Sütlü Çikolata İçin Katı Faz Mikroekstraksıyon Yönteminin Optimizasyonu

In the current study, the Central Composite Design was applied to optimize HS-SPME extraction in orderto detect 2,3,5,6 tetramethyl pyrazine in isomalt contaning milk chocolate. The optimal conditions for thethree experimental responses influencing SPME efficiency were 10 min, 40 min and 57 °C for equilibrationtime, extraction time and extraction temperature, respectively. SPME fibers coated with 100 mpolydimethylsiloxane coating, 65 µm polydimethylsiloxane/divinylbenzene coating, 75 µmcarboxen/polydimethylsiloxane coating and 50/30 µm divinylbenzene/carboxen/polydimethylsiloxane ona StableFlex fiber were investigated. The preparation conditions of the chocolate samples were also evaluatedby measuring their effects on the coating composition of the head space. The SPME fiber coated with 50/30µm divinylbenzene/carboxen-polydimethylsiloxane provided the highest extraction efficiency, especiallywhen the samples were extracted at 60 °C for 30 min under dry conditions. Eighty-one blends were extractedand experimentally detected most of which have been formerly stated as odor-active components.Bu çalışmada, isomalt içeren sütlü çikolatalarda 2,3,5,6 tetra metal pirazin tayini için HS-SPME ekstraksiyonunun optimizasyonunda merkezi kompozit tasarım uygulanmıştır. SPME verimliliği etkileyen dengeleme süresi, ekstraksiyon süresi ve ekstraksiyon sıcaklığı için optimum koşullar olarak sırasıyla 10 dk, 40 dk ve 57 °C olarak belirlenmiştir. Çalışmada StableFlex fibere uygulanmış 100 µm polidimetilsiloksan, 65 µm polidimetilsiloksan/divinilbenzen, 75 µm karboksen/polidimetilsiloksan ve 50/30 µm divinilbenzen/karboksen/polidimetilsiloksan kaplamalar SPME fiberler olarak incelenmiştir. Çikolata örneklerinin hazırlama koşulları ayrıca tepe boşluğunun kaplama bi leşimi üzerindeki etkileri ölçülerek de değerlendirilmiştir. Özellikle örneklerin kuru koşullarda 60 °C’de 30 dk örnek ekstraksiyonunda 50/30 µm divinilbenzen/karboksen/polidimetilsiloksan kaplı SPME fiber en yüksek ekstraksiyon verimliliğini sağlamıştır

Development of Synbiotic Milk Chocolate Enriched with Lactobacillus paracasei, D-tagatose and Galactooligosaccharide

Background and Objective: Prebiotics are food ingredients that induce the growth or activity of beneficial bacteria (Bifidobacteria and Lactobacilli). Galactooligosaccharide and tagatose are two main prebiotic compounds which are used in the food industry. Chocolate is widely consumed all over the world and could be used as an excellent vehicle for delivery of prebiotics. Furthermore, the incorporation of probiotics into chocolate, allows broadening the health claims of chocolate. The aim of the current study was to investigate the effect of tagatose and galactooligosaccharide on the physicochemical and sensory properties of milk chocolate and the survivability of Lactobacillus paracasei in the optimized formulation. Material and Methods: Probiotic milk chocolate containing Lactobacillus paracasei were formulated by replacing a portion of the sucrose with the galactooligosaccharide powder and tagatose. For this purpose various concentrations of galactooligosaccharide and tagatose (2.5, 5 and 7.5% w w-1) along with stevia were used in chocolate formulation. Nine formulations were examined to determine some physicochemical, mechanical and sensory properties in order to find the optimum concentrations of these components. The lyophilized Lactobacillus paracasei were incorporated in the optimal formulation of prebiotic milk chocolate. The viability of probiotic bacteria in milk chocolate was carried out during storage at 22°C for up to 6 months.Results and Conclusion: In general, chocolate formulations with high levels of galactooligosaccharide, achieved the highest plastic viscosity and yield stress. The lowest viscosity and yield stress were observed for the samples containing high concentrations of tagatose and in control. In addition, galactooligosaccharide at higher ratios induced the least desirable sensorial effects, whereas tagatose improved the overall acceptability. It can be concluded that the overall acceptability of milk chocolate samples were with (7.5), tagatose: galactooligosaccharide ratios of 2.5%-2.5%, presenting the optimal applicable range as prebiotic compounds. Numbers of live Lactobacillus paracasei cells remained above 8.0 log CFU g-1 until 6 months under ambient conditions. Milk chocolate was shown to be an excellent vehicle for the delivery of Lactobacillus paracasei, and the prebiotic ingredients galactooligosaccharide and tagatose did not interfere in its viability. Conflict of interest: The authors declare no conflict of interest

Application of simplex lattice mixture design for optimization of sucrose-free milk chocolate produced in a ball mill

The aim of this study was to define optimal conditions by using Simplex lattice mixture design for the for- mulation of sucrose-free chocolate produced in a ball mill. Milk chocolate mass were made using three different polyols including maltitol, xylitol and isomalt along with Stevia as high potency sweetener. The influences of polyols mixtures as sucrose substitutes on rheological properties and main physical quality parameters were investigated. According to the results, the fitted models demonstrated a high coefficient of determination (≥93%). The optimization of the variables illustrated that utilizing 11.16% w/w maltitol, 8.9% w/w xylitol and 12.93% w/w isomalt produced the optimum milk chocolate with the highest desirability (1.00) without un- wanted variations in the rheological and quality characteristics. Also the optimum formulation was produced to validate the optimum model. The sensory analysis of the optimized formulation satisfied the consumer demand

Chocolate flow behavior: Composition and process effects

Chocolate is a non-Newtonian substance, and such substance has different viscosities at different shear rates. Rheological evaluations have become indispensable instruments for characterizing final chocolate, forecasting product efficiency and consumer acceptance. During production, the different steps depend on a well-defined viscosity and yield stress. Furthermore, the characteristics of the final chocolate (the surface and mouth-feel) are directly related to the chocolate's viscous behavior. There is a demand for better understanding the variables affecting chocolates flow behavior. Current research realized great insight into the chocolate flow behavior in different processes such as refining, conching, and tempering. Also, the influence of formulation and particle characteristics on flow behavior of the intermediate product and the final product were discussed. Each stage of the production process: mixing, refining, conching and tempering involves modifications of macroscopic characteristics of the chocolate ingredients thus affecting the rheological attributes of the final product. Particle size distribution and ingredient composition play substantial roles in shaping its flow behavior and sensory perception. The rheological properties of chocolate provide substantial information for food scientists to improve and optimize their products and manufacturing processes. Nowadays, a thorough understanding of chocolate flow behavior is a necessity for food scientists and industry

A Novel Delivering Agent for Bioactive Compounds: Chewing Gum

Functional food concept is one of the hot topics in the food industry. In recent years, people want to consume food products having health beneficial effect as well as nutritive characteristics. Regarding functional food development, foods have also advantages and disadvantages in terms of delivering bioactive compounds due to formulation (interaction of the bioactive compound with other ingredients, calorie value provided) and production process (mechanical and thermal processes applied during production). When considering the factors restricting usage of the food products as a delivery system, chewing gum is one of the most up-and-coming products in many aspects: (i) simplicity of the formulation prevents the activity of bioactive compound by interaction, (ii) level of mechanical and thermal stresses applied during production, (iii) enabling the release of targeted molecule in a controlled and sustained manner, (iv) different consumption behavior abolishing calorie intake concern since it is only chewed without swallowing, and (v) holding time in mouth. Usage of encapsulated bioactive compounds can improve the release behavior of the functional ingredient. Mastication process and the formed matrix/structure of the chewing gum also influence the release of the bioactive compounds. The researches about improving functionality of chewing gum have indicated that chewing gum can be used as a delivery system for transportation of the desired bioactive compound to body/targeted site. However, during functional chewing gum development, formulation, production process, mastication process, and type/form of bioactive compounds should be considered to achieve the product with required functional properties. © 2019, Springer Nature Switzerland AG

Chocolate aroma: Factors, importance and analysis

Background: The quality and value of chocolate are related to its unique and fascinating flavor arisen from volatile and non-volatile compounds present in the product. The particular chocolate aroma is dependent on various factors including genotype and the agro-ecological niche (environment conditions, farming practices), post-harvest conditions and complex biochemical and chemical reactions during this period (fermentation, drying) and manufacturing stages. Scope and approach: In this study, relationship between chemical compounds and cocoa flavors, control and management of post-harvest practices and manufacturing processing in order to obtain chocolate with differentiated characteristics and also evaluation methods especially sensory aspects of the chocolate are highlighted. For this purpose, instrumental experiments including headspace aroma extraction, simultaneous distillation extraction and sensory testing such as discrimination experiments, descriptive tests and hedonic experiments were discussed. Key findings and conclusions: A comprehensive link between the components of cocoa flavor, sensory characteristics, human acceptability, and also the processes involved in flavor formation and formulation used, will assist the administration of a traceability system, a challenging case for quality assurance groups

Effects of polyols on the quality characteristics of sucrose-free milk chocolate produced in a ball mill

Sucrose-free milk chocolates containing different types of bulk (isomalt, xylitol and maltitol) and high intensity (Stevia) sweeteners were produced by using a ball mill. The main quality characteristics of the formulated chocolates were evaluated and compared with those of the conventional sample containing sucrose. The Casson model was the best fitting model for the rheological data. Casson viscosity and Casson yield stress were significantly affected by the type of bulking agent in chocolates formulated with xylitol (p < 0.05). However xylitol notably improved the overall acceptability according to the sensory analysis results. Chocolates containing the sucrose replacers demonstrated lower Tonset values and higher enthalpy than the control sample. Sucrose-free chocolates illustrated a higher degree of particle agglomeration. Bulk sweeteners meanwhile seem to have high potential for milk chocolate production with low calorie values by using the ball mill technique. Industrial applications: the production of sucrose-free chocolates with conventional methods requires a lot of time and energy. Recently, using alternative methods for chocolate production has been raising interest in many small industries. This study proposed a ball mill method for the preparation of sucrose-free milk chocolates with physiochemical properties almost ranging in the standard limit defined for chocolate. Although using the ball mill method presents a more cost-effective technique for chocolate production and provides shorter processing times for small chocolate industries, it seems to be less efficient in evaporating moisture than the conventional processing. Challenges are still ahead for upgrading this alternative technique to be efficient in evaporating more moisture during operation ending in a high quality product

Pre-crystallization process in chocolate: Mechanism, importance and novel aspects

Pre-crystallization is an important step in the production of chocolate, which is defined as tempering of cocoa butter through primary and secondary nucleation. The goal of tempering is to obtain a sufficient amount of beta(v) polymorph of the right size. The pre-crystallization process has a great impact on the quality and production cost of final product. Development of chocolate technology requires the use of the most appropriate techniques and ingredients without negatively affecting the quality characteristics. Applications of novel technologies within the confectionery industry have allowed production of chocolate in sufficient quantities to meet the public needs. In order to provide and investigate the potential and usage of novel technologies, the present review focused on different pre-crystallization methods and factors affecting the processing conditions. Seeding and ultrasound-assisted pre-crystallization can be used as alternatives to conventional tempering process. However, in both methods, optimization of experimental conditions is required

Improving Functionality of Chocolate

Top trends in the food industry are mainly related with improvement of functionality of the products. Food manufacturers and researchers mainly focus on this subject and it is aimed to produce the functional products with quality characteristics similar to conventional ones. In the present chapter, the ways to improve functional characteristics of the chocolate products were reviewed. Calorie reduction in chocolates with using sugar and cocoa butter alternatives and its effect on chocolate quality was mentioned. In addition, the influence of processes applied for cocoa and chocolate productions on polyphenol composition and antioxidant activity was also addressed. Studies related with dietary fiber usage as a prebiotics and their effects on chocolate quality and probiotic chocolates and bioaccessibility of probiotics were also summarized in the chapter. It can be highlighted that functional characteristics of the chocolate or derived products can be improved by enrichment and adjusting production process parameters. Chocolate is a good functional compound carrier since it is lovely consumed by people of all age throughout the world

Alternative Tempering of Sugar-Free Dark Chocolates By βv Seeding: Sensorial, Micro-structural, and Some Physical Properties and Volatile Profile

In this study, sugar-free dark chocolate was produced from isomalt and maltitol by βV seeding technique as an alternative to conventional tempering process. The effect of βV seed concentrations on the particle size dis- tribution, textural, rheological and melting properties of the end products was studied, and the results were compared with those of conventional sugar-free dark chocolates. For this aim, conched dark chocolates were melted and crystallized with βV seeds added at different concentrations (0.5, 0.6, 0.7, 0.8, 0.9 and 1.0 %, m/m). Conventional tempering process was performed by using temper machine (47–27–32 °C). Brightness, chroma, whiteness index and tetramethyl pyrazine content (as marker compounds of dark chocolate volatile compound) were not influenced by seeding technique compared to conventional tempering method. The water activity of the dark chocolate samples was substantially affected by βV seed level according to used bulk sweetener. How- ever, all the values were determined below 0.4 which is critical limit for chocolate. Regarding overall acceptabil- ity, sugar-free dark chocolates tempered by βv seeds had very close scores compared with conventional one, implying that sugar-free chocolates can be produced by βv crystals with desired quality characteristics similar to conventional samples. Results of this study showed that it is possible to produce sucrose-free dark chocolates by using βV seeds with desired quality similar to chocolate produced by using conventional tempering