Mostly 3D printed chemical synthesis robot.

Thanks to the current technology derived from the open-source world of 3D printers, it is conceivable to automate some laboratory activities remotely. In fact, simple operations, such as mixing liquids or solutions, stirring, heating and sampling to control the reaction course can be easily implemented. The idea of ​​automating the chemical laboratory would have immediate advantages, for example in terms of safety. The operators will be able to remotely control the machines and in case of handling dangerous material or accidents, there would only be damage to the hardware components. Many of the process parameters can also be read with low-cost probes and devices that can be easily interfaced with microprocessors. We include for example, but not limited to, temperature, pH, redox potential, electrochemical measurements in general or the use of probes for specific analytes. In this work we wish to present our liquid sampling station able to control up to 6 reagents and a temperature controlled chemical reactor. The workstation can be used graphically with an intuitive interface written in Python. The control program is structured to have modularity and contains a built-in programming language to control the interfaces.

Collection and Characterization of Wood Decay Fungal Strains for Developing Pure Mycelium Mats.

Wood decay fungi (WDF) seem to be particularly suitable for developing myco-materials due to their mycelial texture, ease of cultivation, and lack of sporification. This study focused on a collection of WDF strains that were later used to develop mycelium mats of leather-like materials. Twenty-one WDF strains were chosen based on the color, homogeneity, and consistency of the mycelia. The growth rate of each strain was measured. To improve the consistency and thickness of the mats, an exclusive method (newly patented) was developed. The obtained materials and the corresponding pure mycelia grown in liquid culture were analyzed by both thermogravimetric analysis (TGA) and scanning electron microscopy (SEM) to evaluate the principal components and texture. TGA provided a semi-quantitative indication on the mycelia and mat composition, but it was hardly able to discriminate differences in the production process (liquid culture versus patented method). SEM provided keen insight on the mycelial microstructure as well as that of the mat without considering the composition; however, it was able to determine the hyphae and porosity dimensions. Although not exhaustive, TGA and SEM are complementary methods that can be used to characterize fungal strains based on their desirable features for various applications in bio-based materials. Taking all of the results into account, the Fomitopsis iberica strain seems to be the most suitable for the development of leather-like materials.