A new method for synthesis of gelled microspheres that can homogeneously carry biologically active compounds has been developed. The microspheres become of special interest for their use by themselves or as a vehicle. Unlike other common excipients, these microspheres are resistant to enzymatic degradation, stable, biocompatible, safe, mucoadhesive, and allow a controlled and sustained release of active compounds.
Every year a wide variety of therapeutic agents are developed and, despite the fast progress in this area, some frequent problems associated to drug development such as poor solubility, high potency, unpleasant organoleptic properties, low stability or inadequate pharmaceutic form, are still not fully resolved.
Nowadays, other sustained release pharmaceutic forms exist (liposomes, bicelles, nanoparticles or microparticles). However, they are intermediate products and require a subsequent vehiculation to constitute the final pharmaceutical form, increasing the production costs. In this sense, there is a need of new transport and delivery methods that are safer, more efficient, simpler, and allow a controlled and sustained release of the drug.
In order to meet this market need, a new method for the synthesis of gelled microspheres has been developed. The microspheres can be used by themselves as therapeutic agents or cosmetics, or to vehiculate bioactive compounds. The microspheres stand out due to their biocompatibility, stability, specificity, even encapsulation, and allow the incorporation of a wide range of biologically active compounds (pharmaceutical, nutraceutical, cosmetics…) for a subsequent sustained release, completely maintaining biological activity.
The production of these microspheres consists of an innovation on the emulsification / internal gelation method wherein the aqueous phase contains an alginate salt or derivative therein, a water-soluble polysaccharide, a calcium salt, and optionally the biologically active compound; the oily phase is made of a mixture of several oils. The aqueous phase is added to the oily phase to form a water-in-oil emulsion, to which is added a fat-soluble acid to generate a dispersion of microparticles.
The resulting microparticles show enhanced organoleptic properties and palatability, an increase of the mucoadhesivity and offer protection to the encapsulated compound from inactivation by external agents.
ADVANTAGES AND BENEFITS
Current development status
Laboratory prototypes
Applications
Health
Drug delivery
Cosmetics
Biotechnology
Desired business relationship
Patent licensing
Granada University is one of the most important universities of Spain. The main goal is to transfer technology that our research groups, more than 500, are developing to the industries and companies which are able to take profit from them. It is a general University so Research and Development are offered in different fields like Health Science and Technology, Physics, Chemistry and Mathematics, Environment and Natural Resources, Biotechnology, Information and Communication Technologies, Social, Economic and Legal Sciences....
We hope you find technologies of your interest which will allow us working together in the near future.
Create your free account to connect with Universidad de Granada and thousands of other innovative organizations and professionals worldwide
Send a request for information
to Universidad de Granada
Technology Offers on Innoget are directly posted
and managed by its members as well as evaluation of requests for information. Innoget is the trusted open innovation and science network aimed at directly connect industry needs with professionals online.
Need help requesting additional information or have questions regarding this Technology Offer?
Contact Innoget support
