Abstract
Hydrophilic active ingredients play a crucial role in formulated consumer products, encompassing antioxidants, flavoring substances, and pharmaceuticals. Yet, their susceptibility to environmental factors, such as light, pH, temperature, and humidity, poses challenges to their stability and sustained release. Microencapsulation offers a promising avenue to address these challenges, facilitating stabilization, targeted delivery, and enhanced efficacy of hydrophilic actives. However, despite significant advancements in the field, microencapsulation of hydrophilic actives remains at the forefront of innovation. This is primarily due to the intrinsic characteristics of hydrophilic actives, including small molecular weight and thus high permeability through many microcarriers (e.g., shells), which often necessitate complex and costly technologies to be developed. Moreover, in light of escalating regulatory frameworks, the pursuit of biodegradable and other compliant materials suitable for the entrapment of hydrophilic ingredients is gaining momentum. These advancements aim to provide alternatives to currently used non-degradable synthetic polymer materials. Research is currently pushing towards meeting these regulatory constraints via cutting-edge technologies to engineer novel microscale delivery systems for hydrophilic active ingredients, including microcapsules, microspheres, microneedles, and micropatches. Although still in its infancy, this approach holds true potential for revolutionizing the future of formulated consumer goods.