Effect of Biscuit Baking Conditions on the Stability of Microencapsulated 5-Methyltetrahydrofolic Acid and Their Physical Properties

Abstract

Among the folate compounds, 5-methyltetrahydrofolic acid (5-CH3THF) is regarded as one of the most bioactive forms of folate. It is regarded as the better source of folate to humans as compared to folic acid, a synthetic form of folate, which is used for fortifying foods to prevent the incidence of neural tube defects in the new born babies. The use of 5-CH3THF as an alternative fortificant, in place of folic acid, has been explored by various researchers. However, fortification of 5-CH3THF is problematic due to its lower stability. This study investigated the stability of microencapsulated 5-CH3THF in biscuits baked at various temperatures and times as well as changes in their physical properties. Microcapsule with pectin and alginate ratio of 80:20, prepared by spray drying, gave the highest retention (68.6%) of the 5-CH3THF, therefore, chosen for fortification. The encapsulated and unencapsulated 5-CH3THF were mixed separately with flour and biscuit ingredients and baked at 180℃, 200 and 220℃, each for 5, 9 and 12 min. The inclusion of encapsulated and unencapsulated 5-CH3THF in the biscuit formulation and subsequent baking at various temperatures and times resulted in retention of 5-CH3THF from 19.1% to 1.7%. Microencapsulation of 5-CH3THF slightly improved the retention of 5-CH3THF over unencapsuated biscuits at 180℃ for 5 min, but almost no such effect was achieved under baking temperatures of 200℃ and 220℃. Physical analysis showed darker colour, harder texture and lower moisture content for biscuits baked at higher test temperatures. It seems intense heating condition that caused “over baking” of the biscuit likely to be responsible for the loss of the vitamin as well as less desirable physical properties of the biscuits.

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A. Shrestha, J. Arcot, S. Dhital and S. Crennan, "Effect of Biscuit Baking Conditions on the Stability of Microencapsulated 5-Methyltetrahydrofolic Acid and Their Physical Properties," Food and Nutrition Sciences, Vol. 3 No. 10, 2012, pp. 1445-1452. doi: 10.4236/fns.2012.310188.

1. Introduction

Folate is one of the most talked about vitamins in recent times due to its potential role in preventing various diseases and disorders such as neural tube defects or NTDs in new born babies, megaloblastic anemia, atherosclerosis, stroke, cancer, Alzheimer’s disease, cleft palate, migraine etc. [1,2]. This led to widespread folate fortification of foods, particularly in cereal based foods. Folic acid or pteroylglutamic acid (PGA) is the most common form of folate added in foods. It is now mandatory to fortify cereal-based foods in 57 countries. In spite of that, addition of folic acid, a chemically synthesized folate vitamer as a fortificant in foods, is considered less effective or harmful to human health as it is potentially linked to increased rate of colorectal and prostate cancer, multiple births etc. [2]. Such controversies have resulted in several countries holding back the mandatory fortification programs.

In Australia, the National Health and Medical Research Council (NHMRC) in the year 1993 recommended a periconceptional daily supplement intake of 0.5 mg folic acid for low risk women and 5 mg for women with a family history of NTDs. This eventually resulted in the voluntary fortification of folic acid in cereal based foods in 1995. In Australia, the overall birth prevalence of NTDs from 1998 to 2005 is reported to be 944 or 4.6 per 10,000 births, remaining more or less unchanged over next 7 years [3]. Prior to 1995 intervention, the total prevalence of NTDs in Australia was reported to be approximately 20 per 10,000 births. Data from studies (1992-2005) has shown a 26% decline in NTDs [3,4].

The fact that folic acid might mask the hematological symptoms of vitamin B12 deficiency diseases, while the neurological complications remain in progress, particularly in older populations, is a major concern [5]. The use of 5-methyltetrahydrofolic acid (5-CH3THF) which cannot possibly mask the Vitamin B12 deficiency is now considered as an alternative to folic acid [6]. Besides 5- CH3THF is more natural form of folate and have similar bioavailability as folic acid [7]. Historically, 5-CH3THF has not been considered as a good folate fortificant as it is expensive to synthesize and is less stable as compared to folic acid. But the cost is likely to go down if it is massproduced. As stated in the Food Standard Australia and New Zealand (FSANZ) report on folic acid fortification, these costs are likely to be minimal on the basis of the following: new market opportunities may arise through the use of 5-CH3THF; industry will have the choice to use either 5-CH3THF or folic acid as appropriate for their products; labeling costs may be absorbed through normal business cycles. There may also be a direct benefit to some consumers through consuming a form of folate that is considered unlikely to mask symptoms of a Vitamin B12 deficiency. It is reported to be about 4 times more expensive than PGA [8]. It may remain more expensive than PGA but the production cost will go down if it is mass-produced.

Folate compounds, 5-CH3THF in particular, are reported to be susceptible to thermal degradation, high hydrostatic pressure, presence of various levels of oxygen, extreme pH, presence of various chemicals etc. [9]. Existing literatures indicate that 5-CH3THF cannot be directly used as a fortificant in foods as it is most likely to undergo oxidation during processing. Our recent paper has shown that microencapsulation as one of the methods that potentially improve the stability of 5-CH3THF in cereal based foods [9].

Biscuits or cookies are widely consumed snacks, therefore, along with bread and other-cereal based foods, is an ideal food for folate fortification. There have been few studies where the effect of bread baking on folate compounds is studied but there is no data on stability of 5- CH3THF vitamer in biscuit [10-12]. This project is aimed at investigating the delivery of encapsulated and unencapsulated 5-CH3THF into the biscuit and the recovery of 5-CH3THF under different baking times and temperatures. Besides, the effects of these baking conditions on the quality parameters of biscuits such as texture, moisture, and colour of the biscuits are also investigated. So far, there is no study on microencapsulation of 5-CH3THF and its stability during biscuit baking.

2. Materials and Methods

2.1. Materials

The vitamin 5-CH3THF [(6R,S)-5-Methyl-5,6,7,8 tetrahydrofolic acid calcium salt] was purchased from Schricks Laboratories, Jona, Switzerland. All the ingredients required for biscuits preparation such as, plain soft wheat flour, vegetable oil, sugar, baking soda, vanilla, common salt and lecithin were purchased from the local supermarket (Table 1). One g of encapsulated 5-CH3THF (1801 µg) was used in one formulation whereas 2375 µg unencapsulated or free 5-CH3THF powder was used in the other formulation. Distilled de-ionized water was used throughout the analysis. 

2.2. Microencapsulation of 5-CH3THF

5-CH3THF was encapsulated in a combination of pectin (P) and sodium alginate (A) [(P60:A40), (P70:A30) and P80:A20)] using spray drying. Details of the microencapsulation procedure are given in our previous paper [9]. The loading efficiency of the spray dried 5-CH3THF microcapsule was studied following the protocol described by Madziva i.e., release of microencapsulated 5- CH3THF in 0.1 M phosphate buffer at pH 8.2 [13].

2.3. Preparation of 5-CH3THF Fortified Biscuits

Plain flour and encapsulated 5-CH3THF (1% of total solids) or unencapsulated 5-CH3THF were mixed using a Hobart Planetary Mixer A200 (Hobart, Australia) in a

Table 1. Formulation of biscuit ingredients with encapsulated and unencapsulated 5-CH3THF.

dark room for 10 minutes and placed into the aluminum laminated foil bags. The experiment was performed entirety in a single day to reduced variation between batches. All the ingredients were weighed individually into separate containers. Water, sugar, salt and vanilla were added together as given in the Table 1 and stirred until dissolve in solution. Oil and lecithin were then added and agitated using a Kenwood Major KM201 (Kenwood; UK) for 5 minutes. Flour and bicarbonate soda were added and mixed for a further 3 minutes. The dough was then split into 20 g portions and shaped using a cookie cutter, diameter 4.5 cm, thickness 5 mm. Biscuits containing either unencapsulated 5-CH3THF or encapsulated 5-CH3THF were baked in a pre-heated Convotherm Convostar oven (APV Moffat; Germany) at three temperatures; 180˚C, 200˚C and 220˚C for three different lengths of time of 5, 9 and 12 minutes, until the biscuit become hard and golden brown. These baking temperatures were selected based on the previous baking studies by Jisha et al. and with some trials in the current oven [14]. Three batches of biscuits were prepared, one batch had 18 biscuits under 3 different temperatures and times (replicates 1, 2 and 3) (Table 2). These biscuits were cooled and placed into sealable aluminum foil bags and later used for analysis of physical properties (refrigerate, 4˚C) and 5-CH3THF content (kept frozen, −18˚C). To distinguish the effect of encapsulation and baking temperature at various baking times, analysis of variance (ANOVA) and multiple range tests were conducted on the sample means [15].

2.4. Measurement of Physical Properties

Moisture content of the biscuits was measured by vacuum oven method [16]. All the biscuits were cryo-milled in the liquid nitrogen bath (6850 Freezer/Mill, SPEX CertiPrep Inc., Metuchen, New Jersey, USA) and transferred into dark bottles and kept at −18˚C for subsequent 5-CH3THF extraction. Cryo-milling was used to ensure no heat damage of the vitamin occurs due to heat produced during conventional grinding of biscuit. Moisture content of freeze-dried biscuits was close to zero. Color characteristics (“L”, “a” and “b”) of biscuits were measured by Chroma Meter CR-400/410 (Konica Minolta Sensing Inc., Tokyo, Japan). The Chroma Meter was calibrated against a white standard plate before actual color measurement. In this system, L value indicates lightness, +a value indicates “redness” and −a to greenness, +b value indicates yellowness and −b to blueness. Five replicate measurements were performed for each sample. Biscuits were compared for their relative colour difference () from the control

Table 2. Randomized experimental design of biscuit experiments1.

colour white (L* = 97.146, a* = 5.2048, b* = −3.453). Colour difference was determined by the following formulation:

The texture of the biscuits was measured using a stable micro system TA.XT Plus Texture Analyser (Arrow Scientific Pty Ltd. Lane Cove N.S.W, Australia) with a HDP/3PB three-point bend rig attachment. The maximum force (N) required to break the biscuit was measured, and the resulting graphs were recorded. The biscuits were at room temperature and of uniform size. The TA.XT Plus machine was calibrated to a set load (5 kg) and height. For each texture and colour different analysis, six (biscuits) replicates were used. 

2.5. Analysis of 5-CH3THF from Foods

The 5-CH3THF from the ground sample was extracted by simple boiling and centrifugation as described previously [17]. Further extraction of 5-CH3THF, filtration, purification by solid phase extraction, standard and sample preparation for HPLC analysis and quality control were followed by the method as previously described [9].

3. Results and Discussion

3.1. Sample Analysis and HPLC Performance

HPLC analysis of standards showed folic acid and 5- CH3THF were well separated by the current protocol of gradient elution in the given column. The retention time for 5-CH3THF was 16.76 min (Figure 1). Folic acid was analysed along with 5-CH3THF had retention time of 20.41 min. It was also noted that the retention times of both folate compounds changed slightly between injections. However, it did not affect the absolute value of the folate compounds in the samples. These slight variations could be due to differences in concentration of mobile phase, elution buffer, column temperature and other factors that possibly influence the mobility of the analytes in the column. Some minor peaks also appeared in the vicinity of the folic acid and 5-CH3THF peaks indicating possible breakdown of these compounds.

The processed samples were extracted in the buffer containing combined antioxidants, 2-mercaptoethanol and ascorbate to prevent folic acid loss during the extraction and analysis [18]. The chromatograms of sample extracts showed the solid phase extraction (SPE) technique ensured separation of 5-CH3THF and subsequent detection of folate compounds by HPLC (Figure 1). Recovery of 5-CH3THF during solid phase extraction (SPE-SAX) was also tested that showed the recovery of the vitamin at close to 85% - 112%. It is deemed to be satisfactory as majority of the vitamin being permeated through the column.

3.2. Loading Efficiency 5-CH3THF Microcapsule

Spray drying was chosen as the method of encapsulation due to its availability, cost effectiveness and widespread use in food industries. Details of loading efficiency of 5-CH3THF in the spray dried microcapsule or encapsulate is already described in the previous paper [9]. Results showed loading efficiency of 5-CH3THF in microcapsule at pectin:alginate ratios of (P80:A20), (P70:A30) (P60: A40) resulting in recovery of 68.6%, 46.9% and 26.1% with the 5-CH3THF content ranging from 429, 293 and 163 µg/g, respectively. Previous data also showed pectin

Figure 1. Chromatogram of standard mixtures of folic acid and 5-CH3THF at 200 ng/mL.

improves the gel strength, mixture stability, barrier property to water and gives homogeneity, uniformity of pore size and strength when used along with alginate [19-21].

3.3. Fortification of Biscuits with 5-CH3THF

As previously mentioned, microcapsule with the highest recovery or 429 μg 5-CH3THF/g capsule was used in biscuit formulation (426 μg/g fortified biscuit) whereas 563 μg 5-CH3THF/g was added to per g unencapsulated fortified biscuit formulation (Table 1). Relatively higher amount of 5-CH3THF was added to unencapsulated fortified biscuit as it is more likely to degrade than the one from the encapsulated fortified biscuit. Table 3 shows that the baking temperatures and times largely affected the retention of added 5-CH3THF, in both encapsulated and unencapsulated fortified biscuits. Fortified biscuit with encapsulated 5-CH3THF heated at 180˚C for 5 min showed the highest retention of 5-CH3THF (19.1%) but further heating significantly (p ≥ 0.05) reduced 5-CH3THF to 8.5% at 200˚C and 4.9% at 220˚C. This study clearly showed very low retention of 5-CH3THF at elevated temperatures particularly at or above 200˚C. Baking of 5- CH3THF encapsulated biscuits from 200˚C to 220˚C at 5 to 12 min resulted in further reduction, with retention of vitamin ranging from 5.1% to 6.8%. The loss of vitamin appeared to be indiscriminate of processing conditions, e.g., time and temperature.

Fortified biscuits with unencapsulated 5-CH3THF had severe destruction of 5-CH3THF (Table 3). The highest and lowest retention of unencapsulated 5-CH3THF were 6.7% and 1.7% for biscuits baked for 5 and 12 min at 200˚C, respectively, following indiscriminate trend of 5- CH3THF loss as shown in the encapsulated samples.

Considering a half-life period of 21.4 min at 100˚C, loss of 5-CH3THF during baking (temperature >180˚C) was anticipated [22]. It was also expected that microencapsulation would give a certain degree of protection to the vitamin during heat processing but the outcome was not encouraging. Our previous study showed that the use of encapsulated 5-CH3THF gives better retention in the extrudates (temperature ranging from 100˚C - 150˚C) as compared to unencapsulated. The vitamin degradation was much less in the extrudates containing encapsulated 5-CH3THF as compared to unencapsulated, particularly at higher temperatures, from 120˚C and 150˚C [9]. It appears that baking causes higher degradation of 5-CH3THF than extrusion, in both encapsulated and unencapsulated vitamin containing biscuits. Higher processing temperature and larger exposed surface area to volume that facilitate oxidation of 5-CH3THF could be few factors contributing towards such a heavy loss of the vitamin.  

There are very few published literatures on the effect of processing on added 5-CH3THF in cereal-based foods. Crystalline L-5-CH3THF-Ca tablet is reported to be stable during long-term storage (48 months at 40˚C and up to 75% RH) [23]. Ohrvik et al. recently reported the retention of Ca salt of [6S]-5-CH3THF during bread baking at about 220˚C (inner temperature for 96˚C) for more than 90 min, total baking and cooling time about 5 h, ranged from 31% to 38% [24]. Study also showed more endogenous 5-CH3THF was retained (75%) compared to the externally added folate vitamer.

Baking methods for cakes, breads and biscuit are different. In bread, baking temperature is lower over a longer period of time and the moisture gradient is at atmospheric conditions so the moisture escapes at an even rate before a crust forms. As a result of this, the inside temperature of the food does not exceed 100˚C. However, in the current study, baking a thin (5 mm) biscuit dough with relatively low moisture content (~20%) means moisture from the surface evaporates rapidly and there is little gradient of moisture and temperature. Heat transfer by a combination of conduction, convection and radiation are likely to establish the biscuit temperature closer to the baking temperature. It was noticed that baking at a higher temperature, from 200˚C onwards resulted in surface charring of

Table 3. Measurement 5-CH3THF of biscuits baked at different temperatures and times.

the biscuits (picture not shown). Therefore, heat sensitive vitamins are more likely to be destroyed during biscuit baking compared to bread baking.

Previous studies have also reported a loss of 7% to 67% endogenous 5-CH3THF when proofed dough is baked at about 240˚C for 40 min [10,12]. Biodar has referred to their unpublished data that reported the micro-encapsulated 5-CH3THF-Ca (using inert carriers) is about 90% recoverable from baked bread, and 75% recoverable from breakfast cereals, in which it had been incorporated during the manufacturing process [25]. Biodar further reported the 5-CH3THF-Ca could be released completely from the encapsulation by incubation in an artificial digestive system at pH 6.8 for 3 hours. It has also been suggested that 5-CH3THF-Ca in microencapsulated form, preferably with ascorbate as an antioxidant, has long-term stability in a variety of foodstuffs [23]. A recent study by Tomiuk et al. (2012) reported the use of skim milk powder as the encapsulating agent for 5-CH3THF using spray drying and subsequent fortification in bread. The recovery of microencapsulated 5-CH3THF from the bread was 81%, which further increased to 87% when ascorbic acid was incorporated into the formulation.

3.4. Change in Colour Parameters

Biscuit baked at 180˚C appeared to be golden brown in color which is the characteristic of baked cereal foods. High temperature and low moisture content in the surface layers cause caramelization of sugars and oxidation of fatty acids to aldehydes, lactones, ketones, alcohols and esters which cause a deeper brown colour [26]. Color development in sugar and protein rich system like biscuits, which is baked at higher temperature, is caused by Maillard reaction. The golden brown color in biscuits turned to intense red and dark when baked for short times at 200˚C and 220˚C (Table 4). This is in agreement with previous report that showed an increase in oven temperature decreases the lightness of biscuit, independent of heat transfer mode of oven temperature to the product (>190˚C) [27]. Further heating time, such as 9 and 12 min at 200˚C and 220˚C led to almost charring of the biscuit surface.

The color characteristics of the baked products showed that increasing baking temperature and time lowered the lightness value (L) but increased the redness (a) and yellowness (b) (data not shown). Table 4 shows a gradual increase in overall colour difference (ΔEab) values with increase in baking temperature and time in encapsulated as well as unencapsulated biscuits. This indicates a gradual transformation of biscuit colour from lighter to much deeper yellow and red colour and finally into much darker product.

3.5. Change in Texture Profiles

Biscuit baked at 180˚C for 5 min required the lowest force to break the biscuits (Table 4). The force increased with increase in baking time. Lower hardness in low temperature/time baked biscuits indicates less brittle (but crunchy) biscuits with greater internal cohesiveness and springiness [28]. It is also likely that the biscuits at this stage were still not fully cooked and had a relatively softer texture. With increase in time and temperature, further development of gluten matrix as well as starch gelatinization and retrogradation occurs that might entrap

Table 4. Measurement of texture, moisture and change in colour characteristics of biscuits baked at different temperatures and times.

moisture in their matrix. Besides, moisture release from the surface might have hampered as the crust is sealed due to plasticization of proteins and starch. This might lead to a more hard, brittle and cohesive mass that needs greater force to break the biscuits. It was difficult to compare the force needed to break biscuits baked at 200 and 220˚C as the biscuit surface (interior in some cases) started to carbonize due to high temperature and baking time. For example, for biscuits with encapsulated 5- CH3THF baked at 220˚C, the breaking force started to drop with increasing baking time (Table 4). It is likely that the biscuit become hard and brittle that poses less resistance to breaking force. Results showed a distinguishable variation in measurable hardness of biscuits. Ahmad and colleagues have reported that the texture of biscuits vary within the same biscuit due to non-uniform moisture distribution, particularly in conventional oven [29].

3.6. Change in Moisture Content

As expected the moisture content of the biscuits decreased with increase in baking temperature and time (Table 4). The initial moisture content of the dough containing encapsulated 5-CH3THF was 16% (dry basis) which decreased to 7.8%, 6.3% and 4.6% when baked for 5 minutes at 180˚C, 200˚C and 220˚C, respectively. These values further decreased to 2.7%, 1.7% and 1.4% when baked for 12 min at 180˚C, 200˚C and 220˚C, respectively. The moisture loss trend in biscuits with unencaspsulated 5-CH3THF was similar to encapsulated ones, therefore, not reported. Moisture loss during the first 5 min caused more than half of the initial moisture in the dough. As expected, the moisture loss was too low and too quick while drying at 220˚C which leads to scorching and slight charring of the biscuit surface. Low moisture content in biscuits resulted in brittleness, as shown by breakdown at lower peak force (Table 4). It has been widely reported that non-uniform distribution of moisture in the biscuit during baking and drying affect the texture formation and hardness [29].

4. Conclusion

Microencapsulation is a technique that provides protection to highly susceptible micronutrients including 5- CH3THF. Use of pectin and alginate solution as encapsulating material showed increased pectin in the mixture resulting in higher loading efficiency of 5-CH3THF. The inclusion of encapsulated and unencapsulated 5-CH3THF in the biscuit formulation and subsequent baking at various temperatures and times resulted in retention of 5- CH3THF from 19.1% to 1.7%. It seems intense heating that caused “over baking” of the biscuit likely to be responsible for the loss of the vitamin. Physical analysis showed darker colour, harder texture and lower moisture for biscuits baked at higher test temperatures.

5. Acknowledgements

Early Career Research Grant from the Office of Research and Postgraduate Studies (ORPS), The University of Queensland, Brisbane, Australia, is gratefully acknowledged.

NOTES

Conflicts of Interest

The authors declare no conflicts of interest.

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