Abstract
Iron deficiency in children is a persistent global public health problem. This study evaluated the efficacy of an extruded rice matrix as a carrier for micronized dispersible ferric pyrophosphate (MDFP), aiming to increase iron bioavailability in traditional rice-based desserts formulated with cow's milk (CM) or soy soluble protein extract (SSPE). Four experimental diets were administered to the rats: (i) fortified with CM and MDFP incorporated into extruded rice; (ii) fortified with SSPE and MDFP incorporated into extruded rice; (iii) control with ferrous sulfate (AIN-93G); and (iv) a control with pure MDFP (AIN-93G). Both fortified groups showed significantly higher recovery of iron nutritional status (p < 0.05), demonstrating that the different liquid ingredients did not compromise iron bioavailability. Gene expression analyses of key iron metabolism proteins (DMT-1, DcytB, ferroportin, hephaestin, transferrin, and ferritin) confirmed that the extruded rice matrix increased the bioavailability of MDFP compared to the compound in its pure form (p < 0.05), possibly reducing aggregation and favoring direct interaction with intestinal absorption sites. Furthermore, the fortified formulations demonstrated satisfactory sensory acceptance among school-ageRd children. These results indicate that incorporating MDFP into an extruded rice is an effective and technologically viable strategy for developing fortified rice desserts, with potential application in programs to combat iron deficiency anemia, specially in schoo-laged children at poor regions worldwide. PRACTICAL APPLICATIONS: Rice desserts fortified with micronized ferric pyrophosphate (MDFP) in an extruded rice matrix effectively improved iron availability without diminish sensory acceptance by children. Hence, the technology here reported offers a practical, low-cost strategy for school feeding programs as well as for food industry to develop fortified products to fight against iron deficiency anemia.