Agriculture Reference
In-Depth Information
Cromwell, G.L., Stahly, T.S., Edgerton, L.A., Monegue, H.J., Burnell, T.W., Schenck, B.C. and
Schricker, B.R., 1992. Recombinant porcine somatoptropin for sows during late gestation and
throughout lactation. Journal of Animal Science 70: 1404-1416.
Cross, B.A., Goodwin, R.F.W. and Silver, I.A., 1958. A histological and functional study of the
mammary gland in normal and agalactic sows. Journal of Endocrinology 17: 63-74.
DeHoff, M.H., Stoner, C.S., Bazer, F.W., Collier, R.J., Kraeling, R.R. and Buonomo, F.C., 1986.
Temporal changes in steriods, prolactin and growth hormone in pregnant and pseudopregnant
gilts during mammogenesis and lactogenesis. Domestic Animal Endocrinology 3: 95-105.
Di Pierro, F., Callegari, A., Carotenuto, D. and Tapia, M.M., 2008. Clinical efficacy, safety and
tolerability of BIO-C® (micronized Silymarin) as a galactagogue. Acta Biomedica 79: 205-210.
Dusza, L. and Krzymowska, H., 1981. Plasma prolactin levels in sows during pregnancy, parturition
and early lactation. Journal of Reproduction and Fertility 61: 131-134.
Farmer, C., Knight, C. and Flint, D., 2007a. Mammary gland involution and endocrine status in
sows: effects of weaning age and lactation heat stress. Canadian Journal of Animal Science
87: 35-43.
Farmer, C., Lapointe, J. and Palin, M.F. , 2014a. Effects of the plant extract silymarin on prolactin
concentrations, mammary gland development, and oxidative stress in gestating gilts. Journal
of Animal Science 92: 2922-2930.
Farmer, C. and Palin, M.F., 2005. Exogenous prolactin stimulates mammary development and
alters expression of prolactin-related genes in prepubertal gilts. Journal of Animal Science
83: 825-832.
Farmer, C. and Palin, M.F., 2008. Feeding flaxseed to sows during late-gestation affects mammary
development but not mammary expression of selected genes in their offspring. Canadian
Journal of Animal Science 88: 585-590.
Farmer, C., Palin, M.F., Gilani, G.S., Weiler, H., Vignola, M., Choudhary, R.K. and Capuco, A.V.,
2010a. Dietary genistein stimulates mammary hyperplasia in gilts. Animal 4: 454-465.
Farmer, C., Palin, M.F. and Hovey, R., 2010b. Greater milk yield is related to increased DNA and
RNA content but not to mRNA abundance of select genes in sow mammary tissue. Canadian
Journal of Animal Science 90: 379-388.
Farmer, C., Palin, M.F. and Martel-Kennes, Y., 2012a. Impact of diet deprivation and subsequent
over-allowance during prepuberty. Part 1. Effects on growth performance, metabolite status,
and mammary gland development in gilts. Journal of Animal Science 90: 863-871.
Farmer, C., Palin, M.F. and Martel-Kennes, Y., 2012b. Impact of diet deprivation and subsequent
over-allowance during prepuberty. Part 2. Effects on mammary gland development and
lactation performance of sows. Journal of Animal Science 90: 872-880.
Farmer, C., Palin, M.F. and Martel-Kennes, Y., 2014b. Impact of diet deprivation and subsequent
over-allowance during gestation on mammary gland development and lactation performance.
Journal of Animal Science 92: 141-151.
Farmer, C., Palin, M.F., Theil, P.K., Sorensen, M.T. and Devillers, N., 2012c. Milk production in
sows from a teat in second parity is influenced by whether it was suckled in first parity. Journal
of Animal Science 90: 3743-3751.
Farmer, C., Pelletier, G., Brazeau, P. and Petitclerc, D., 1997. Mammary gland development of sows
injected with growth hormone-releasing factor during gestation and(or) lactation. Canadian
Journal of Animal Science 77: 335-338.
