Determination of digestible energy values and fermentabilities of dietary fibre supplements: A European interlaboratory study in vivo
Research output: Contribution to journal › Journal article › Research › peer-review
Standard
Determination of digestible energy values and fermentabilities of dietary fibre supplements : A European interlaboratory study in vivo. / Livesey, G; Smith, T; Eggum, B O; Tetens, Inge H; Nyman, M; Roberfroid, M; Delzenne, N; Schweizer, T F; Decombaz, J.
In: British Journal of Nutrition, Vol. 74, No. 3, 1995, p. 289-302.Research output: Contribution to journal › Journal article › Research › peer-review
Harvard
APA
Vancouver
Author
Bibtex
}
RIS
TY - JOUR
T1 - Determination of digestible energy values and fermentabilities of dietary fibre supplements
T2 - A European interlaboratory study in vivo
AU - Livesey, G
AU - Smith, T
AU - Eggum, B O
AU - Tetens, Inge H
AU - Nyman, M
AU - Roberfroid, M
AU - Delzenne, N
AU - Schweizer, T F
AU - Decombaz, J
N1 - (Ekstern)
PY - 1995
Y1 - 1995
N2 - The performance of methods to determine energy conversion factors for dietary fibre (DF) supplements and fermentability (D) values of their non-starch polysaccharides (NSP) was investigated. Heats of combustion, digestible energy (DE) and D values were determined on five DF supplements in five European laboratories on five separate occasions. In each instance the DF supplements were fed to juvenile male Wistar rats at two doses, 50 and 100 g/kg basal diet, for 3 weeks with food and faeces collected in the 3rd week. Among-laboratory variations in heats of combustion (AHC) were < 2%. DE values (kJ/g dry weight) at the upper and lower doses respectively were: 10 4 and 99 for a high-methoxyl apple pectin, 95 and 9-4 for a sugar-beet DF supplement, 12 2 and 12-7 for soyabean DF supplement, 3-8 and 4-0 for maize bran, and 0 3 and 0-3 for Solka-floc cellulose. Variations among laboratories, among occasions and among animals were < 1, < 2 and < 2-5 kJ/g respectively. The among-occasion: among-laboratory variance ratio for DE was 0 5, suggesting the method performed equally well in all laboratories. There was no evidence of learning or fatigue in the performance of the method. D values were also independent of dose and at the high and lower doses were: pectin 0-92 and 0-95, sugar-beet NSP 0-68 and 0 68, soyabean NSP 0-86 and 0-88, maize bran 0-17 and 0-18, cellulose 0-07 and 0-06. Among-laboratory variance tended to increase with decreasing fermentability and ranged from 0-03 to 018. The DE and D data were not significantly different from a previously proposed relationship DE = 0-7 x AHC x Z), where AHC is the heat of combustion of the supplement. We conclude that while the among-laboratory variation in the D of difficult-to-ferment NSP is too large for the reliable prediction of energy value the method for the direct determination of DE is both reproducible and repeatable, that DE is independent of dosage of DF supplement up to 100 g/kg diet, and that it is safe to discriminate between energy values with a precision of 3 kJ/g. The conversion of both DE and D to net metabolizable energy for the purpose of food labelling, tables and databases is described.
AB - The performance of methods to determine energy conversion factors for dietary fibre (DF) supplements and fermentability (D) values of their non-starch polysaccharides (NSP) was investigated. Heats of combustion, digestible energy (DE) and D values were determined on five DF supplements in five European laboratories on five separate occasions. In each instance the DF supplements were fed to juvenile male Wistar rats at two doses, 50 and 100 g/kg basal diet, for 3 weeks with food and faeces collected in the 3rd week. Among-laboratory variations in heats of combustion (AHC) were < 2%. DE values (kJ/g dry weight) at the upper and lower doses respectively were: 10 4 and 99 for a high-methoxyl apple pectin, 95 and 9-4 for a sugar-beet DF supplement, 12 2 and 12-7 for soyabean DF supplement, 3-8 and 4-0 for maize bran, and 0 3 and 0-3 for Solka-floc cellulose. Variations among laboratories, among occasions and among animals were < 1, < 2 and < 2-5 kJ/g respectively. The among-occasion: among-laboratory variance ratio for DE was 0 5, suggesting the method performed equally well in all laboratories. There was no evidence of learning or fatigue in the performance of the method. D values were also independent of dose and at the high and lower doses were: pectin 0-92 and 0-95, sugar-beet NSP 0-68 and 0 68, soyabean NSP 0-86 and 0-88, maize bran 0-17 and 0-18, cellulose 0-07 and 0-06. Among-laboratory variance tended to increase with decreasing fermentability and ranged from 0-03 to 018. The DE and D data were not significantly different from a previously proposed relationship DE = 0-7 x AHC x Z), where AHC is the heat of combustion of the supplement. We conclude that while the among-laboratory variation in the D of difficult-to-ferment NSP is too large for the reliable prediction of energy value the method for the direct determination of DE is both reproducible and repeatable, that DE is independent of dosage of DF supplement up to 100 g/kg diet, and that it is safe to discriminate between energy values with a precision of 3 kJ/g. The conversion of both DE and D to net metabolizable energy for the purpose of food labelling, tables and databases is described.
UR - http://www.scopus.com/inward/record.url?scp=0029147414&partnerID=8YFLogxK
U2 - 10.1079/BJN19950136
DO - 10.1079/BJN19950136
M3 - Journal article
C2 - 7547845
AN - SCOPUS:0029147414
VL - 74
SP - 289
EP - 302
JO - British Journal of Nutrition
JF - British Journal of Nutrition
SN - 0007-1145
IS - 3
ER -
ID: 253136903