@article{anderson_havenstein_jenkins_osborne_2013, title={Changes in commercial laying stock performance, 1958–2011: thirty-seven flocks of the North Carolina random sample and subsequent layer performance and management tests}, volume={69}, ISSN={0043-9339 1743-4777}, url={http://dx.doi.org/10.1017/S0043933913000536}, DOI={10.1017/s0043933913000536}, abstractNote={Thirty-seven layer performance tests have been conducted at North Carolina State University during the past 53 years. Originally established as the North Carolina Random Sample Layer Test (NCRSLT), all of the test flocks have been hatched and housed at the Poultry Unit of the North Carolina Department of Agriculture and Consumer Service's Piedmont Research Station at Salisbury, North Carolina. In 1988, the NCRSLT name was changed to the North Carolina Layer Performance and Management Test (NCLP&MT) reflecting changes in the testing procedures to include the evaluation of management practices used by commercial egg producers. Strain testing and evaluating the relative egg production of commercially available egg production stocks began in 1911, and the number of such Random Sample Tests in North America peaked at 23 in approximately 1968. The mission for the NCRSLT to provide an unbiased evaluation of the overall performance of strains, evolved to include the effects of various housing and husbandry practices on the performance of the genetic stocks entered into the test. Test results have been distributed to the industry throughout the USA as well as to producers in 22 other countries throughout the world. In addition, the internet site for the NCLP&MT http://poultry.ces.ncsu.edu/layer-performance/ allows the distribution of the results to many other interested university and government officials. This review of the first 37 North Carolina layer tests shows continuing improvements in egg production, reduction in body weight and feed consumption, increases in egg weight and feed conversion, improvements in liveability, and an improvement in egg quality from the commercially available white and brown egg strains. These changes have continued throughout the 50+ year history of the tests, and the changes observed have been brought about primarily by poultry breeding companies applying quantitative genetics for the improvement of the layer stocks used worldwide.}, number={3}, journal={World's Poultry Science Journal}, publisher={Informa UK Limited}, author={Anderson, K.E. and Havenstein, G.B. and Jenkins, P.K. and Osborne, J.}, year={2013}, month={Sep}, pages={489–514} }
 @article{anderson_jones_davis_jenkins_2007, title={Effects of genetic selection on behavioral profiles of single comb white Leghorn hens through two production cycles}, volume={86}, ISSN={["1525-3171"]}, DOI={10.1093/ps/86.9.1814}, abstractNote={Four layer genetic stocks consisting of 3 Ottawa control strains (5, 7, and 10) and a commercial laying stock (CCS) were utilized to evaluate potential changes in behavioral profiles due to the effects of genetic selection through 2 production cycles. The Ottawa strains were started as random bred strains from the crosses of several popular commercial layers in 1950, 1959, and 1972, and the commercial strain used herein was from calendar year 1993, and its ancestors were involved in the formation of all of the random bred strains. The behavior study utilized 2 replicates from each strain that contained 4 cages, 6 hens/cage, for a total of 192 hens. Behavioral observations were recorded on 2 consecutive days beginning at 22 wk of age and every 28 d thereafter during the first production cycle, the molt period, and the second production cycle through 90 wk of age and periodic feather and Hansen's test scores recorded. Behavior profiles were similar between the control strains and the CCS, indicating that long-term genetic selection by commercial egg-type breeding firms to enhance production parameters has had no impact on laying strain behavior patterns. Appetitive behaviors were not affected by strain. During the molt, hens had reduced (P < 0.05) feeding and drinking frequencies in comparison with those observed during the first and second cycles. The data indicated that hens pecked inedible objects at a greater (P < 0.0001) frequency during the first cycle and molt than during the second cycle. Fearfulness scores were only influenced by production phase with the molt having the highest (P < 0.01) score of 3.46. Strain or production phase did not influence the frequency of aggressive and submissive acts.}, number={9}, journal={POULTRY SCIENCE}, author={Anderson, K. E. and Jones, D. R. and Davis, G. S. and Jenkins, P. K.}, year={2007}, month={Sep}, pages={1814–1820} }
 @article{payne_osborne_jenkins_sheldon_2007, title={Modeling the growth and death kinetics of Salmonella in poultry litter as a function of pH and water activity}, volume={86}, ISSN={["1525-3171"]}, DOI={10.1093/ps/86.1.191}, abstractNote={Contaminated poultry litter, serving as a reservoir for Salmonella, can be linked to both food safety concerns when contaminated birds enter processing plants and environmental concerns when used as a fertilizer. Predictive modeling allows for the estimation of microbial growth or inactivation as a function of controlling environmental growth factors. A study was conducted to observe the combined effects of pH and water activity (A(w)) at a constant temperature on Salmonella populations in used turkey litter to predict microbial response over time. Litter, first pH-adjusted and then inoculated with a 3-strain Salmonella serovar cocktail to an initial concentration of approximately 10(7) cfu/g, was placed into individual sealed plastic containers with saturated salt solutions for controlling A(w). A balanced design including 3 A(w) values (0.84, 0.91, 0.96), 3 pH values (4, 7, 9), and a constant temperature of 30 degrees C was used, with litter samples periodically removed and analyzed for Salmonella populations, pH, and A(w). At each combination of environmental factors, the Churchill or exponential inactivation mathematical models were used to describe the growth and death of Salmonella over time. Salmonella populations exhibited growth (approximately 2 log) with little decline up to 42 d in litter environments of pH 7 and 9 and a A(w) of 0.96. As litter A(w) and pH levels were reduced, populations declined, with the most drastic reductions (approximately 5 log in 9 h) occurring in low-pH (4) and low-A(w) (0.84) environments. Generalized models for bacterial growth and death under grouped pH environments were successfully developed to predict Salmonella behavior in litter over time. These findings suggest that the best management practices and litter treatments that lower litter A(w) to < or =0.84 and pH to < or =4 are effective in reducing Salmonella populations. The use of a single equation to predict the growth and decline of Salmonella populations as a function of pH and A(w) has potential application for use in the development of effective pathogen control strategies at the farm level.}, number={1}, journal={POULTRY SCIENCE}, author={Payne, J. B. and Osborne, J. A. and Jenkins, P. K. and Sheldon, B. W.}, year={2007}, month={Jan}, pages={191–201} }
 @article{anderson_davis_jenkins_carroll_2004, title={Effects of bird age, density, and molt on behavioral profiles of two commercial layer strains in cages}, volume={83}, ISSN={["0032-5791"]}, DOI={10.1093/ps/83.1.15}, abstractNote={Two commercial strains, Hy-Line W-36 and DeKalb XL, were moved to a laying house at 18 wk of age. They were housed 6 hens/layer cage at 2 densities (361 and 482 cm2/bird) with 2 replications each per strain/density combination. The high-density treatment contained 24 hens/replication and the low-density treatment contained 18 hens/replication for a total of 168 hens. Production parameters were measured during the first egg production cycle, the molt period, and the first 4 wk of the second lay cycle (20 to 68 wk of age). Behavioral observations were taken during 2 consecutive d at 26, 34, 43, 51, 62, 64, and 68 wk of age to examine behavioral patterns. Modified Hansen's tests were conducted concurrently to provide indication of the fearfulness levels of hens at the various stages of production. The production characteristics were similar for both strains. The hens kept at the higher density had lower (P < 0.01) hen-day production and (P < 0.05) daily egg mass. Appetitive behaviors were not affected by strain or density but were affected by the age of the hen and by molting. During the molt, feeding and drinking behavioral acts were fewer (P < 0.05) at 0.018 and 0.013 acts per bird/min, respectively, and standing behavior was highest. The results indicated that the frequencies of pecking inedible objects during the molt period were similar to the frequencies at 26 and 34 wk. Hens performed more acts of standing, and crouching and had lower frequency of movement during the molt. Those kept at a low density performed more movement acts. Feather pecking decreased as hens aged and increased when they molted but was not affected by strain or density. The frequency of aggression and submissive acts was significantly lower during the molt period. Behaviors were affected by strain, density, bird age, and molting; however, the patterns and number of aggressive acts did not increase to compromise the welfare status of the hens. Behaviors during the molt appeared consistent with mechanisms for conservation of body reserves.}, number={1}, journal={POULTRY SCIENCE}, author={Anderson, KE and Davis, GS and Jenkins, PK and Carroll, AS}, year={2004}, month={Jan}, pages={15–23} }