Food-grade tracers have been developed as an identification technology for grain traceability from original harvest to final destination for transportation. The characteristics of food-grade tracers must be able to satisfy the environmental demands for grain traceability. To optimize the food-grade tracer production process, the effects of direct compression formulation and load on the mechanical characteristics were studied using response surface methodology (RSM) with central composite design (CCD). Among the four tested formulations, Formulations #2 (consisting of 35.00% lactose 100 mesh, 64.50% microcrystalline cellulose 102 and 0.50% magnesium stearate) and #4 (consisting of 38.00% lactose 100 mesh, 50.00% microcrystalline cellulose 102, 11.00% pregelatinized starch and 1.00% magnesium stearate) were selected for tracer production based on their physical properties as powders. The value of Carr’s flowability index was 68 for both Formulations #2 and #4, which was the highest among all the formulations. Therefore, Formulations #2 and #4 also had the best powder flowability. The magnesium stearate ratio (1.00%-3.00%) and pressure (6.00-16.00 kgf) were used as independent variables to detect changes in the breaking rate, peak shear force and friction coefficient of tracers compressed by the selected formulations. The optimal production parameters could be achieved at a magnesium stearate ratio of 2.25% and pressure of 16.00 kgf for Formulation #2 and at a magnesium stearate ratio of 1.02% and pressure of 16.00 kgf for Formulation #4. Under these optimal conditions, the tracers had good impact characteristics (breaking rate), compression characteristics (peak shear force) and frictional characteristics (friction coefficient). Moreover, Formulation #2 was more suitable for production because compared to Formulation #4, its breaking rate and friction coefficient values were lower, and its peak shear force value was higher.
Keywords: grain traceability, food-grade tracer, optimization, food safety, formulation, mechanical property, central composite design
DOI: 10.25165/j.ijabe.20171006.3531

Citation: Liang K, Zhang L L, Lu W, Okinda C S, Shen M X. Optimization of compression formulation and load of food-grade tracers for grain traceability using central composite design. Int J Agric & Biol Eng, 2017; 10(6): 221–230.

grain traceability, food-grade tracer, optimization, food safety, formulation, mechanical property, central composite design

Zhu H, Jackson P, Wang W. Consumer anxieties about food grain safety in China. Food Control, 2017; 73: 1256–1264.

Aung M M, k Chang Y S. Traceability in a food supply chain: Safety and quality perspectives. Food Control, 2014; 39: 172-184.

Wang X, He Q, Matetic M, Jemric T, Zhang X. Development and evaluation on a wireless multi-gas-sensors system for improving traceability and transparency of table grape cold chain. Computers and Electronics in Agriculture, 2017; 135: 195–207.

Narsimhalu U, Potdar V, Kaur A. A case study to explore influence of traceability factors on Australian food supply chain performance. Procedia - Social and Behavioral Sciences, 2015; 189: 17–32.

Can-Trace. Can-Trace develops traceability standards for all food products sold in Canada. www.can-trace.org. 2003. Accessed on [2017-05-21].

EU. (EC) No. 178/2002 of the european parliament and of the council of 28 January 2002. Official Journal of the European Communities, 2002; L31: 1-24.

Ceruti F C, Lazzari S, Lazzari F A. Traceability in the wheat production chain. 9th International Working Conference on Stored Product Protection, 2006; pp.1198-1205.

Lee K M, Armstrong P R, Thomasson J A, Sui R X, Casada M, Herrman T J. Application of binomial and multinomial probability statistics to the sampling design process of a global grain tracing and recall system. Food Control, 2011; 22(7): 1085–1094.

Herrman T J. White paper on traceability in the U. S. grain and plant protein feed ingredient industries.

Comba L, Belforte G, Dabbene F, Gay P. Methods for traceability in food production processes involving bulk products. Biosystems Engineering, 2013; 116(1): 51–63.

Thakur M, Hurburgh C R. Framework for implementing traceability system in the bulk grain supply chain. Journal of Food Engineering, 2009; 95(4): 617–626.

Kvarnström B, Bergquist B, Vännman K. RFID to improve traceability in continuous granular flows—An experimental case study. Quality Engineering, 2011; 23(4): 343–357.

Hirai Y, Schrock M D, Oard D L, Herrman T J. Delivery system of tracing caplets for wheat grain traceability. Applied Engineering in Agriculture, 2006; 22(5): 747–750.

Sui R X, Thomasson J A, Herrman T. Development of tracers for grain tracing system. Asabe Annual International Meeting, 2007.

Lee K M, Armstrong P R, Thomasson J A, Sui R X, Casada M, Herrman T J. Development and characterization of food-grade tracers for the global grain tracing and recall system. Journal of Agricultural and Food Chemistry, 2010; 58(20): 10945–10957.

Liang K, Thomasson J A, Lee K M, Shen M X, Ge Y, Herrman T J. Printing data matrix code on food-grade tracers for grain traceability. Biosystems Engineering, 2012; 113(4): 395–401.

Liang K, Thomasson J A, Shen M X, Armstrong P R, Ge Y, Lee K M, et al. Ruggedness of 2D code printed on grain tracers for implementing a prospective grain traceability system to the bulk grain delivery system. Food Control, 2013; 33(2): 359–365.

Kamst G F, Bonazzi C, Vasseur J, Bimbenet J J. Effect of deformation rate and moisture content on the mechanical properties of rice grains. Transactions of the ASAE, 2002; 45(1): 145–151.

Güzel E, Akçalı İ D, İnce A. Behavior of peanut bulk under static loads. Journal of Food Engineering, 2007; 80(2): 385–390.

Subramanian S, Viswanathan R. Bulk density and friction coefficients of selected minor millet grains and flours. Journal of Food Engineering, 2007; 81(1): 118–126.

Sanghvi P P, Collins C C, Shukla A J. Evaluation of Preflo modified starches as new direct compression excipients. I. Tabletting characteristics. Pharmaceutical Research, 1993; 10(11): 1597–1603.

Zhang Y L, Law Y, Chakrabarti S. Physical properties and compact analysis of commonly used direct compression binders. AAPS PharmSciTech, 2003; 4(4): 489-499.

Sacchetti M, Teerakapibal R, Kim K, Elder Jr E J. Role of water sorption in tablet crushing strength, disintegration, and dissolution. AAPS Pharmscitech, 2017; 1–13.

ASAE Standard. Compression test of food materials of Convex Shape. ASAE S368.4 DEC2000, 2008.

Shafaei S M, Nourmohamadi-Moghadami A, Kamgar S. Analytical study of friction coefficients of pomegranate seed as essential parameters in design of post-harvest equipment. Information Processing in Agriculture, 2016; 3(3): 133–145.

Yang Z M, Guo Y M, Cui Q L, Li H B. Test and influence factors analysis of friction characteristics of millet. Transactions of the CSAE, 2016; 32(16): 258–264. (in Chinese)

Matsumoto R, Kawakami K, Aoki S. Impact of compression pressure on tablet appearance. International Journal of Pharmaceutics, 2007; 341(1-2): 44-49.

Faqih A M N, Mehrotra A, Hammond S V, Muzzio F J. Effect of moisture and magnesium stearate concentration on flow properties of cohesive granular materials. International Journal of Pharmaceutics, 2007; 336(2): 338-345.

Iranloye T, Parrott E. Effects of compression force, particle size, and lubricants on dissolution rate. J Pharm Sci., 1978; 67(4): 535-539.

Ganesan V, Rosentrater K A, Muthukumarappan K. Physical and flow properties of regular and reduced fat distillers dried grains with solubles (DDGS). Food and Bioprocess Technology, 2009; 2(2): 156–166.

Carr R. Evaluating flow properties of solids. Chem. Eng., 1965; 72(2): 163–168.

Otsuka T, Iwao Y, Miyagishima A, Itai S. Application of principal component analysis enables to effectively find important physical variables for optimization of fluid bed granulat or conditions. International Journal of Pharmaceutics, 2011; 409(1-2): 81-88.

Sakurai Y, Mise R, Kimura S, Noguchi S, Iwao Y, Itai S. Novel method for improving the water dispersibility and flowability of fine green tea powder using a fluidized bed granulator. Journal of Food Engineering, 2017; 206: 118–124.

Nakamura S, Yamaguchi S, Hiraide R, Iga K, Sakamoto T, Yuasa H. Setting ideal lubricant mixing time for manufacturing tablets by evaluating powder flowability. AAPS Pharmscitech, 2017; pp.1–9.