1. Introduction
Endogenous fat is produced continuously from the digestive tract mainly including bile, desquamated epithelial cells, intestinal secretions and microbial lipids. These endogenous fats are mixed with dietary lipids then partially digested and absorbed. The unabsorbed fraction is excreted and considered as the endogenous loss of fat (ELF) [
1,
2]. Precise measurement of these inevitable losses is of great significance for the determination of true digestibility of fat and determining fatty acid requirements. True digestibility of fat is more reflective of fat availability [
3]. Furthermore, fatty acids are the most important factors determining the nutritive value of fat [
4,
5]. However, there has been limited information about the endogenous losses of fatty acids (ELFA) published previously.
ELF may be influenced by many factors. Previous studies have focused on comparing the ELF of intact oils with their corresponding extracted oils [
6,
7,
8]. In addition, effects of dietary fiber on ELF have been well researched by Kil et al. [
6] and Chen et al. [
2]. Saturation degree and carbon chain length of fatty acids have an impact on digestion and absorption of oils in pigs [
9], and thus may impact reabsorption of endogenous fat. However, data that compares ELF in different oil sources containing diverse fatty acid composition has been limited. Oils are often used in the swine industry to increase energy density in diets and to improve growth performance of swine [
10]. Understanding the effect of different oils on ELF and ELFA systematically has important implications for effective utilization of oil in commercial practices.
Endogenous loss of fat can be measured by different methods. One of the most common methods is to provide graded dietary concentrations of fat and perform a regression to estimate endogenous loss and true digestibility of fat [
11]. A second method requires feeding the animal a fat-free diet and measuring the fat content in feces, which represents the endogenous losses [
2]. Regression methods have been widely used to evaluate ELF in pigs [
6,
7,
8,
11], but research on fat-free diet methods is limited. Comparing the two methods is important for future method selection.
One objective of this study was to determine the effect of oil sources with differing degrees of fatty acid saturation on endogenous losses of fat and fatty acids in growing pigs using palm oil (PO), soybean oil (SBO), flaxseed oil (FSO) and rapeseed oil (RSO). A second objective was to compare estimations of endogenous losses by fat-free diet and regression method.
4. Discussion
The regression method was used to estimate ELF and TTTD for four oils in the current study. A linear response of total apparently digested fat to dietary fat intake is a prerequisite of using the regression method [
6,
11]. The content and nature of fiber among diets should be similar for accurate estimation of the ELF [
7]. These conditions were all met in the present experiment. In addition, this experiment utilized highly digestible, semi-purified diets to evaluate the fat excreted by pigs at zero fat intake, allowing for the estimation of ELF with little influence from dietary ingredients.
To our knowledge, this was the first study that estimated ELF value for FSO (4.17 g/kg DMI). In the current experiment, the ELF estimates for PO, SBO and RSO were 6.28, 5.30 and 4.84 g/kg DMI over the entire intestinal tract, respectively, which were less than 10.80 [
21], 14.02 [
22] and 23.0 g/kg DMI [
8], respectively. This difference could be due to more purified ingredients in diets fed in the present study. Instead of feeding traditional diets based on natural ingredients (corn, barley, soybean meal, canola meal), cornstarch and soy protein isolate containing lower fiber content were formulated in the present diets. Previous studies reported that greater dietary fiber content resulted in increasing endogenous fat excretion [
2,
6,
7]. In addition, purified ingredients with high digestibility may decrease endogenous fat excretion [
22,
23]. Estimation of ELF for SBO in this experiment was close to the value reported by Jørgensen et al. [
11] because purified ingredients were used in both studies. Furthermore, the least concentration of dietary fat fed and range in fat concentration would affect the estimation of ELF [
6].
Oil sources containing different fatty acid compositions may affect digestion, absorption and metabolic utilization of dietary fat [
5], which may also affect reabsorption of endogenous fat. Therefore, four vegetable oils were chosen for their starkly different fatty acid compositions. When using the regression method, the estimated ELF values over the entire intestinal tract were not different in pigs fed PO, SBO, FSO or RSO. This observation is in agreement with a previous study where the amount of ELF was not different in pigs fed coconut oil or soybean oil [
24]. Furthermore, there was no significant correlation between the concentration of ELF and fatty acid composition. This result confirms that vegetable oil sources containing diverse fatty acid composition had no effect on the estimation of ELF. The experiment indicates that the amount of ELF had a tendency (
p < 0.10) to be positively correlated with SFAs. This may have been because fatty acid types could distinctly impact gut bacteria [
25]. The polyunsaturated fatty acids had a stronger inhibitory effect on gut bacteria than SFAs [
26], so the great amount of SFAs could have increased the excretion of bacterial lipids.
The TTTD of fat in pigs fed PO, SBO and RSO diets were very similar to those reported previously for PO (91.9%) [
21], SBO (95.4%) [
22] and RSO (100%) [
8]. The TTTD of fat in diets was above 90%, regardless of oil sources, and reveals that vegetable oils are highly digestible ingredients for growing pigs. Within regression equations, greater TTTD of fat in pigs fed FSO and RSO diets rather than an PO diet was observed. The reason for this may be a higher U:S in FSO and RSO compared with PO [
9].
To our knowledge, little information about ELFA of pigs exists. According to our regression equations (
Table 6), average contents of endogenous losses of C16:0, C18:0 and C18:1 for four oils were 0.64, 0.81 and 0.11 g/kg DMI, respectively. These values were slightly higher than those of Jørgensen et al. [
11], who reported that endogenous losses of C16:0, C18:0 and C18:1 for soybean oil were 0.41, 0.21 and 0.10 g/kg of DMI, respectively. In the study of Jørgensen et al. [
11], however, addition of soybean oil was up to 3% only, which would have influenced the estimation of ELFA. The estimated values for endogenous loss of individual fatty acid in pigs fed PO, SBO, FSO or RSO were not different, indicating that the estimation of ELFA was not influenced by vegetable oil sources. In the current study, the fact that most of the estimated ELFA by the regression method was not different from 0 is a reflection of the relatively large variability in ELFA.
A fat-free diet was fed to pigs to allow the measurement of fat content in feces that represented the ELF. However, unlike a protein-free diet, no routine fat-free diet was available for determining ELF in pigs. In this experiment, preparation of fat-free diets with cornstarch, soy protein isolate, sucrose and rice hull (0.23% EE, DM basis) resulted in an estimated value of 2.60 g/kg DMI for ELF. Chen et al. [
2] researched the effect of fiber on ELFA in growing pigs using the fat-free diet method, and reported that the major components of ELFA over the entire intestinal tract were C16:0, C18:0, C18:1 and C18:2, which is in general agrees with our results. In addition to the even-chain fatty acids, bacteria also contain many odd-chain fatty acids [
27,
28]. The amounts of C15:0 and C17:0 in ELFA were relatively high in the current experiment, which confirms that microbial lipids could be a substantial source of ELF. Only 37.69% of the ELF was accounted for by ELFA in this experiment. The balance (62.31%) comes from non-fatty acid sources including cholesterol, bile acids [
29], desquamated intestinal epithelial cells [
1] or phospholipids and sphingolipids of microbial origin [
1,
30]. Similarly, Tancharoenrat et al. [
31] reported that only 48.1% of the endogenous fat was of fatty-acid origin in broiler chickens.
Notably, even under the closely controlled experimental conditions, differences in ELF and ELFA could be observed using different estimation methods. In the current experiment, the fat-free diet had lower ELF and ELFA values compared with the regression method. This was linked to the low fat content in the fat-free diet, which was far below the fat content of normal diets for growing pigs. The low fat content of the fat-free diet increases reabsorption of endogenous fat [
1]. According to this experiment, we can clearly see that fewer pigs were required for the fat-free diet method. However, the regression method is more complicated and costly, and taking estimate values extrapolated to zero intake of a particular source of oil, instead of directly measuring fat content in feces, can bias the data, with the risk of overestimating the endogenous excretion. There is large variability in the estimation of ELFA by the regression method. Furthermore, the composition of the experimental diet used in the regression method has a large impact on endogenous losses, but no unified diets are available for determining ELF. Based on these considerations, estimation for endogenous losses using the fat-free diet method is an attractive method for correcting apparent digestibility of fat and fatty acids, and the fat-free diet deserves to be explored further.
The ATTD of fat in diet increased as the inclusion level of oil in diets increased, regardless of oil sources. This result is in agreement with previous studies in pigs fed extracted oil diets [
6,
7,
11,
21], intact oil diets [
6,
8,
32] and diets containing both [
33]. In this experiment, the contribution of ELF to total fecal fat decreased as the inclusion level of oil in diets increased, reflecting a greater effect of ELF on apparent digestibility at lower dietary fat levels than at higher levels. Furthermore, the amount of ELF obtained by the regression method would have accounted for more than 50% of the total fecal fat (
Table 8). Therefore, the effect of ELF on the true digestibility of fat cannot be ignored. The ATTD of fat in diets could not reflect the true availability of fat, especially in low fat diets, so consideration should be given to estimating ELF to determine true digestibility.