Dissolution of NaCl crystals in artificial saliva and water by video-microscopy

Enhancing the perception of saltiness and reducing NaCl levels in snacks through sensory interaction: Immobilizing NaCl nanocrystals in Litsea oleoresin-sunflower seed oleogels

Excessive dietary salt intake leads to health issues, while reducing NaCl content compromises flavor. Therefore, identifying methods to decrease salt levels without sacrificing flavor is crucial. This study investigated the sensory interaction between the saltiness of NaCl and the pungency of Litsea oleoresin. Glyceryl monostearate (6.6%) and soy lecithin (4.4%) were used as gelling agents to create oleogels, which were then employed to immobilize NaCl nanocrystals, optimizing sensory interactions. NaCl nanocrystals (427.73 ± 61.98 nm) were encapsulated in a Litsea oleoresin-sunflower seed oleogel system with uniform distribution. Sensory evaluation indicated that the NaCl nanocrystal/Litsea oleoresin@oleogel system, with moderate pungency, significantly enhanced perceived saltiness intensity (29.00 ± 1.14, compared to the control, 18.48 ± 1.12) (P < 0.05). When applied to potato chips, this system noticeably increased saltiness perception. This research provides a promising approach for developing low-sodium yet flavorful foods.

Sodium reduction in foods: Challenges and strategies for technical solutions

In many parts of the world, sodium consumption is higher than recommended levels, representing one of the most important food-related health challenges and leading to considerable economical costs for society. Therefore, there is a need to find technical solutions for sodium reduction that can be implemented by food producers and within food services. The aims of this review are to discuss the barriers related to sodium reduction and to highlight a variety of technical solutions. The barriers relate to consumer perception, microbiology, processing, and physicochemistry. Existing technical solutions include inhomogeneous salt distribution, coated salt particles, changing particle sizes and forms, surface coating, multisensory combinations, sodium replacements, double emulsions, adapted serum release by microstructure design, and adapted brittleness by microstructure design. These solutions, their implementation and the associated challenges, and applicable product categories are described. Some of these solutions are ready for use or are in their early development stages. Many solutions are promising, but in most cases, some form of adaptation or optimization is needed before application in specific products, and care must always be taken to ensure food safety. For instance, further research and innovation are required in the dynamic evolution of saltiness perception, consumer acceptance, the binding and migration of sodium, juiciness, microbiological safety, and the timing of salt addition during processing. Once implemented, these solutions will undoubtedly support food producers and food services in reducing sodium content and extend the application of the solutions to different foods.

Modification of NaCl structure as a sodium reduction strategy in meat products: An overview

Sodium chloride (NaCl) is an indispensable ingredient in meat products, but the consumption of high doses of sodium contained in their formulations may bring about negative health implications. The replacement of NaCl by other salts in meat products has been a technological challenge. Accordingly, this review highlights the importance of NaCl over other sodium and non‑sodium salts in the saltiness perception and proposes the use of reduced-size and shapes of NaCl to maximize saltiness perception, while using less NaCl dosages in meat products. However, the effect of matrix components (water, proteins and fats) on the final salty taste is of special consideration. To counteract the effect of the matrix components, two main routes of incorporation of different NaCl types in meat products are discussed: encapsulation and protection of NaCl by the hydrophobic component of the meat product. Given the limited number of publications using this potential strategy, more studies on the application of these technological strategies are required.

Substitution of sodium chloride by salt microspheres in dough: Effect on dough rheological properties

This research aimed to evaluate the impact of different salts on dough rheology parameters and gas cell development during dough preparation. Three types of salts in four concentrations each were used in dough preparation and following analyses were conducted: sodium content, salt structure analysis, dough hardness, dough stickiness and dough image analysis. The research showed how significantly (p < .05) the measured properties of dough can be influenced by the used type of salt, salt concentrations and fermentation time. The emphasis is put on salt substitutes of hollow microsphere salt (Hs) substitutes due to its special physical characteristics. The uniqueness of Hs physical characteristics was confirmed by electron microscope photomicrographs. The gained results are indicating that even low changes in salt concentration (0.40; 0.30; 0.25; and 0.15) make noticeable changes in dough characteristics. The usage of salt substitutes in food industry has been constantly growing and it makes the research a valuable source of information for further application of this salts.

PRACTICAL APPLICATIONS

The different salt types (table-Ts, sea-Ss and hollow microsphere-Hs) which were studied in our work differ just slightly. However, an important issue in choosing salt should also be the nutritive perspective, in particular low sodium content as a preventive measure against cardio-vascular diseases. Hs and Ss are therefore suitable alternatives to typical Ts.

The morphology of salt crystals affects the perception of saltiness

High intake of salt (NaCl) has been associated with risk of non-communicable diseases, including hypertension, cardiovascular disease and stroke. Several strategies for reducing salt in foods are under study, including the relation of crystal morphology on dissolution properties of salt in the mouth. The aim of this paper was to study the dissolution of salt crystals with different morphologies in artificial saliva and to correlate the findings with the perception of saltiness over time. The morphology of five commercial salts was analyzed by scanning electronic microscopy and micro-CT studies. Shape parameters of crystals were determined using images from an optical microscope. Crystal dissolution in artificial saliva was evaluated using video-microscopy and the perception of saltiness was evaluated using sensorial test of time-intensity at standardized sodium content. Salt morphology was correlated well with dissolution rate and certain time-intensity parameters (time to maximum intensity, intensity at maximum and increase angle). Non-cubic and agglomerated crystals, such as Kosher and Maldon salts, were dissolved faster (dissolution rate up to 3.8 times higher) and experienced maximum saltiness (up to 17% more) at shorter times (up to 40% less). Crystal morphology may be a variable to consider to achieve sodium reduction while maintaining salt intensity.