Apparent digestibility of amino acids in feedstuffs used in diets for the Pacific white shrimp, Penaeus vannamei

Villarreal-Cavazos, David Alonso; Ricque-Marie, Denis; Nieto-López, Martha; Tapia-Salazar, Mireya; Lemme, Andreas; Gamboa-Delgado, Julián; Cruz-Suárez, Lucia Elizabeth; Villarreal-Cavazos, David Alonso; Ricque-Marie, Denis; Nieto-López, Martha; Tapia-Salazar, Mireya; Lemme, Andreas; Gamboa-Delgado, Julián; Cruz-Suárez, Lucia Elizabeth

doi:10.7773/cm.v45i3.3007

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Ciencias marinas

versão impressa ISSN 0185-3880

Cienc. mar vol.45 no.3 Ensenada Set. 2019 Epub 30-Jul-2021

https://doi.org/10.7773/cm.v45i3.3007

Articles

Apparent digestibility of amino acids in feedstuffs used in diets for the Pacific white shrimp, Penaeus vannamei

Eficiencia digestiva aparente de aminoácidos en ingredientes utilizados en dietas para camarón blanco del pacífico, Penaeus vannamei

David Alonso Villarreal-Cavazos¹^*
http://orcid.org/0000-0001-5572-9710

Denis Ricque-Marie¹
http://orcid.org/0000-0003-1029-1561

Martha Nieto-López¹
http://orcid.org/0000-0002-1000-4406

Mireya Tapia-Salazar¹
http://orcid.org/0000-0002-1048-9781

Andreas Lemme²

Julián Gamboa-Delgado¹
http://orcid.org/0000-0001-9041-1388

Lucia Elizabeth Cruz-Suárez¹
http://orcid.org/0000-0003-3808-2972

^¹Departamento de Ecología, Facultad de Ciencias Biológicas, Universidad Autónoma de Nuevo León, Cd. Universitaria, CP 66450, Monterrey (San Nicolás de los Garza), Nuevo León, Mexico.

^²Evonik Degussa GmbH, Rodenbacher Chaussee 4, D-63457 Hanau (Wolfgang), Germany.

Abstract

Apparent digestibility coefficients (ADC) for dry matter, energy, crude protein (CP), and amino acids (AA) were evaluated for 4 feedstuffs used to feed juvenile white shrimp (Penaeus vannamei): fish meal (73.5% CP), potato protein concentrate (89.3% CP), brewer’s yeast (42.5% CP), and crustacean meal (47.2% CP). Experimental diets included 30% of the test ingredient and 69% of a commercial diet supplemented with 1% chromium oxide as inert marker. Amino acid contents in the ingredients, experimental diets, leached diets, and feces were analyzed by high-performance liquid chromatography. Nutrient loss in water was highest in the fishmeal diet (25%). The AA with the highest losses in water were lysine, methionine, and arginine (25%, 23%, and 21%, respectively). The ADC for dry matter oscillated between 79.2% and 90.6%, for CP between 78.1% and 91.8%, and for AA between 75.4% and 96.6%. In all cases the lower limit corresponded to the meal with potato protein concentrate and the upper limit to the crustacean meal. The ADC for energy fluctuated between 89.1% and 95.2%, with the lower limit for the crustacean meal and the upper limit for the meal with potato protein concentrate.

Key words: digestibility; shrimp; Penaeus vannamei; amino acids

Resumen

Los coeficientes de digestibilidad aparente (CDA) de materia seca, energía, proteína cruda (PC) y aminoácidos (AA) fueron evaluados en 4 ingredientes utilizados para alimentar juveniles de camarón blanco (Penaeus vannamei): harina de pescado (73.5% PC), concentrado proteico de papa (89.3% PC), levadura de cerveza (42.5% PC) y harina de crustáceo (47.2% PC). Las dietas experimentales incluyeron 30% del ingrediente prueba y 69% de una dieta comercial suplementada con 1% de óxido de cromo como marcador inerte. El contenido de aminoácidos en los ingredientes, las dietas formuladas, las dietas lixiviadas y las heces fue analizado por cromatografía líquida de alta resolución. La mayor pérdida de nutrientes en el agua se presentó con la dieta de harina de pescado (25%). Los AA con mayor pérdida en el agua fueron la lisina, la metionina y la arginina (25%, 23% y 21%, respectivamente). Los CDA para la materia seca oscilaron entre el 79.2% y el 90.6%, para la PC entre el 78.1% y el 91.8%, y para los AA entre el 75.4% y el 96.6%. En todos los casos el límite inferior correspondió al concentrado proteico de papa y el superior a la harina de crustáceo. El CDA para la energía fluctuó entre el 89.1% y el 95.2%, con el límite inferior para la harina de crustáceo y el superior para el concentrado proteico de papa.

Palabras clave: eficiencia digestiva; camarón; Penaeus vannamei; aminoácidos

Introduction

Aquaculture feed production is increasingly challenged by the rising cost and limited production of fish meal, the main ingredient in feeds. In the shrimp farming industry, feed is the most expensive input in the variable costs of production when operating grow-out farms. Today a wide range of alternative feedstuffs have to be considered to reduce the amount of fish meal used in penaeid shrimp feed. These feedstuffs must be well characterized to understand their nutritional quality, which is particularly important in the formulation of efficient (highly digestible), ecologically sustainable (low-polluting), and economically competitive feeds. In particular, the apparent digestibility of nutrients in feedstuffs, namely amino acids, plays a very important role in the nutritional quality of feeds. The aim of the present study is to evaluate the apparent digestibility efficiency of dry matter, energy, proteins, and amino acids in a reference diet (commercial diet) and in 4 feedstuffs used in shrimp feed: Pilchard meal (Sardinops sagax), potato protein concentrate (Solanum tuberosum), brewer’s yeast (Saccharomyces cerevisiae), and crustacean meal (Heterocarpus reedi). Apparent digestibility coefficients were adjusted to account for nutrient losses (nutrient leaching) in seawater.

Materials and Methods

Feedstuffs were obtained from feed mills and/or their distributors. We obtained the fish meal (S. sagax) and potato protein concentrate (S. tuberosum) from Sonora (Mexico), the brewer’s yeast (S. cerevisiae) from Baja California (Mexico), and the crustacean meal (H. reedi) from Santiago (Chile). Feeds were prepared following the method described by ^{Villarreal-Cavazos et al.
(2017)}; test ingredients were mixed in a KitchenAid mixer (Benton Harbor, Michigan) for 10 min while adding warm water (30%), and then for 15 min after water was incorporated. A Torrey meat grinder (Monterrey, Mexico) with 1.6-mm holes was used. Manufacturing time was 40 min per kilogram of feed, and manufacturing temperatures reached 75-80 ºC. The extruded feed was dried in a ventilated oven at 100 ºC for 8 min and kept at room temperature for one night before packing. Digestibility of feedstuffs was determined following the method described by ^{Cho and Slinger (1979)}. Experimental diets contained 30% of the test ingredient and 70% of the reference diet (^{Cruz-Suárez et al. 2009}).

The digestibility trial was carried out in a closed recirculating artificial seawater system at the Mariculture Program facilities (Faculty of Biological Sciences, Autonomous University of Nuevo León). Twenty-eight identical, fiberglass aquariums with 120-L capacity and regulated flow rate of 710 mL·min^-1 were used. Tanks were randomly distributed. Each diet was tested in 4 replicate tanks with 24 Peaneus vannamei juveniles (5.4 ± 0.1 g) each. Shrimp were fed ad libitum starting with 10% of total biomass in the tank. Fresh feces were collected (12 g) from each tank with a siphon, immediately after excretion, over a period of 7 d.

The bromatological composition of feedstuffs, diets, and feces was determined with the following methods: 930.15, 990.03, 942.05, and 962.09B for moisture, crude protein, ash, and fiber, respectively (^{AOAC
International 1997}). Lipids were extracted using the Soxhlet method (^{Tecator 1983}), and the nitrogen free extract was calculated as the difference. Nutrient loss in seawater was determined according to the method reported by ^{Tapia-Salazar et
al. (2012)}. Chrome content was determined according to the method described by ^{Bolin et al. (1952)} and modified by ^{Cruz-Suárez et al. (2009)}. Amino acid composition was determined according to ^{Llames and
Fontaine (1994)} and ^{Fontaine
(2003)}. The apparent digestibility coefficients (ADCs) for dry matter, protein, and amino acids in the diets were calculated using the following equation: %ADC_diet = 100 - [100(C_diet/N_diet) × (N_feces/ C_feces)], where C and N are, respectively, the chromium oxide and nutrient concentrations in the diets or feces (dry weight basis). The ADCs for feedstuffs were calculated according to ^{Bureau and Hua (2006)}. The ADCs for diets and feedstuffs were adjusted considering the percentage of nutrient loss in water due to leaching (^{Villarreal-Cavazos et al. 2014}). We used the leaching values that were obtained after 1-h immersions of feeds in seawater. To account for losses in dietary dry matter, protein, and amino acids before ingestion by the animal, the ADC for each nutrient was corrected for using the equations reported by ^{Nieto-López et al. (2011)}. Nutrient concentration values (feedstuffs, diets, leached diets, feces) and ADCs were subjected to a one-way analysis of variance and Duncan’s multiple range test to separate the treatment averages into normal and homogenous groups. The software used was SPSS v.22 for Windows.

Results

Crude protein content ranged from 42.5% to 89.3%. Lipids oscillated between 1.4% and 10.8% and crude fiber between 0.1% and 3.4%. The range for ash content was 5.3-18.1%. Amino acid (AA) proximate composition and AA contents varied greatly between feedstuffs (Table 1). The composition of experimental feeds showed values that were very close to the expected values, according to calculations based on the nutrient concentrations of feedstuffs in the formulated feeds (Table 2). Feeds containing crustacean meal and the fish meal showed the highest nutrient losses (20% and 24%, respectively) in seawater (Table 3). The AAs with the highest losses in seawater were lysine, methionine, and arginine (27%, 24%, and 20%, respectively) (Table 3).

Table 1 Proximate composition and amino acid contents for the different experimental feedstuffs.

	FM	PPC	BY	CM
Proximal composition (% DM)
Crude protein	69.7	89.3	42.5	47.2
Crude fat	10.8	1.4	3.2	3.4
Crude fiber	0.0	0.2	2.2	3.4
Ash	18.1	5.3	6.3	13.3
Nitrogen-free extract	0.0	3.2	45.0	31.3
Gross energy (cal·g^-1)	4,605	5,510	5,052	4,773
Amino acid profile (%)
Arginine	4.03	4.4	2.5	2.2
Histidine	1.87	2.0	1.0	0.9
Isoleucine	2.62	5.0	1.7	1.7
Leucine	4.86	9.2	2.5	2.7
Lysine	5.22	7.2	2.6	2.2
Methionine	1.80	1.9	0.6	0.8
Phenylalanine	2.63	5.7	1.6	2.1
Threonine	2.81	5.2	1.8	1.6
Valine	3.19	6.0	2.1	2.1
Sum of EAA	29.0	46.7	16.3	16.3
Alanine	4.31	4.4	2.3	2.4
Aspartic acid	6.20	10.9	3.5	3.8
Cystine	0.58	1.2	0.5	0.4
Glutamic acid	8.51	9.5	5.7	5.1
Glycine	4.67	4.5	1.9	2.5
Proline	3.07	4.6	2.0	1.9
Serine	2.67	4.8	1.8	1.6
Sum of analyzed AA	59.10	86.4	34.2	34.0

DM: dry matter; cal: calories; EAA: essential amino acids; AA: amino acids; FM: fish meal; PCC: potato protein concentrate; BY: beer yeast; CM: crustacean meal.

Table 2 Formula (g·kg^-1; dry matter, DM) for experimental diet composition.

	RD	FMD	PPCD	BYD	CMD
Reference ingredient+	1,000	700	700	700	700
Fish meal	-	300	-	-	-
Potato protein concéntrate	-		300	-	-
Beer yeast	-		-	300	-
Crustacean meal	-		-	-	300
Proximal composition (% DM)
Crude protein	34.6	46.5	50.3	36.2	37.7
Crude fat	10.6	10.5	7.8	8.3	8.4
Crude fiber	3.7	2.1	2.6	3.3	3.7
Ash	11.0	14.5	9.4	9.7	12.0
Nitrogen-free extract	39.9	26.9	---	42.2	---
Gross energy (cal·g^-1)	4,750	4,162	4,949	4,811	4,728
Arginine	2.0	2.8	2.7	2.1	2.0
Histidine	0.7	1.1	1.1	0.8	0.8
Isoleucine	1.3	1.8	2.4	1.5	1.4
Leucine	2.3	3.2	4.3	2.5	2.4
Lysine	1.8	3.1	3.4	2.2	1.8
Methionine	0.7	1.1	1.0	0.7	0.7
Phenylalanine	1.6	2.0	2.7	1.6	1.7
Threonine	1.2	1.8	2.3	1.5	1.3
Valine	1.5	2.2	2.9	1.8	1.7
Sum of EAA	13.1	19.0	22.8	14.7	13.8
Alanine	1.8	2.7	2.5	2.1	1.9
Aspartic acid	2.9	4.1	5.2	3.3	3.1
Cystine	0.4	0.4	0.6	0.4	0.4
Glutamic acid	6.0	7.1	7.0	5.7	5.7
Glycine	2.0	3.0	2.7	2.0	2.1
Proline	2.2	2.6	2.8	2.1	2.1
Serine	1.4	1.8	2.3	1.7	1.4
Sum of analyzed AA	29.8	40.8	45.9	32.0	30.5

⁺Shrimp commercial feed.

RD: reference diet; FMD: fish meal diet; PPCD: potato protein concentrate diet; BYD: beer yeast diet; CMD: crustacean meal diet; cal: calories; EAA: essential amino acids; AA: amino acids.

Table 3 Dietary nutrient losses (percentage of initial content) in seawater.

	RD	FMD	PPCD	BYD	CMD	Mean⁺
Dry matter	14	5	13	11	7	10
Crude protein	25	25	13	2	20	17b
Arginine	23	19	19	14	24	20c
Histidine	11	20	16	6	18	14ab
Isoleucine	13	34	16	3	20	17b
Leucine	9	20	13	4	16	12a
Lysine	25	42	23	16	29	27e
Methionine	31	22	25	17	26	24e
Phenylalanine	12	26	13	4	16	14ab
Threonine	11	38	12	4	15	16ab
Valine	9	21	16	5	20	14ab
Sum of EAA	15	10	17	8	20	14ab
Alanine	15	19	16	11	22	17b
Aspartic acid	13	25	13	5	15	14ab
Cystine	18	22	12	5	11	14ab
Glutamic acid	16	20	16	6	16	15ab
Glycine	26	32	19	11	25	23c
Proline	23	32	18	10	19	20c
Serine	14	30	12	9	18	17b
Sum of analyzed AA	17	22	16	8	19	16ab
Mean (all AA)	17	24	17	8	20	17b

⁺Analysis of variance for AA (P < 0.001); different letters indicate significant differences according to Duncan’s multiple range test (α = 0.05).

RD: reference diet; FMD: fish meal diet; PPCD: potato protein concentrate diet; BYD: beer yeast diet; CMD: crustacean meal diet; EAA: essential amino acids; AA: amino acids.

The ADC varied between 79% and 91% for dry matter, between 89% and 95% for energy, and between 78% and 93% for crude protein. The ADC for total AAs varied between 75% and 97% (Table 4). AAs in the crustacean meal feed proved to be highly digestible (94.6% mean digestibility). Digestibility of AAs in the brewer’s yeast meal was good (87.1%). Mean AA digestibility was lowest in the potato protein concentrate (75.2%). In general, mean digestibility of AAs in the experimental feedstuffs was more than 90%, except in the case of cystine (80.6%). The AAs with digestibility values greater than 95% were methionine, isoleucine, lysine, glycine, and proline. Cystine was the least digestible AA. Corrections for nutrient leaching tended to reduce standard ADC values for most of the experimental feedstuffs (Table 5).

Table 4 Apparent digestibility coefficients for dry matter, energy, crude protein, and amino acids of ingredients used in Pacific white shrimp (Litopenaeus vannamei) diets.

	FM	PPC	BY	CM⁺
Dry matter	90 ± 3a	79 ± 1c	82 ± 2b	91 ± 2a
Energy	93 ± 1b	95 ± 1a	90 ± 4c	89 ± 1c
Crude protein	93 ± 2a	78 ± 2d	87 ± 4b	92 ± 2a
Arginine	98 ± 1a	79 ± 1d	92 ± 4c	96 ± 4b
Histidine	97 ± 1a	77 ± 1d	88 ± 5c	92 ± 4b
Isoleucine	93 ± 1a	75 ± 1d	88 ± 6c	96 ± 4b
Leucine	94 ± 1a	75 ± 1c	88 ± 6b	96 ± 5a
Lysine	96 ± 1a	80 ± 2c	92 ± 8b	96 ± 6a
Methionine	99 ± 1a	80 ± 2d	90 ± 6c	97 ± 4b
Phenylalanine	93 ± 1a	74 ± 1d	87 ± 5c	93 ± 4b
Threonine	99 ± 1a	72 ± 1d	84 ± 6c	93 ± 4.b
Valine	97 ± 1a	76 ± 1c	90 ± 6b	96 ± 3a
Sum of EAA	98 ± 1a	76 ± 1d	88 ± 6c	95 ± 4b
Alanine	97 ± 1a	76 ± 1c	89 ± 4b	97 ± 4a
Aspartic acid	97 ± 1a	73 ± 1d	87 ± 5c	94 ± 4b
Cystine	90 ± 3a	66 ± 1d	73 ± 6c	87 ± 5b
Glutamic acid	97 ± 1a	76 ± 1d	88 ± 4c	95 ± 4b
Glycine	89 ± 2b	77 ± 1c	89 ± 3c	100 ± 1a
Proline	97 ± 1a	72 ± 1d	85 ± 5c	92 ± 4b
Serine	98 ± 1a	76 ± 1c	87 ± 4b	97 ± 3a
Sum of analyzed AA	97 ± 1a	75 ± 1c	88 ± 5b	95 ± 4a

⁺Analysis of variance for AA (P < 0.001); different letters indicate significant differences according to Duncan’s multiple range test (a = 0.05).

FM: fish meal; PPC: potato protein concentrate; BY: beer yeast; CM: crustacean meal; EAA: essential amino acids; AA: amino acids.

Table 5 Apparent digestibility coefficients (%) adjusted for nutrient losses in seawater prior to ingestion.

	FM	PPC	BY	CM+
Dry matter	85 ± 5b	78 ± 1d	82 ± 3c	94 ± 2a
Crude protein	86 ± 3c	77 ± 2d	91 ± 5b	97 ± 2a
Arginine	98 ± 2a	75 ± 2c	92 ± 4b	94 ± 5b
Histidine	97 ± 2a	71 ± 1c	88 ± 5b	87 ± 5b
Isoleucine	96 ± 2a	69 ± 1c	90 ± 5b	92 ± 5b
Leucine	96 ± 1a	70 ± 1d	89 ± 6c	92 ± 5b
Lysine	99 ± 1a	74 ± 3c	93 ± 1b	93 ± 1b
Methionine	97 ± 2a	75 ± 2c	96 ± 5ab	98 ± 2a
Phenylalanine	94 ± 2a	69 ± 1c	89 ± 5b	91 ± 5b
Threonine	96 ± 2a	68 ± 1d	85 ± 1c	91 ± 2b
Valine	95 ± 1a	71 ± 1d	88 ± 2c	90 ± 1b
Sum of EAA	97 ± 2a	71 ± 2c	90 ± 1b	92 ± 1b
Alanine	96 ± 2a	71 ± 2d	90 ± 2c	93 ± 1b
Aspartic acid	96 ± 2a	69 ± 1c	89 ± 2b	92 ± 2b
Cystine	87 ± 1b	64 ± 1d	81 ± 2c	95 ± 1a
Glutamic acid	96 ± 2a	72 ± 2d	90 ± 2c	94 ± 1b
Glycine	85 ± 2b	74 ± 1c	99 ± 1a	99 ± 1a
Proline	96 ± 2a	69 ± 1c	85 ± 1b	88 ± 1b
Serine	96 ± 1a	71 ± 1c	92 ± 1b	98 ± 1a
Sum of analyzed AA	96 ± 2a	71 ± 1d	90 ± 2c	93 ± 2b

⁺Analysis of variance for AA (P < 0.001); different letters indicate significant differences according to Duncan’s multiple range test (a = 0.05).

FM: fish meal; PPC: potato protein concentrate; BY: beer yeast; CM: crustacean meal; EAA: essential amino acids; AA: amino acids.

Discussion

The AA proximate composition and AA contents found for the different feedstuffs were similar to what has been previously reported (^{NRC
1983}, ^{Novus 1996}, ^{Hess et al. 2006}). In addition, in terms of dry matter, energy, crude protein, and total AAs, all feedstuffs (fish meal, crustacean meal, brewer’s yeast, and potato protein concentrate) were more digestible than the reference diet. ^{Goytortúa-Bores et al. (2006)} analyzed the crustacean meal (red crab, Pleuroncodes planipes) used to feed Pacific white shrimp and found that ADC values for crude protein were lower than the value observed in the present study (82-84% vs 92.8%). This value coincides with that reported by ^{Tibbets
et al. (2006)} for whole krill fed to cod (96%). ^{Ozório et al. (2012)} evaluated the increasing levels of brewer’s yeast in tilapia feed and found that apparent digestibility of crude protein decreased (82.3%, 81.3%, 78.6%, 78.1%, and 79.4%) as inclusion levels of brewer’s yeast in the diet increased (0%, 10%, 15%, 20%, and 30%, respectively). In the present study, for Pacific white shrimp, brewer’s yeast was a highly digestible feedstuff (91.8%) in terms of crude protein at an inclusion level of 30%. ^{Terrazas-Fierro et al. (2010)} reported ADC values for essential AAs in a red crab (P. planipes) meal that were much lower (82.1%) than the values found for crustacean meal in the present study (95%). In the present study, experimental diets were formulated with 30% of the test ingredient. The Commonwealth Scientific and Industrial Research Organisation (Australia) work group indicates that the higher the inclusion level of the feedstuff in the experimental diet, the higher the precision in the determination of feedstuff digestibility because differences with the reference diet become clearer and more accurate (^{Cruz-Suárez et al. 2008}). Correction for nutrient leaching tended to increase ADC values for brewer’s yeast, whereas the rest of the feedstuffs showed the opposite effect. ^{Tusche et al. (2011)} reported low growth rates for rainbow trout when feed contained 50% of potato protein concentrate. ^{Xie and Jokumsen (1997)} reported that growth rates for rainbow trout decreased as inclusion levels of potato protein concentrate increased, which could be associated with low AA digestibility, as shown in the present study for shrimp. The present study showed that the digestive efficiency of essential AAs in the experimental fish meal was high (97%), much higher than the values reported by ^{Yang et al. (2009)} (87%), ^{Terrazas-Fierro et al. (2010)} (89%), and ^{Carvalho et al. 2016} (84%). This differences could be associated with different factors, such as fish species, raw material (whole fish, by-products resulting from the filleting process, mixture of viscera from other species, etc.), or the elaboration process (drying by direct flame or by steam jacket). However, the previously mentioned studies do not specify on the raw material or elaboration process used.

English translation by Claudia Michel-Villalobos

References

[AOAC International ] Association of Official Analytical Chemists International. 1997. Official Methods of Analysis of AOAC International. 16th ed. Cunnift P, editor. Gaithersburg (MD): AOAC International; 1033 pp. [ Links ]

Bolin DW, King RP, Klosterman EW. 1952. A simplified method for the determination of chromic oxide Cr₂O₃ when used as an index substance. Science 116(3023): 634-635. https://doi.org/10.1126/science.116.3023.634 [ Links ]

Bureau DP, Hua K. 2006. Letter to the editor of Aquaculture. Aquaculture 252: 103-105. [ Links ]

Carvalho RAPLF, Haruo-Ota R, Olveira-Kadry V, Tacon AGJ, Lemos D. 2016. Apparent digestibility of protein, energy and amino acids of six protein sources included at three levels in diets for juvenile white shrimp Litopenaeus vannamei reared in high performance conditions. Aquaculture 465: 223-234. https://doi.org/10.1016/j.aquaculture.2016.09.010 [ Links ]

Cho CY, Slinger SJ. 1979. Apparent digestibility measurement in feedstuffs for rainbow trout. In: Halver JE, Tiews K (eds.), Finfish Nutrition and Fishfeed Technology. Vol. 2. Berlin (Germany): Heenemann Verlagsgesellschaft; p. 239-247. [ Links ]

Cruz-Suárez LE, Ricque-Marie D, Tapia-Salazar M. 2008. Integración y análisis global de las metodologías de digestibilidad in vivo. In: Cruz-Suárez LE, Villarreal-Colmenares H, Tapia-Salazar M, Nieto-López M, Villarreal-Cavazos DA, Ricque-Marie D (eds.), Manual de Metodologías de Digestibilidad in vivo e in vitro para Ingredientes y Dietas para Camarón. Monterrey (Nuevo León; Mexico): Universidad Autónoma de Nuevo León; p. 180-187. ISBN: 978-607-433-020-5. [ Links ]

Cruz-Suárez LE, Tapia-Salazar M, Villarreal-Cavazos D, Beltran-Rocha J, Nieto-López M, Lemme A, Ricque-Marie D. 2009. Apparent dry matter, energy, protein and amino acid digestibility of four soybean ingredients in white shrimp Litopenaeus vannamei juveniles. Aquaculture 292 (1-2): 87-94.https://doi.org/10.1016/j.aquaculture.2009.03.026 [ Links ]

Fontaine J. 2003. Amino acid analysis of feeds. In: D’Mello JPF (ed.), Amino acids in animal nutrition. 2nd ed. Wallingford (United Kingdom): CABI publishing; p. 22-31. [ Links ]

Goytortúa-Bores E, Civera-Cerecedo R, Rocha-Meza S, Green-Yee A. 2006. Partial replacement of red crab (Pleuroncodes planipes) meal for fish meal in practical diets for the white shrimp Litopenaeus vannamei. Effects on growth and in vivo digestibility. Aquaculture 256(1-4): 414-422. https://doi.org/10.1016/j.aquaculture.2006.02.035 [ Links ]

Hess V, Fickler J, Fontaine J, Heimbeck W. 2006. AminoDat 3.0- Amino acid composition of feedstuffs. Hanau (Germany): Evonik-Degussa GmbH, Health and Nutrition. [ Links ]

Llames C, Fontaine J. 1994. Determination of amino acids in feeds: Collaborative study. J. AOAC Int. 77(6): 1362-1402. [ Links ]

Nieto-López M, Tapia-Salazar M, Ricque-Marie D, Villarreal-Cavazos D, Lemme A, Cruz-Suárez LE. 2011. Digestibility of different wheat products in white shrimp Litopenaeus vannamei juveniles. Aquaculture 319(3-4): 369-376. https://doi.org/10.1016/j.aquaculture.2011.06.046 [ Links ]

[NRC] National Research Council [US]. 1983. Nutrient Requirements of Warmwater Fishes and Shellfishes. Washington DC: National Academy Press; 102 pp. [ Links ]

Novus. 1996. Novus Raw Material Compendium. Amino acid profiles database. Brussels (Belgium): [Novus International]. [ Links ]

Ozório ROA, Portz L, Borghesi R, Cyrino JEP. 2012. Effects of dietary yeast (Saccharomyces cerevisia) supplementation in practical diets of tilapia (Oreochromis niloticus). Animals 2 (1): 16-24. https://doi.org/10.3390/ani2010016 [ Links ]

Tapia-Salazar M, García-Pérez OD, Velásquez-Soto RA, Nieto-López MG, Villarreal-Cavazos D, Ricque-Marie D, Cruz-Suárez LE. 2012. Growth, feed intake, survival, and histological response of white shrimp Litopenaeus vannamei fed diets containing grains naturally contaminated with aflatoxin = Crecimiento, consumo de alimento, supervivencia y respuesta histológica del camarón blanco Litopenaeus vannamei alimentado con dietas de granos contaminados naturalmente con aflatoxinas. Cienc. Mar. 38 (3): 491-504. https://doi.org/10.7773/cm.v38i3.2094 [ Links ]

Tecator. 1983. Fat Extraction on Feeds with the Soxtec System HT-The Influence of Sample Preparation and Extraction Media. Application note AN 67/83 (1983.06.13). Sweden: Tecator. [ Links ]

Terrazas-Fierro M, Civera-Cerecedo RC, Ibarra-Martínez L, Goytortúa-Bores E, Herrera-Andrade M, Reyes-Becerra A. 2010. Apparent digestibility of dry matter, protein, and essencial amino acid in marine feedstuffs for juvenile whiteleg shrimp Litipenaeus vannamei. Aquaculture 308 (3-4): 166-173. https://doi.org/10.1016/j.aquaculture.2010.08.021 [ Links ]

Tibbets SM, Milley JE, Lall SP. 2006. Apparent protein and energy digestibility of common and alternative feed ingredients by Atlantic cod, Gadus morhua (Linnaeus, 1758). Aquaculture. 261(4): 1314-1327. https://doi.org/10.1016/j.aquaculture.2006.08.052 [ Links ]

Tusche K, Berends K, Wuertz S, Susenbeth A, Schulz C. 2011. Evaluation of feed attractants in potato protein concentrate based diets for rainbow trout (Oncorhynchus mykiss). Aquaculture 321 (1-2): 54-60. [ Links ]

Villarreal-Cavazos DA, Cruz-Suárez LE, Tapia-Salazar M, Nieto-López M, Gamboa-Delgado J, Lemme A, Ricque-Marie D. 2017. Effect of feces leaching on apparent digestibility coefficients of Pacific white shrimp (Litopenaeus vannamei) = Efecto de la lixiviación de heces sobre los coeficientes de digestibilidad aparente en camarón blanco del Pacífico (Litopenaeus vannamei). Hidrobiológica 27(3): 353-357. [ Links ]

Villarreal-Cavazos DA, Ricque-Marie D, Peña-Rodríguez A, Nieto-López M, Tapia-Salazar M, Lemme A, Gamboa-Delgado J, Cruz-Suárez LE. 2014. Apparent digestibility of dry matter, crude protein, and amino acids of six rendered by-products in juvenile Penaeus vannamei = Digestibilidad aparente de materia seca, proteína cruda y aminoácidos de seis subproductos de rastro en juveniles de Litopenaeus vannamei. Cienc. Mar. 40(3) 163-172. http://dx.doi.org/10.7773/cm.v40i3.2427 [ Links ]

Xie S, Jokumsen A. 1997. Replacement of fish meal by potato protein concentrate in diets for rainbow trout, Oncorhynchus mykiss (Walbaum): growth, feed utilization and body composition. Aquacult. Nut. 3(1): 65-69. https://doi.org/10.1046/j.1365-2095.1997.00074.x [ Links ]

Yang Q, Zhou X, Zhou Q, Tan B, Chi S, Dong X. 2009. Apparent digestibility of selected feed ingredients for white shrimp Litopenaeus vannamei, Boone. Aquacult. Res. 41(1): 78-86.https://doi.org/10.1111/j.1365-2109.2009.02307.x [ Links ]

Received: May 01, 2019; Accepted: June 01, 2019

^*Corresponding author. E-mail: david.villarrealcv@uanl.edu.mx, villarrealcd@hotmail.com

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