Protein Digestibility-Corrected Amino Score (PDCAAS) is discussed. PDCAAS is now widely used as a routine assay for protein quality evaluation, replacing the more traditional biological methods [e.g., measurement of the Protein Efficiency Ratio (PER) in rats]. PDCAAS is based on comparison of the essential amino acid content of a test protein with that of a reference essential amino acid pattern and a correction for differences in protein digestibility as determined using a rat assay. Although PDCAAS is a rapid and useful method, it often shows discrepancies when compared to PER values. These discrepancies relate to the following issues: uncertainty about the validity of reference patterns, invalidity of correction for fecal (versus ileal) digestibility, truncation of PDCAAS values to 100%, failure to obtain full biological response after supplementation of the limiting essential amino acid, discrepancies between protein and amino acid digestibility, effects of processing on protein quality, and effects of the presence of antinutritional factors in the matrix containing the protein. Part of the discrepancy between PDCAAS and PER can be overcome by modifications of PDCAAS. This article describes some proposed modifications and puts forward the suggestion that the rat protein fecal digestibility assay be replaced by an in vitro ileal amino acid digestibility assay based on a computer-controlled gastrointestinal model.

The first objective in evaluating protein quality is to permit a ranking of proteins according to their potential nutritive value and to permit detection of changes in nutritive value due to processing and/or storage. The second objective is to permit prediction of the contribution a food protein, or mixture of food proteins, makes toward meeting nitrogen and amino acid requirements for growth or maintenance. Different approaches are used in meeting these distinct aims. The preferred current method to meet the second aim is the protein digestibility corrected amino acid score (PDCAAS). This article introduces the concept of PDCAAS and places it in the context of the series of papers published in this Special Guest Editor Section addressing aspects of dietary amino acid utilization.

This study was conducted to evaluate protein quality, acceptability and storage stability of processed cereal-bean-sardine composite foods for pre-school age children in Tanzania. Four composite products namely corn-bean-sardine meal (CBSM), bean meal (BM), sorghum-bean-sardine meal (SBSM) and rice-bean-sardine meal (RBSM) were formulated to maximize the amino acid score for pre-school age children and were processed by extrusion, drum-processing and conventional cooking. The products were evaluated for true protein digestibility (TPD) and protein digestibility-corrected amino acid score (PDCAAS). The TPD and PDCAAS were highest in the extruded products. The TPD values for the products ranged from 82 to 93%. The PDCAAS values for the composite foods were 64-86% and were greater than the minimum value of 60% recommended by FAO/WHO/UNU. There were no significant (p > 0.05) variations in the amino acid contents for foods processed by extrusion, drum-processing or conventional cooking. Threonine was most limiting in the CBSM, SBSM and RBSM while methionine + cysteine were most limiting in the BM. Sensory evaluation showed that, relative to the traditional cornmeal-Uji, the extruded CBSM and SBSM had significantly superior (p less than or equal to 0.05) texture and highly acceptable color and taste. Storage of the products up to 16 weeks at 38 degrees C resulted in a small but significant increase (p less than or equal to 0.05) in the malondialdehyde concentrations; nevertheless, the levels remained within the acceptable range found in processed commercial supplements. Total acids, pH and organoleptic attributes did not change significantly (p > 0.05) during storage and the foods were acceptable to the end of the storage period.

Com o crescimento populacional, a indústria avícola tem se desenvolvido rapidamente, devido à demanda de alimentos. O seu produto possui grande aceitação no mercado mundial, em função do seu valor nutricional e por não existirem restrições culturais. Entretanto, este alimento gera grande quantidade de resíduos, dentre eles, as penas. Elas são compostas principalmente por queratina, substância de difícil degradação. Neste trabalho foram utilizadas duas bactérias queratinolíticas de resíduos da indústria avícola, para se avaliar a capacidade de degradação das mesmas. Foram produzidos hidrolisados de penas por proteólise bacteriana com ambos microrganismos: Bacillus cereus (KR16) e Chryseobacterium sp. (KR6). O crescimento das bactérias em diferentes quantidades de penas, e o fator de degradação das penas comprovaram que em até 5 % obteve-se degradação para KR6, enquanto, para a KR16, obteve-se degradação até 1%. A digestibilidade in vitro dos hidrolisados foi avaliada. Observou-se que o hidrolisado da bactéria KR6 apresentou maior digestibilidade, enquanto o de farinha de penas apresentou o menor valor. A composição de aminoácidos dos hidrolisados foi determinada, sendo observadas baixas concentrações de metionina, histidina e lisina. A partir da digestibilidade in vitro e da composição de aminoácidos, foram calculados o escore de aminoácidos corrigidos (PDCAAs), o coeficiente de eficiência protéica (PER) e o valor biológico (BV). O tratamento das penas com KR6 resultou em hidrolisados com os valores mais altos de PDCAAs, PER e BV, sugerindo que este microrganismo produz hidrolisados com propriedades nutricionais superiores aos demais.

O objetivo principal deste trabalho foi o isolamento e a caracterização química e nutricional (in vitro) das duas principais frações protéicas do soro de sangue bovino. Imediatamente, após coleta higiênica do sangue em matadouro, promoveu-se a coagulação e a remoção da fração celular por centrifugação, em condições apropriadas. A fração globulina (GB) foi precipitada do soro pela saturação a 50% com (NH4)2 SO4 . Após separação da GB por centrifugação a saturação do sobrenadante foi elevada a 80%, para a precipitação da albumina (BSA). A precipitação de proteínas séricas das duas frações somou 98% das proteínas totais do soro. As duas frações protéicas foram caracterizadas quanto à composição centesimal, perfil de aminoácidos, composição mineral, escore de aminoácidos essenciais (EAE), digestibilidade da proteína e PDCAAS ("Protein digestibility corrected amino acid scoring"). O teor de proteína nas duas frações foi de aproximadamente 85% e a BSA se caracterizou pelo elevado teor de lisina, histidina e aminoácidos sulfurados. O EAE para BSA foi 70% sendo triptofano o aminoácido mais limitante e 87,8% para a GB, sendo a isoleucina o aminoácido mais limitante. O uso das técnicas de eletroforese e densitometria permitiu a caracterização das frações quanto ao número de bandas pesos moleculares e proporção relativa entre as várias proteínas. | The main objective of this work, was the isolation, chemical and nutritional (in vitro) characterization of the two main protein fractions of bovine blood serum. Immediatly after hygienic collection at the slaughter house the blood was coagulated and the cellular fraction separated by centrifugation under appropriate conditions. The globulin (GB) fraction was precipitated from blood serum by 50% saturation with ammonium sulfate. The supernalant was separated by centrifugation and the (NH4)2SO4 saturation elevated to 80%. Under this condition BSA precipitated. Precipitation (recovery) of proteins amounted to 98% of total serum protein, in the two fractions. Both GB and BSA were characterized as to proximate percent composition, mineral, amino acid profiles, essential amino acid score (EAE), protein digestibility, and protein digestibility corrected amino acid scoring (PDCAAS). Protein concentration in both fractions was around 85%. BSA presented high concentrations of lysine, histidine and sulfur amino acids, particulary cistine. The EAE for BSA was 70%, tryptophan being the most limiting amino acid, and for GB the EAE score was 87.8% with isoleucine as the most limiting amino acid. PAGE-SDS and densitometry permitted the fractions characterization as the number of protein bands molecular weight and relative proportions among the various proteins.

During processing and storage, phenolic compounds (PCs) may react with food protein bound amino acids (AAs). Such reactions have been reported to change physicochemical and to decrease in vitro digestion properties of proteins. A rat growth and nitrogen (N) balance study was conducted to prove whether derivatization with chlorogenic acid (CA) affects the nutritional quality of beta-lactoglobulin (beta-LG). Test diets (10% protein level) contained nonderivatized beta-LG (LG, treated under omission of CA), low derivatization level beta-LG (LGL), high derivatization level beta-LG (LGH), or casein supplemented with L-methionine (0.3% of diet; C+met) as an internal standard. An additional group received untreated beta-LG supplemented with pure CA (1.03% of diet; LG+CA). The AA composition of test proteins, plasma AAs, and liver glutathione (GSH) concentrations were determined. Protein digestibility-corrected amino acid score (PDCAAS) was calculated using human or rat AA requirement patterns and rat fecal digestibility values. N excretion was significantly higher in feces and lower in urine of rats fed with LGH as compared to LG and LGL. Consequently, true N digestibility (TND) was significantly lower with LGH as compared to LG and LGL. The lower content of methionine, cysteine, lysine, and tryptophan in LGH corresponded to a reduced TND. Net protein utilization (NPU) was not different between treated beta-LG fed diet groups but was lower than in LG+CA and C+met fed groups. Only at a relatively high level of derivatization with CA, the otherwise good nutritional quality of beta-LG is affected so that TND is reduced, while NPU still remains unaffected. Derivatization of beta-LG with CA does not seem to lead to an additional deficiency in a specific indispensable AA in growing rats fed with 10% protein

Digestibility of protein in traditional diets from developing countries such as India, Guatemala, and Brazil is considerably lower compared to that of protein in typical North American diets (54-78 versus 88-94%). The presence of less digestible protein fractions, high levels of insoluble fiber, and high concentrations of antinutritional factors in the diets of developing countries, which are based on less refined cereals and grain legumes as major sources of protein, are responsible for poor digestibility of protein. The effects of the presence of some of the important antinutritional factors on protein and amino digestibilities of food and feed products are reviewed in this chapter. Food and feed products may contain a number of antinutritional factors that may adversely affect protein digestibility and amino acid availability. Antinutritional factors may occur naturally, such as glucosinolates in mustard and rapeseed protein products, trypsin inhibitors and hemagglutinins in legumes, tannins in legumes and cereals, phytates in cereals and oilseeds, and gossypol in cottonseed protein products. Antinutritional factors may also be formed during heat/alkaline processing of protein products, yielding Maillard compounds, oxidized forms of sulfur amino acids, D-amino acids, and lysinoalanine (LAL, an unnatural amino acid derivative). The presence of high levels of dietary trypsin inhibitors from soybeans, kidney beans, or other grain legumes can cause substantial reductions in protein and amino acid digestibilities (up to 50%) in rats and pigs. Similarly, the presence of high levels of tannins in cereals, such as sorghum, and grain legumes, such as fababean (Vicia faba L.), can result in significantly reduced protein and amino acid digestibilities (up to 23%) in rats, poultry, and pigs. Studies involving phytase supplementation of production rations for swine or poultry have provided indirect evidence that normally encountered levels of phytates in cereals and legumes can reduce protein and amino acid digestibilities by up to 10%. D-amino acids and LAL formed during alkaline/heat treatment of proteins such as casein, lactalbumin, soy protein isolate, or wheat proteins are poorly digestible (less than 40%), and their presence can reduce protein digestibility by up to 28% in rats and pigs. A comparison of the protein digestibility determination in young (5-week) versus old (20-month) rats suggests greater susceptibility to the adverse effects of antinutritional factors in old rats than in young rats. Therefore, the inclusion of protein digestibility data obtained with young rats, as the recommended animal model, in the calculation of PDCAAS (Protein Digestibility-Corrected Amino Acid Score) may overestimate protein digestibility and quality of products, especially those containing antinutritional factors, for the elderly. For products specifically intended for the elderly, protein digestibility should be determined using more mature rats.