Particle Size Reduction Leading to Cell Wall Rupture Is More

Dec 1, 2010 - The amount of nutrients that can be released from food products (i.e., nutrient in vitro bioaccessibility) is often studied as it is a s...
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J. Agric. Food Chem. 2010, 58, 12769–12776

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DOI:10.1021/jf102554h

Particle Size Reduction Leading to Cell Wall Rupture Is More Important for the β-Carotene Bioaccessibility of Raw Compared to Thermally Processed Carrots LIEN LEMMENS, SANDY VAN BUGGENHOUT, ANN M. VAN LOEY, AND MARC E. HENDRICKX* Laboratory of Food Technology and Leuven Food Science and Nutrition Research Centre (LFoRCe), Department of Microbial and Molecular Systems (M2S), Katholieke Universiteit Leuven, Kasteelpark Arenberg 22, 3001 Leuven, Belgium

The amount of nutrients that can be released from food products (i.e., nutrient in vitro bioaccessibility) is often studied as it is a starting point for investigating nutrient bioavailability, an indicator for the nutritional value of food products. However, the importance of mastication as a particle size reduction technique is poorly understood and is often neglected during in vitro procedures determining bioaccessibility. Therefore, the aim of the present work was to study the effect of mechanical breakdown on the β-carotene bioaccessibility of carrot samples, having different textural/structural characteristics (as a result of thermal processing). In the first part of this study, the all-E-β-carotene bioaccessibility of carrot particles of different sizes (ranging from cell fragments up to large cell clusters), generated from raw as well as from gently and intensely cooked carrot samples, was determined. In the second part of the study, the effect of human mastication on the particle size reduction of raw as well as of gently and intensely cooked carrot samples was investigated in order to allow identification and validation of a technique that could mimic mastication during in vitro procedures. Results showed a strong dependency of the all-E-β-carotene bioaccessibility on the particle size for raw and gently cooked carrots. After intense cooking, on the other hand, a considerable amount of all-E-β-carotene could be released from cell fragments (smaller than a cell) as well as from small and large cell clusters. Hence, the importance of mechanical breakdown, and thus also of (in vitro) mastication, is dependent on the carrot sample that is considered (i.e., the extent to which the carrot sample has been thermally processed prior to the particle size reduction). Structural changes occurring during mechanical and thermal processing are hereby key factors determining the all-E-β-carotene bioaccessibility. The average particle size distribution curves of raw and cooked carrots, which were chewed by 15 persons, could be mimicked by mixing 50 g of carrots using a Grindomix (Retsch) at 2500 rpm during 5 s. Based on this scientific knowledge, the identified in vitro mastication technique was successfully integrated in the in vitro digestion procedure determining the all-E-β-carotene bioaccessibility of carrot samples. KEYWORDS: all-E-β-Carotene bioaccessibility; in vitro digestion models; mastication; particle size; thermal processing

*Corresponding author. Tel: þ32 16 32 15 85. Fax: þ32 16 32 19 60. E-mail: [email protected].

nutrient that is available for utilization and for storage in the human body (2). Nutrient bioavailability incorporates availability for absorption, absorption, metabolism, tissue distribution and bioactivity of the nutrient (1, 3, 4). In order to be available for absorption, the ingested nutrients need to be released from the food matrix (5). This is referred to as the nutrient bioaccessibility (2). It is typically determined by in vitro methods simulating the human digestion process. Studying nutrient bioaccessibility is a good starting point for estimating or predicting nutrient bioavailability (6). However, it should be stressed that additional in vivo studies are necessary to validate the results obtained by in vitro analyses (1). To assess nutrient bioaccessibility, physiological conditions occurring during oral, gastric and intestinal

© 2010 American Chemical Society

Published on Web 12/01/2010

INTRODUCTION

Fruit and vegetable based food products are often characterized in terms of nutritional content. However, it was emphasized by Ferna´ndez-Garcı´ a et al. (1) that it is (even more) relevant to investigate to what extent the bioactive nutrients present in the food products can be digested and effectively assimilated by the human body in order to eventually reach the target tissues where they can carry out their function. In this context, concepts as nutrient bioavailability and bioaccessibility are important. Nutrient bioavailability is defined as the fraction of an ingested

pubs.acs.org/JAFC

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J. Agric. Food Chem., Vol. 58, No. 24, 2010

digestion are simulated by adjusting operational characteristics like temperature, pH, addition of enzymes, and so on (7). Nevertheless, only limited attention is given to the simulation of the mechanical breakdown of the food products during mastication (oral digestion). This is mainly important for solid food systems. If the imitation of the mechanical breakdown is specified (for most of the studies on bioaccessibility, this is not the case), it is very case-specific and, to the best of our knowledge, no scientific foundation for the method of choice can be found in currently existing literature. For example, techniques as “finely chopping” (8), “homogenizing with a kitchen blender for 1 minute” (9, 10), “homogenizing with a kitchen blender for 15-second intervals” (11) and “mixing 2 times 5 seconds at 7500 rpm” (12 ) were reported to simulate mastication. Concerning carotenoid bioaccessibility in (processed) vegetable tissue, only few studies paid attention specifically to the mechanical breakdown during the oral phase in in vitro digestion protocols (e.g., Epriliati et al. (13)). It is clear that if mastication would have an effect on nutrient bioaccessibility, no unambiguous comparison between different studies can be made. These examples suggest that there are still some shortcomings for in vitro digestion protocols to determine nutrient bioaccessibility and that there is space for improvement, optimization and standardization facilitating the comparison of results of different studies and the improvement of the predictions for in vivo studies. Generally, nutrient bioavailability is influenced by exogenous and endogenous factors (3), and the term “SLAMENGHI” combines the first letters of all these factors (14). The endogenous factors consist mainly of host related factors, while the exogenous factors are predominantly related to the food product, linking these factors also to nutrient bioaccessibility. In this case study on carrots, the major focus point was the effect of “the matrix in which the carotenoids are incorporated” (“M” in “SLAMENGHI”) on the β-carotene bioaccessibility. Previous research (15) has shown that homogenization of raw and cooked carrot pieces can increase the β-carotene bioaccessibility. In line with the latter study, the present work aims for a more detailed insight into the relation between the carrot tissue particle size and the all-E-β-carotene bioaccessibility. Carrot pieces were mechanically processed and sieved in order to obtain 12 carrot particle fractions of different sizes. The all-E-β-carotene bioaccessibility of the different fractions was determined in order to have a clear view on the relation between the particle size and the β-carotene bioaccessibility. The influence of the textural/structural quality of the carrot material prior to mechanical processing was included. Hereto, carrot pieces were boiled in water during different time intervals. The resulting carrot samples, clearly differing in textural and thus structural quality, were treated and analyzed in the way as mentioned above (for raw samples). In the second part of the present work, it was the purpose to get a detailed insight into the particle size reduction effect of mastication. A small-scale human study was set up to determine the average particle size distribution of chewed carrot samples. Again this was performed for carrot samples differing in textural/structural quality in order to find out the effect of textural/structural quality on the chewing behavior. In a final part of the present work, a technique to in vitro mimic the particle size reduction during human mastication of carrot samples (with different textural/structural characteristics) was identified and validated. Based on this scientific knowledge, the identified in vitro mastication technique was successfully integrated in the in vitro digestion procedure determining the all-E-βcarotene bioaccessibility of carrot samples. MATERIALS AND METHODS Carrot Samples. Throughout the study, a single batch of carrots (Daucus carota cv. Nerac) was used (stored at 4 °C). Carrots were peeled,

Lemmens et al. 3

cut into pieces (around 1 cm ) and used as such (raw carrots), cooked in boiling water for 3 min (gently cooked carrots) or cooked in boiling water for 25 min (intensely cooked carrots). These three carrot samples were characterized in terms of hardness as an indication for the textural/structural quality. As explained in detail by Sila et al. (16), a compression test, using a TA-XT2i Texture Analyzer (Stable Micro Systems, Surrey, U.K.), was performed to examine the hardness of the carrots (calibrated carrot pieces, 10 mm height and 12 mm diameter). The residual hardness of the raw, gently and intensely cooked carrots was respectively 100%, 60% and 3%. Part 1. Generation of Carrot Particle Fractions of Different Sizes. Raw, gently cooked and intensely cooked carrot pieces were mechanically processed, i.e. mixed or blended (Grindomix GM 200, Retsch, Haan, Germany), and by using the technique of wet sieving (Retsch, Aartselaar, Belgium), fractions of 12 different particle size ranges were obtained (