Introduction Baby pig anemia has be

Introduction

Baby pig anemia has been a potential problem since swine producers first farrowed litters in confinement, denying the nursing pig access to iron in the soil. Iron is a vital component in forming hemoglobin, a protein comprising about one-third the weight of the red blood cell. Hemoglobin within the red blood cell has the unique function of carrying oxygen from the lungs to the tissues of the body in support of cellular metabolism and transporting carbon dioxide resulting from cellular metabolism back to the lungs.

Table 1. The typical blood picture of normal and anemic baby pigs
Measure Normal Anemic
Hemoglobin, grams/100 milliliters 12 5
cell in blood 35 17
RBC count, millions/cubic millimeter 53
RBC size, cubic microns 70 55
RBC hemoglobin concentration, % 35 30

Table 2. Body tissue iron of different species.
PPM of Iron in fat-free body tissue
Species Newborn Adult
Pig 29 90
Cat 55 60
Rabbit 135 60
Human 94 74

When there is a deficiency of iron, the baby pig cannot synthesize an adequate amount of hemoglobin. A blood sample taken from the iron-deficient, anemic pig will have fewer red blood cells than normal, and these red blood cells will be smaller and lighter in color than normal because of low hemoglobin content (Table 1). Thus, baby pig anemia is a condition of the blood in which the oxygen-carrying capacity is greatly reduced, and this condition is generally due to iron deficiency.

Causes of Iron Deficiency Anemia

Iron deficiency develops rapidly in nursing pigs reared in confinement because of (1) low body storage of iron in the newborn pig, (2) low iron content of sow’s colostrum and milk, (3) elimination of contact with iron from soil, and (4) the rapid growth rate of the nursing pig. Let’s consider the impact of each of these causes of iron deficiency. Low body storage of iron in the newborn pig. The baby pig is born with a total of about 40mg of iron in his body, most of which is present in the form of hemoglobin in blood and storage forms in the liver. With an iron requirement of about 7mg daily to maintain blood hemoglobin level in the normally growing baby pig, it is apparent that without supplemental iron, body stores will not last very long. Attempts to increase body iron stores in the fetal pig by administering large amounts of iron to the sow in late gestation, either in her feed or by injection, have not been successful. The data in Table 2 demonstrate the low initial body iron storage and high iron requirement of the pig compared to other domestic animals and man.

Figure 1. Relative preweaning growth rate of pig, lamb, calf, colt and child.
Figure 1. Relative preweaning growth rate of pig, lamb, calf, colt and child.

Figure 2. Utilization of oral and injected iron.
Figure 2. Utilization of oral and injected iron.

Table 3. Hemoglobin values at 3 weeks of age of nursing pigs, lambs and calves that received either no supplemental iron or an injection of iron-dextran early in life.
Species Untreated Iron Injected*
Pig 4.0 10.7
Lamb 6.2 10.8
Calf 9.0 9.8
*Intramuscular iron-dextran injection supplied the following milligrams of iron: pig, 100; lamb, 375; calf, 500.

Low iron content of sow’s colostrum and milk. Sow’s colostrum and milk is a good source of all nutrients the baby pig is known to require, with the exception of iron. The concentration of iron in colostrum is seldom greater than 2ppm, and in milk is lower, averaging about 1ppm. Because of the low concentration of iron in sow’s milk, the baby pig cannot obtain more than about 1mg of iron daily from this source. This falls far short of his requirement for 7mg daily. Attempts to increase significantly the iron concentration in sow’s milk by feeding high levels of various forms of iron in the sow’s late gestation and lactation diet or by injecting the sow with a large amount of iron-dextran late in gestation or during lactation have not been successful.

Elimination of contact with iron from soil. The baby pig is equipped with a snout with which he is able to root almost as soon as he is born. Thus, under natural conditions he could obtain his iron from the soil. When the pig is placed on concrete or reared in confinement in a central farrowing facility, he is denied this opportunity.

Rapid growth rate of the nursing pig. Compared to other domestic mammals, the baby pig has a tremendous ability to grow. This is demonstrated in Figure 1, in which the capabilities of the pig, lamb, calf, colt and child to increase their birth weight during the first 6 weeks of life are compared. This rapid growth of the nursing pig with the resulting increase in plasma volume demands a high intake of iron to maintain adequate hemoglobin. The data in Table 3 demonstrate the greater susceptibility of the baby pig to anemia than the nursing lamb or calf reared in confinement.

Signs of Iron Deficiency Anemia

Iron deficiency may vary from a borderline chronic anemia to acute anemia. Signs of chronic anemia are p