Beer brewing waste could help bone regeneration

(Nanowerk News) As a result of a research study conducted by researchers from the Centre for Biomedical Technology of Universidad Politécnica de Madrid (UPM) and the Institute of Materials Science and the Institute of Catalysis and Petrochemistry of Consejo Superior de Investigaciones Científicas (CSIC), all in collaboration with the Mahou and Createch Co., have developed biocompatible materials to be used as support for bone regeneration from the food industry waste, mainly bagasse (residue) from beer brewing. These new materials can be considered as an alternative to the prosthesis made from processed sheep bones or synthetic materials which are more expensive and more harmful to the environment ("Preparation, characterization and in vitro osteoblast growth of waste-derived biomaterials").
The waste obtained from the beer brewing process contains the main chemical components found in bones (phosphorus, calcium, magnesium and silica), that after undergoing modification processes, this waste can be used as support or scaffold to promote bone regeneration for medical applications such as coating prosthesis or bone grafts. The waste usage from the food industry is a great source of raw material recovery rich in chemical diversity, and simultaneously it can reduce the impact generated by the accumulation of waste in the environment
Mouse osteoblasts growing over 3D matrixes developed from food industry waste
Mouse osteoblasts growing over 3D matrixes developed from food industry waste.
So far, the usage of synthetic materials as bone substitutes is the most used therapy for treatment of bone diseases. The therapeutic strategies are based on stiff porous scaffolds made of biocompatible materials to be used as molds. These molds will provide mechanical stability and will promote the growth of the new bone tissue that helps its regeneration.
The synthetic calcium phosphates are frequently used as matrices and coatings for orthopedic implants because of their resemblance to the composition of a bone. These materials are often obtained through chemical reactions of complex synthesis that use toxic reagents (for example benzoyl peroxides benzene and aniline) and calcinations at high temperatures close to 1500 ° C. As a result of this process, we obtain bioceramics but just after adding silicon through the hydrolysis of TEOS and sintering over 1,100 ° C.
The billing of the brewing sector was €2,990 million in 2012, almost covering completely the total production of malt and hops in the country. The most common products in the production process are bagasse, yeast and malt dried residues.
Bagasse is constituted by organic waste from malt, never experiencing modifications afterwards. This is the reason why bagasse is considered a subproduct, commonly used to make fodder and it is inexpensive. The treatments applied to bagasse residue in this research give as a result a new material rich in silicon, phosphorus, calcium and magnesium. The analysis of this new material shows the presence of interconnected pores of between 50 and 500 microns in diameter which is similar to the porosity of cancellous bone. All this would facilitate the complete vascularization after the bone implant.
A first approach using cell cultures has established the biocompatibility of the materials by analyzing the cell viability of cultured osteoblasts in the presence of powder materials components. Then, after compacting and sintering the materials that became 3D solid matrixes, the ability of bone-like cells to adhere to these materials were analyzed. Also, researchers analyzed how these materials proliferate and distinguish from the mature bone cells which are able to express typical markers of bone phenotype such as alkaline phosphatase and to conduct the collagen synthesis and mineralization of the extracellular matrix.
This research, developed by UPM and CSIC in collaboration with the Mahou and Cratech Co. within the framework of the INPACTO project funded by MINECO, reveals the value of these materials derived from the food industry for their conversion into support or scaffolds suitable for bone regeneration.
Source: Universidad Politécnica de Madrid