Powdered honey – drying methods and parameters, types of carriers and drying aids, physicochemical properties and storage stability

Comparative studies on the rheological characteristics, functional attributes, and baking stability of xanthan and guar gum formulated honey gel matrix

The research aims to enhance the characteristics of honey by incorporating xanthan gum (XG) and guar gum (GG) at various concentrations (0.5-2.0% w/w) and preparing a honey gel matrix (HGM) through high-shear homogenization. This approach serves as a substitute for fat-based filling materials commonly used in bakery products. The study encompassed an investigation of the rheological characteristics (steady and dynamic), total phenolic content (TPC), antioxidant activity, and baking stability of the HGMs. The concentration of the gums used significantly influenced the transformation of honey into the HGM and its stability. Notably, the XG-HGM demonstrated greater shear thinning behavior and higher consistency compared to the GG-HGM. Herschel Bulkley and power law models were found to be the best-fitted models for XG-HGM and GG-HGM, respectively. Furthermore, both XG-HGM and GG-HGM exhibited a higher viscous component (G″) than an elastic component (G') at low concentrations, up to 1% (w/w) for XG-HGM and 1.5% (w/w) for GG-HGM; however, this behavior reversed beyond those concentrations (G' > G″). The XG-HGM exhibited lower temperature sensitivity compared to GG-HGM, indicating better stability under varying heat conditions. Moreover, both TPC and antioxidant activity decreased with increasing concentrations of both gums. The XG-HGM achieved the highest baking stability index, reaching 95.23% at a 2% concentration. This modified HGM formulated with XG demonstrated superior consistency, color retention, and exceptional baking stability, making it a promising candidate for application as a filling material in the bakery sector. Its improved stability and quality can facilitate the development of a wide range of baking products in the food industry.

Design, Preparation, and Physicochemical Characterisation of Alginate-Based Honey-Loaded Topical Formulations

Honey has widespread use as a nutritional supplement and flavouring agent. Its diverse bioactivities, including antioxidant, antimicrobial, antidiabetic, anti-inflammatory, and anticancer properties, have also made it an aspirant natural product for therapeutic applications. Honey is highly viscous and very sticky, and its acceptance as a medicinal product will require formulation into products that are not only effective but also convenient for consumers to use. This study presents the design, preparation, and physicochemical characterisation of three types of alginate-based topical formulations incorporating a honey. The honeys applied were from Western Australia, comprising a Jarrah honey, two types of Manuka honeys, and a Coastal Peppermint honey. A New Zealand Manuka honey served as comparator honey. The three formulations were a pre-gel solution consisting of 2-3% (w/v) sodium alginate solution with 70% (w/v) honey, as well as a wet sheet and a dry sheet. The latter two formulations were obtained by further processing the respective pre-gel solutions. Physical properties of the different honey-loaded pre-gel solutions (i.e., pH, colour profile, moisture content, spreadability, and viscosity), wet sheets (i.e., dimension, morphology, and tensile strength) and dry sheets (i.e., dimension, morphology, tensile strength, and swelling index) were determined. High-Performance Thin-Layer Chromatography was applied to analyse selected non-sugar honey constituents to assess the impacts of formulation on the honey chemical composition. This study demonstrates that, irrespective of the honey type utilised, the developed manufacturing techniques yielded topical formulations with high honey content while preserving the integrity of the honey constituents. A storage stability study was conducted on formulations containing the WA Jarrah or Manuka 2 honey. The samples, appropriately packaged and stored over 6 months at 5, 30, and 40 °C, were shown to retain all physical characteristics with no loss of integrity of the monitored honey constituents.

Evaluation of physicochemical properties of honey powder using rice and pea proteins as carriers

Honey is a special product widely appreciated because of its peculiar flavor and aroma as well as its beneficial effects on health due to its constituents. However, the use of honey in its natural form can present several disadvantages to the food industry because of its high viscosity and density. This work aimed to obtain honey powder using rice, pea, or a mixture of both proteins as carriers by spray drying and to characterize physiochemically. Also, the mass balance was performed to evaluate changes in humidity and temperature that occurred by the drying air during the process. The honey showed acceptable physicochemical parameters by the legislation of honey quality control in regard to color (143.43 ± 4.34) mm Pfund, free acidity (46.41 ± 0.53) meq/kg, pH (3.73 ± 0.03), fructose content (46.52 ± 0.56) g/100 g and glucose content (35.88 ± 0.16) g/100 g, which leads to the production of honey powder. Among the carriers tested, the honey powder using rice protein achieved the highest powder recovery yield at (64.88 ± 0.64) %. The physicochemical properties were evaluated and the phenolic compounds were not negatively affected by spray drying conditions, maintaining a value of gallic acid equivalent (GAE) content at (301.31 ± 20.95) mg/kg of honey. Therefore, this work shows honey as an alternative food ingredient in powdered form, including the growing market for using alternative protein.

Development of spray-dried N-acetylcysteine dry powder for inhalation

N-acetylcysteine (NAC) has both antioxidant and immunomodulatory activities and has been used as adjuvant therapy in several viral infections. Recently, NAC attracted attention for its possible role in reducing the affinity of the spike protein receptor binding domain to angiotensin-converting enzyme (ACE2) receptors. Since only NAC solutions are available for inhalation, the purpose of the work was to develop a NAC dry powder for inhalation using mannitol or leucine as excipient. The powder was successfully produced using co-spray-drying with leucine. ATR-FTIR analyses evidenced spectral variations ascribed to the formation of specific interactions between NAC and leucine. This effect on the NAC environment was not evident for NAC-mannitol powders, but mannitol was in a different polymorphic form compared to the supplied material. Both the feedstock concentration and the leucine content have an impact on the powder aerodynamic features. In particular, to maximize the respirable fraction, it is preferable to produce the powder starting from a 0.5 % w/v feedstock solution using 33 to 50 % w/w leucine content. The NAC-leucine powder was stable for ten months maintaining NAC content of 50 % (w/w) and about 200 μg of NAC was able to deposit on a transwell insert, useful for future in vitro studies.

Classification of Honey Powder Composition by FTIR Spectroscopy Coupled with Chemometric Analysis

Fourier transform infrared spectroscopy (FTIR) in connection with chemometric analysis were used as a fast and direct approach to classify spray dried honey powder compositions in terms of honey content, the type of diluent (water or skim milk), and carrier (maltodextrin or skim milk powder) used for the preparation of feed solutions before spray drying. Eleven variants of honey powders containing different amounts of honey, the type of carrier, and the diluent were investigated and compared to pure honey and carrier materials. Chemometric discrimination of samples was achieved by principal component analysis (PCA), hierarchical clustering analysis (HCA), linear discriminant analysis (LDA), and partial least squares-discriminant analysis (PLS-DA) modelling procedures performed on the FTIR preprocessed spectral data for the fingerprint region (1800-750 cm^-1) and the extended region (3600-750 cm^-1). As a result, it was noticed that the type of carrier is a significant factor during the classification of different samples of powdered multifloral honey. PCA divided the samples based on the type of carrier, and additionally among maltodextrin-honey powders it was possible to distinguish the type of diluent. The result obtained by PCA-LDA and PLS-DA scores yielded a clear separation between four classes of samples and showed a very good discrimination between the different honey powder with a 100.0% correct overall classification rate of the samples.

Deep and Machine Learning Using SEM, FTIR, and Texture Analysis to Detect Polysaccharide in Raspberry Powders

In the paper, an attempt was made to use methods of artificial neural networks (ANN) and Fourier transform infrared spectroscopy (FTIR) to identify raspberry powders that are different from each other in terms of the amount and the type of polysaccharide. Spectra in the absorbance function (FTIR) were prepared as well as training sets, taking into account the structure of microparticles acquired from microscopic images with Scanning Electron Microscopy (SEM). In addition to the above, Multi-Layer Perceptron Networks (MLPNs) with a set of texture descriptors (machine learning) and Convolution Neural Network (CNN) with bitmap (deep learning) were devised, which is an innovative attitude to solving this issue. The aim of the paper was to create MLPN and CNN neural models, which are characterized by a high efficiency of classification. It translates into recognizing microparticles (obtaining their homogeneity) of raspberry powders on the basis of the texture of the image pixel.

Resistant Starch-Based Edible Coating Composites for Spray-Dried Microencapsulation of Lactobacillus acidophilus, Comparative Assessment of Thermal Protection, In Vitro Digestion and Physicochemical Characteristics

Polysaccharides have excellent potential as food-grade coating materials for microencapsulation in pro- and prebiotics-based functional food industry. In this study, potato, maize, and rice resistant starches composite coatings with D-mannose, maltodextrin, and whey protein concentrate were prepared for the spray-dried microencapsulation of Lactobacillus acidophilus KLDS 1.1003. Assessment of different polysaccharide coatings to enhance the longevity of probiotics at high temperatures of spray-drying process, storage, and targeted delivery in the gastrointestinal tract were the key objectives of the present study. The highest microencapsulation efficiencies were shown by maize (95.80%) and potato (94.30%) resistant starches. Similarly, maize resistant starch (MRS)-based composites provided the highest thermal resistance, with Tg 38.77 ± 1.10–93.13 ± 0.81 °C and showed the least 2.1 log cycles viability loss in simulated GI tract. Viability losses during storage were in the following order: control > RRS > PRS > MRS, and the inactivation rate of the microencapsulated cells followed the first-order kinetics (R2 = 0.9264–0.9918). The resistant starch-based spray-dried microcapsules possessed 27.00 ± 0.03 to 52.28 ± 1.02 µm size range and SEM micrographs showed a unified smooth surface without cracks and ruptures. These findings will expand the potential use of natural food-grade coatings in functional foods and allied industries involving spray-dried products.

Dehumidified-Air-Assisted Spray Drying of Buckwheat Honey with Maltodextrin and Skim Milk Powder as Carriers

Buckwheat honey is proven to demonstrate health beneficial properties; however, its application in the industry is limited due to its high viscosity and syrupy-like consistency. The paper aimed to investigate process performance and physiochemical properties of carrier-reduced buckwheat honey. Honey was spray dried conventionally (inlet/outlet drying temperature: 180 °C/80 °C) and at low drying temperature with dehumidified air application (inlet/outlet drying temperature: 80 °C/45 °C) with maltodextrin as traditional carrier and alternatively with skim milk powder. The results of this study indicate that lowering the humidity of drying air enabled a decrease in carrier content of up to 25% (w/w solids), following powder recovery over 87%, which has not been recorded before for buckwheat honey powders. The results for the physicochemical properties proved that the application of the dehumidified air and skim milk powder as a carrier ameliorated their physiochemical properties and the antioxidant activity. Furthermore, the energy consumption of dehumidified-air-assisted spray drying was investigated as a basis for potential industrial application of this innovative method, which has not been studied in the literature before. The industrial application of this method must be carefully analyzed with regard to its advantages, as the energy consumption is significantly higher than in conventional spray drying.

Quality Assessment of Honey Powders Obtained by High- and Low-Temperature Spray Drying

The paper aimed to compare the quality of rapeseed and honeydew honey powders, obtained by two methods of spray drying—traditional at a high temperature (inlet air 180 °C) and innovative low-temperature spray drying with the use of dehumidified air as a drying medium (inlet air 75 °C). Total polyphenol content, antioxidant activity, and the content and types of aromatic compounds were determined. In addition, Fourier-transform infrared spectroscopy (FTIR) coupled with chemometrics analyses was done. Powders obtained by the low-temperature spray drying method (with dehumidified air) were characterized by a higher content of polyphenols, antioxidant activity, and aromatic compounds, compared to powders obtained by the traditional method. Honeydew honey compared to rapeseed honey was characterized by a higher content of polyphenols, antioxidant activity, and composition of aromatic compounds. The results proved that the production method had a higher impact on the final properties of powders than the type of honey.

Identification of sugars and phenolic compounds in honey powders with the use of GC-MS, FTIR spectroscopy, and X-ray diffraction

This work aimed at the chemical and structural characterization of powders obtained from chestnut flower honey (HFCh) and honey with Inca berry (HBlu). Honey powders were obtained by spray drying technique at low temperature (80/50 °C) with dehumidified air. Maltodextrin (DE 15) was used as a covering agent. The isolation and evaluation of phenolic compounds and sugars were done by gas chromatography-mass spectrometry analysis. Scanning electron microscopy, Fourier-transform infrared (FTIR) spectroscopy, and X-ray diffraction were performed to determine the morphology of the studied honey powders. The obtained results showed that the content of simple sugars amounted to 72.4 and 90.2 g × 100 g^-1 in HFCh and HBlu, respectively. Glucose was found to be the dominant sugar with a concentration of 41.3 and 51.6 g × 100 g^-1 in HFCh and HBlu, respectively. 3-Phenyllactic acid and ferulic acid were most frequently found in HFCh powder, whereas m-coumaric acid, benzoic acid, and cinnamic acid were the most common in HBlu powder. The largest changes in the FTIR spectra occurred in the following range of wavenumbers: 3335, 1640, and below 930 cm^-1. The X-ray diffraction profiles revealed wide peaks, suggesting that both honey powders are amorphous and are characterized by a short-range order only.

Reformulation of spray-dried apple concentrate and honey for the enhancement of drying process performance and the physicochemical properties of powders

BACKGROUND

Apple concentrate and honey were spray-dried with traditional carriers (maltodextrin, Nutriose®, Kleptose®) and with skimmed milk powder as a carrier substitute offering added value for the final product.

RESULTS

Skimmed milk powder, although having the lowest glass transition temperature, was the best carrier in terms of the highest powder recovery (higher than 80% was achieved) and with powder physical properties comparable to those obtained with other carriers. Thus, skimmed milk powder was used to produce honey powder of reduced carrier content (to 25% solids). The physical properties of the powders obtained and lower powder recovery indicated more problematic drying of AC. Powders produced with skimmed milk were characterized by enhanced nutritional value compared with variants with traditional carriers.

CONCLUSION

Thus, skimmed milk is proposed as a natural carrier for spray-drying, offering high processing yield, the possibility to reduce carrier content in honey powder, and to create products of nutritional added value. © 2020 Society of Chemical Industry.

Optimisation of umbu juice spray drying, and physicochemical, microbiological and sensory evaluation of atomised powder

Aim: Optimum conditions of umbu juice spray drying were selected using inlet air temperature (T), feed flow rate (F) and 10-DE maltodextrin concentration (C_MD) as independent variables, and water activity, moisture content, hygroscopicity and phenolic compounds retention as responses.Methods: Powders water activity was determined with a water activity metre, moisture content and hygroscopicity gravimetrically, total phenolics spectrophotometrically, apparent and absolute density, porosity and solubility by standard methods, particle size by laser diffraction, and morphology by Scanning Electron Microscopy. Nectars sensory analysis was based on acceptance, purchase intention and multiple comparison preference tests. Powder stability was checked at 25 °C varying water activity and storage time in the ranges 0.1-0.3 and 30-90 days, respectively.Results: Powders prepared at T = 110 °C, F = 0.84 L/h, C_MD=10% and T = 140 °C, F = 0.60 L/h, C_MD=10% gave the best microparticles and sensory results. The former showed properties suitable for industrial production.Conclusion: These findings may promote umbu powder industrial exploitation.