Cereal bran protects vitamin A from degradation during simmering and storage

Abstract Feed ingredients and additives could be a potential medium for foreign animal disease entry into the United States. The feed industry has taken active steps to reduce the risk of pathogen entry through ingredients. Medium chain fatty acid (MCFA) and heat pulse treatment could be an opportunity to prevent pathogen contamination. The objective of experiment 1 was to determine the impact of 0, 30, 60, or 90 d storage time on fat-soluble vitamin stability when vitamin premix (VP) and vitamin trace mineral premix (VTM) were blended with 1% inclusion of MCFA (1:1:1 blend of C6:C8:C10) or mineral oil (MO) with different environmental conditions. Samples stored at room temperature (RT) (~22 °C) or in an environmentally controlled chamber set at 40 °C and 75% humidity, high-temperature high humidity (HTHH). The sample bags were pulled out at days 0, 30, 60 and 90 for RT condition and HTHH condition. The objective of experiment 2 was to determine the effect of heat pulse treatment and MCFA addition on fat-soluble vitamin stability with two premix types. A sample from each treatment was heated at 60 °C and 20% humidity. For experiment 1, the following effects were significant for vitamin A: premix type × storage condition (P = 0.031) and storage time × storage condition (P = 0.002) interactions; for vitamin D3: main effect of storage condition (P < 0.001) and storage time (P = 0.002); and for vitamin E: storage time × storage condition interaction (P < 0.001). For experiment 2, oil type did not affect the stability of fat-soluble vitamins (P > 0.732) except for vitamin A (P = 0.030). There were no differences for fat-soluble vitamin stability between VP and VTM (P > 0.074) except for vitamin E (P = 0.016). Therefore, the fat-soluble vitamins were stable when mixed with both vitamin and VTM and stored at 22 °C with 28.4% relative humidity (RH). When premixes were stored at 39.5 °C with 78.8%RH, the vitamin A and D3 were stable up to 30 d while the vitamin E was stable up to 60 d. In addition, MCFA did not influence fat-soluble vitamin degradation during storage up to 90 d and in the heat pulse process. The vitamin stability was decreased by 5% to 10% after the premixes was heated at 60 °C for approximately nine and a half hours. If both chemical treatment (MCFA) and heat pulse treatment have similar efficiency at neutralizing or reducing the target pathogen, the process of chemical treatment could become a more practical practice.

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DDT Effect on Rats Raised on Alpha-protein Rations: Growth and storage of liver vitamin A

Journal of Nutrition ◽

10.1093/jn/98.3.319 ◽

1969 ◽

Vol 98 (3) ◽

pp. 319-324 ◽

Cited By ~ 8

Author(s):

Ian J. Tinsley

Keyword(s):

Vitamin A ◽

And Storage ◽

Liver Vitamin

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Vitamin A Baking and Storage Stability in Nigerian Retailed Bread

European Journal of Nutrition & Food Safety ◽

10.9734/ejnfs/2015/20840 ◽

2015 ◽

Vol 5 (5) ◽

pp. 336-337

Author(s):

Florence Uchendu ◽

Tola Atinmo

Keyword(s):

Vitamin A ◽

Storage Stability ◽

And Storage

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Multiple Fortification of Beverages

Food and Nutrition Bulletin ◽

10.1177/156482659801900213 ◽

1998 ◽

Vol 19 (2) ◽

pp. 168-171 ◽

Cited By ~ 5

Author(s):

Denis Barclay

Keyword(s):

Vitamin A ◽

Raw Materials ◽

Cost Effective ◽

Target Population ◽

Micronutrient Deficiencies ◽

Organoleptic Characteristics ◽

Multiple Micronutrient ◽

Materials Used ◽

Processing And Storage ◽

And Storage

Diet-related micronutrient deficiencies rarely occur in isolation; deficiencies of iodine and vitamin A or of iron and vitamin A or zinc are often observed in the same populations. In addition, widespread deficiencies of some micronutrients, for example, zinc and calcium, may often go undiagnosed because of the absence of specific and sensitive status indicators. Multiple micronutrient supplementation can be more effective in improving nutritional status than supplementation with single key micronutrients; therefore, the multiple fortification of appropriate food vectors, including beverages, is of interest from the nutritional standpoint. Beverages fortified with multiple micronutrients include dairy products, chocolate beverages, fruit juices, and soya-based drinks. As well as the documented or estimated micronutrient deficiencies and the requirements of the target population or consumer group, the conception of such a multiply fortified beverage must take into account a number of other important factors. The choice of the chemical form of the fortification micronutrients should be made with consideration of bioavailability, the effects on the organoleptic characteristics of the particular beverage, and cost. The initial calculation of the composition of the micronutrient premix should include the levels of micronutrients in the raw materials used and the estimated losses of specific micronutrients during processing and storage. Preliminary production and storage trials are then needed to determine the actual losses. The composition of the micronutrient premix may then be finalized. Interactions, both positive and negative, between fortification micronutrients may also need to be considered. For example, the bioavailability of iron may be enhanced by the addition of vitamin C, whereas mineral–vitamin and vitamin–vitamin interactions can accelerate the destruction of some vitamins. To render quality control procedures simple and cost-effective, only a limited number of fortification micronutrients, which are especially sensitive to losses and which are easy to measure, may be analysed. Simple, inexpensive, and rigorous analytical methods for such measurements are now available.

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The Effects of Soya Lecithin on the Absorption, Utilization and Storage of Vitamin a and Carotene in the white Rat

Journal of Nutrition ◽

10.1093/jn/36.3.391 ◽

1948 ◽

Vol 36 (3) ◽

pp. 391-404 ◽

Cited By ~ 11

Author(s):

G. C. Esh ◽

T. S. Sutton

Keyword(s):

Vitamin A ◽

Soya Lecithin ◽

And Storage

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Retail Sugar From One Zambian Community Does Not Meet Statutory Requirements for Vitamin A Fortification

Food and Nutrition Bulletin ◽

10.1177/0379572117733841 ◽

2017 ◽

Vol 38 (4) ◽

pp. 594-598 ◽

Cited By ~ 3

Author(s):

Matthew D. Greene ◽

Gladys Kabaghe ◽

Mofu Musonda ◽

Amanda C. Palmer

Keyword(s):

Vitamin A ◽

Marked Improvement ◽

Storage Conditions ◽

Food Fortification ◽

Structured Interviews ◽

Fortified Foods ◽

Vitamin A Status ◽

Statutory Requirement ◽

Monitoring And Enforcement ◽

And Storage

Background: Industrial food fortification is a major strategy to improve dietary micronutrient intakes and prevent deficiencies. Zambia introduced mandatory sugar fortification with vitamin A, at a target of 10 mg/kg, in 1998. Representative surveys conducted since that time do not support marked improvement in vitamin A status. Objective: To describe vitamin A concentrations in retail sugar, as well as vendor practices, perceptions of fortified foods, and sugar use practices. Methods: We conducted a census of sugar vendors in one Zambian community, capturing information on vendors, available brands and packaging options, and storage conditions. We purchased all brands and package types of sugar available at each vendor. In a 15% subsample, we conducted semi-structured interviews with vendor–consumer pairs. We tested 50% of sugar samples at random for vitamin A using an iCheck portable fluorimeter. Results: The distribution of vitamin A in sugar in market samples was highly skewed, with a median of 3.1 mg/kg (25th-75th percentiles: 1.8-5.5) and a range from 0.2 to 29.9 mg/kg. Only 11.3% of samples met the 10 mg/kg statutory requirement. Sugar was primarily repackaged and sold in small quantities, with rapid turnover of stocks. Perceptions of fortification by vendors and consumers were generally positive. Conclusions: Vitamin A in fortified sugar fell well below statutory requirements. Our data point to challenges at regional depot and/or poor adherence to fortification standards at the factory level. A renewed commitment to monitoring and enforcement will be required for Zambia to benefit from a food fortification strategy.

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