Food Biochemistry and Food Processing (2 edition)

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516 Part 4: Milk

Stage of lactation (wk)

0 2 4 6 8 10 12 14 16 18

Salt concentration (mg/mL)

0

200

400

600

800

1000

1200

1400

1600

Figure 26.5.Influence of the stage of lactation on the concentration
of calcium (•), magnesium (◦), phosphate (), potassium (∇)or
sodium () in equine milk. (Data from Schryver et al. 1986.)

by the stage of lactation (Fig. 26.5), which shows a progressive
decrease in the concentrations of calcium, magnesium, phos-
phorus, sodium and potassium from the end of the first week of
lactation. The concentration of calcium in equine milk increases
during the first week of lactation, before decreasing steadily
thereafter (Ullrey et al. 1966). As in the milk from all mammals
which have been studied in sufficient detail, the concentrations
of calcium and phosphate in equine milk far exceeds the solubil-
ity of calcium phosphate in milk. As a result, part of the calcium
and phosphate exist in a non-ultrafiltrable, micellar, form, that
is MCP. Holt and Jenness (1984) reported that approximately
60%, 20% or 40% of total calcium, magnesium or inorganic
phosphorus, respectively, in equine milk are non-ultrafiltrable,
compared to approximately 70%, 35% or 45% of total calcium,
magnesium and inorganic phosphorus in bovine milk. On the
basis of measurements of the distribution of salts between the
ultrafiltrable and non-ultrafiltrable phase of milk, Holt and Jen-
ness (1984) estimated the concentrations of ionic calcium and
magnesium in equine milk at pH 7.0 are 2.5 and 0.6 mmol L−^1 ,
respectively, compared to 2.0 or 0.8 mmol L−^1 , respectively, in
bovine milk at pH 6.7. For human infant nutrition, a Ca:P ratio
of approximately 2:1 is considered optimal; for bovine milk, the
ratio is approximately 1:1, but in equine milk it is about 2:1, and
is very close to that in human milk.

Trace Elements

Data on concentrations of trace elements, that is, those elements
present at concentrations less than 30 mg L−^1 , in equine milk
have been sporadic. The concentrations of trace elements in
equine, bovine and human milk are compared in Table 26.15.
Compared to bovine milk, equine milk contains markedly higher
levels of aluminum, copper, iron and titanium but lower lev-
els of boron, barium, lithium, molybdenum, manganese, silicon

Table 26.15.Concentrations of Trace Elements
(μg.L−^1 ) in Equine, Bovine and Human Milk

Species

Element Equine Bovine Human

Aluminum 123 98 125
Boron 97 333 273
Barium 76 188 149
Copper 155 52 314
Iron 224 194 260
Lithium 15 24 7
Molybdenum 16 22 17
Manganese 14 21 7
Silicon 161 434 472
Strontium 442 417 60
Titanium 145 111 25
Zinc 1835 3960 2150

Source: Modified from Anderson 1992.

and zinc. Human milk contains more boron, barium, copper,
iron, silicon and zinc, but less lithium, manganese, strontium
and titanium than equine milk (Table 26.15). Concentrations
of zinc, iron and copper in equine milk decrease progressively
with advancing lactation, whereas the concentration of man-
ganese increases during the first 5 days of lactation, after which
it decreases progressively (Csapo-Kiss et al. 1995, Ullrey et al. ́
1974).

PHYSICAL PROPERTIES OF EQUID MILK


The physical properties of the milk of some species are compared
in Table 26.16.

Density

The density (kg m−^3 ) of equine colostrum is higher than that of
equine milk (Waelchli et al. 1990, Ullrey et al. 1966, Mariani
et al. 2001), due primarily to its considerably higher protein
content. Values for colostrum can reach up to approximately
1080 kg m−^3 (Ullrey et al. 1966) and show a significant linear
correlation with the IgG content of colostrum (Waelchli et al.
1990, LeBlanc et al. 1986). Density is highest immediatelypost-
partumand decreases rapidly during the first 12 h (Ullrey et al.
1966); considerably smaller decreases in density are observed
during the rest of lactation (Ullrey et al. 1966, Mariani et al.
2001). Density values reported for mature equine milk range
from approximately 1028 to 1035 kg m−^3. The density of whole
mature bovine milk normally ranges from 1027 to 1033 kg m−^3
(Singh et al. 1997).

Refractive Index

The refractive index for equine colostrum ranges from 1.340
to 1.354, whereas that of mature equine milk is approximately
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