TY - JOUR
T1 - Gas production and starch degradability of corn and barley meals differing in mean particle size
AU - Gallo, Antonio
AU - Giuberti, Gianluca
AU - Masoero, Francesco
PY - 2016
Y1 - 2016
N2 - The objective of this study was to verify the effect of
mean particle size (mPS) on both gas production and
in vitro rumen starch degradability (IVSD) of corn and
barley meals (Cm and Bm, respectively). Batches of
the same Cm or Bm were separately processed through
2 different mills (i.e., a cutter mill or a rotor speed mill)
equipped with or without different screens to achieve
different mPS for each tested meal. Samples were analyzed
accordingly to a completely randomized design
and the main tested effect of model was mPS (n = 11,
from 0.46 to 3.50 mm mPS for Cm or n = 10, from 0.11
to 2.98 mm mPS for Bm). For both in vitro assays, the
rumen inocula were collected from 2 rumen-fistulated
Holstein lactating dairy cows fed a total mixed ration
with 16.2% crude protein, 28.5% starch, and 35.0%
neutral detergent fiber on a dry matter basis. To fit gas
production data, 1-pool exponential model and 1-pool
or 2-pool Gompertz models were adopted. The rate of
gas production decreased and lag increased by increasing
mPS of both Cm and Bm, irrespective of adopted
1-pool models. When the 2-pool Gompertz model was
used to fit gas production data, a shift of particles from
fast to slow fermentable pools was measured by increasing
mPS. In particular, the ratio between fast and slow
final volumes ranged from 0.90 at 0.11 mm mPS to 0.10
at 2.98 mm mPS for Bm. For Cm, the ratio between
fast and slow final volumes decreased quadratically
by increasing mPS, with the highest value (i.e., 0.58)
measured at the lowest tested mPS. Values lower than
0.10 were measured for mPS greater than 1.93 mm for
Cm. Concerning IVSD data, linear decreases in rate
of starch degradation equal to −0.049 or −0.092 h−1
for each 1-mm increase in mPS were achieved for Cm
and Bm, respectively. The 7-h IVSD decreased by 6.3
or 6.5% starch for each 1-mm increase in mPS of Cm
or Bm, respectively. Present findings supported the
hypothesis that different particle sizes within the same
starch source represent an important factor influencing
both fermentation kinetic parameters and IVSD.
AB - The objective of this study was to verify the effect of
mean particle size (mPS) on both gas production and
in vitro rumen starch degradability (IVSD) of corn and
barley meals (Cm and Bm, respectively). Batches of
the same Cm or Bm were separately processed through
2 different mills (i.e., a cutter mill or a rotor speed mill)
equipped with or without different screens to achieve
different mPS for each tested meal. Samples were analyzed
accordingly to a completely randomized design
and the main tested effect of model was mPS (n = 11,
from 0.46 to 3.50 mm mPS for Cm or n = 10, from 0.11
to 2.98 mm mPS for Bm). For both in vitro assays, the
rumen inocula were collected from 2 rumen-fistulated
Holstein lactating dairy cows fed a total mixed ration
with 16.2% crude protein, 28.5% starch, and 35.0%
neutral detergent fiber on a dry matter basis. To fit gas
production data, 1-pool exponential model and 1-pool
or 2-pool Gompertz models were adopted. The rate of
gas production decreased and lag increased by increasing
mPS of both Cm and Bm, irrespective of adopted
1-pool models. When the 2-pool Gompertz model was
used to fit gas production data, a shift of particles from
fast to slow fermentable pools was measured by increasing
mPS. In particular, the ratio between fast and slow
final volumes ranged from 0.90 at 0.11 mm mPS to 0.10
at 2.98 mm mPS for Bm. For Cm, the ratio between
fast and slow final volumes decreased quadratically
by increasing mPS, with the highest value (i.e., 0.58)
measured at the lowest tested mPS. Values lower than
0.10 were measured for mPS greater than 1.93 mm for
Cm. Concerning IVSD data, linear decreases in rate
of starch degradation equal to −0.049 or −0.092 h−1
for each 1-mm increase in mPS were achieved for Cm
and Bm, respectively. The 7-h IVSD decreased by 6.3
or 6.5% starch for each 1-mm increase in mPS of Cm
or Bm, respectively. Present findings supported the
hypothesis that different particle sizes within the same
starch source represent an important factor influencing
both fermentation kinetic parameters and IVSD.
KW - cereal
KW - gas production
KW - particle size
KW - starch degradation
KW - cereal
KW - gas production
KW - particle size
KW - starch degradation
UR - http://hdl.handle.net/10807/75613
U2 - 10.3168/jds.2015-10779
DO - 10.3168/jds.2015-10779
M3 - Article
SN - 0022-0302
SP - 1
EP - 13
JO - Journal of Dairy Science
JF - Journal of Dairy Science
ER -