, then a rating is applied. The lower the EC number, the better. It signifies less leaching of solutes and a higher vigour. If you are concerned about the vigour of your pulse seed, contact a CSAAC member for advice. For contact infor- mation, visit www.seedanalysts.ca. Morgan Webb, CSAAC Vigour Committee Chair. Elyse Ellis of Seed Check Technologies performs an electrical conductivity test to determine the vigour of a seed lot.  Photo: Morgan Webb.