Dysphagia or swallowing difficulty is a common morbidity experienced by those who have suffered a stroke or those undergone such treatments as head and neck surgeries. Dysphagic patients require special foods that are easier to swallow. Various technologies, including high‐pressure processing, high‐hydrodynamic pressure processing, pulsed electric field treatment, plasma processing, ultrasound‐assisted processing, and irradiation have been applied to modify food texture to make it more suitable for such patients. This review surveys the applications of these technologies for food texture modification of products made of meat, rice, starch, and carbohydrates, as well as fruits and vegetables. The review also attempts to categorize, via the use of such key characteristics as hardness and viscosity, texture‐modified foods into various dysphagia diet levels. Current and future trends of dysphagia food production, including the use of three‐dimensional food printing to reduce the design and fabrication time, to enhance the sensory characteristics, as well as to create visually attractive foods, are also mentioned.
Summary
Influences of pretreatment methods (washing, blanching, soaking in ethanol), drying methods (hot air‐drying, infrared‐drying, microwave‐drying) and drying temperature on selected characteristics of dietary fibre powder from orange pulp residues were investigated. Pretreatments improved the hydration properties, oil‐holding capacity and glucose dialysis retardation index, but led to losses of fibres, decreased α‐amylase inhibitory activity and aflatoxin B1 adsorption capacity. Hydration properties, oil‐holding capacity and glucose uptake depended on the structure and porosity of the fibre, while the ability to inhibit α‐amylase and AFB1 adsorption depended more on the content and molecular fingerprinting of the fibre. Drying condition did not significantly affect functional properties of the fibre, except for the ability to uptake glucose, inhibit α‐amylase and adsorb AFB1 (P ≤ 0.05). Hot air‐drying at 60 °C resulted in fibre with the highest ability to decrease the rate of glucose and AFB1 adsorption.
Summary
Although chemical‐free production processes of nanofibrillated cellulose (NFC) have been investigated, comparative studies on the effect of chemical and chemical‐free processes to produce NFCs are limited. Combined effect of either of these production routes and defibrillation condition has also never been studied. Here, thermally treated NFCs were produced through microfluidisation for 6–12 passes (ANFC6‐ANFC12), while TEMPO‐oxidised NFC (TONFC) was prepared at six passes. Proportion of nanocellulose, viscosity, Gʹ and Gʺ values increased with increased microfluidisation pass in the cases of ANFCs. ANFC12 exhibited gel‐like behaviour with strongest three‐dimensional network structure and required lowest concentration to enhance thin liquid foods into honey‐like consistency. TONFC needed to be added by as much as 8.5, 1.3 and 2.3 times the amount of ANFC12 to achieve the same consistency in thickened water, milk and soup, respectively. ANFC12 can also be well used as Pickering emulsifier due to its higher viscosity and gel‐like property.
Sugarcane bagasse
fly ash is industrial waste produced by incinerating
biomass to generate power and steam. The fly ash contains SiO2 and Al2O3, which can be used to prepare
aluminosilicate. This latter material exhibits high potential as an
adsorbent in various applications, including the livestock industry
where issues related to contamination of aflatoxins in animal feeds
need to be addressed; addition of adsorbents can help decrease the
concentration of aflatoxins during feed digestion. In this study,
the effect of the structure of silica prepared from sugarcane bagasse
fly ash on physicochemical properties and aflatoxin B1 (AFB1) adsorption
capability compared with that of bentonite was investigated. BPS-5,
Xerogel-5, MCM-41, and SBA-15 mesoporous silica supports were synthesized
using sodium silicate hydrate (Na2SiO3) from
sugarcane bagasse fly ash as a silica source. BPS-5, Xerogel-5, MCM-41,
and SBA-15 exhibited amorphous structures, while sodium silicate possessed
a crystalline structure. BPS-5 possessed larger pore size, pore volume,
and pore size distribution with a bimodal mesoporous structure, while
Xerogel-5 exhibited lower pore size and pore size distribution with
a unimodal mesoporous structure. BPS-5 with a negatively charged surface
exhibited the highest AFB1 adsorption capability compared with other
porous silica. However, the AFB1 adsorption capability of bentonite
was superior to those of all porous silica. Sufficient pore diameter
with high total pore volume as well as high intensity of acid sites
and negative charge on the surface of the adsorbent is required to
increase AFB1 adsorption in the in vitro gastrointestinal tract of
animals.
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