The Scrum approach to software development

Agile methodologies have become the standard approach to software development. The most popular and used one is Scrum. Scrum is a very simple and flexible framework that respond to unpredictability in a really effective way. However, his implementation must be correct, and since Scrum tells you what to do but not how to do it, this is not trivial. In this thesis I will describe the Scrum Framework, how to implement it and a tool that can help to do this. The thesis is divided into three parts. The first part is called Scrum. Here I will introduce the framework itself, its key concepts and its components. In Scrum there are three components: roles, meetings and artifacts. Each of these is meant to accomplish a series of specific tasks. After describing the “what to do”, in the second part, Best Practices, I will focus on the “how to do it”. For example, how to decide which items should be included in the next sprint, how to estimate tasks, and how should the team workspace be. Finally, in the third part called Tools, I will introduce Visual Studio Online, a cloud service from Microsoft that offers Git and TFVC repositories and the opportunity to manage projects with Scrum. == Versione italiana: I metodi Agile sono diventati l’approccio standard per lo sviluppo di software. Il più famoso ed utilizzato è Scrum. Scrum è un framework molto semplice e flessibile che risponde ai cambiamenti in una maniera molto efficace. La sua implementazione deve però essere corretta, e visto che Scrum ci dice cosa fare ma non come farlo, questo non risulta essere immediato. In questa tesi descriverò Scrum, come implementarlo ed uno strumento che ci può aiutare a farlo. La tesi è divisa in tre parti. La prima parte è chiamata Scrum. Qui introdurrò il framework, i suoi concetti base e le sue componenti. In Scrum ci sono tre componenti: i ruoli, i meeting e gli artifact. Ognuno di questi è studiato per svolgere una serie di compiti specifici. Dopo aver descritto il “cosa fare”, nella seconda parte, Best Practices, mi concentrerò sul “come farlo”. Ad esempio, come decidere quali oggetti includere nella prossima sprint, come stimare ogni task e come dovrebbe essere il luogo di lavoro del team. Infine, nella terza parte chiamata Tools, introdurrò Visual Studio Online, un servizio cloud della Microsoft che offre repository Git e TFVC e l’opportunità di gestire un progetto con Scrum.

Fabrication of 2D and 3D microelectrode arrays for amperometric dopamine sensing: towards a metal free approach to bioelectronics

Dopamine is a neurotransmitter which has a role in several psychiatric and neurological disorders. In-vivo detection of its concentration at the microscopic scale would benefit the study of these conditions and help in the development of therapies. The ideal sensor would be biocompatible, able to probe concentrations in microscopic volumes and sensitive to the small physiological concentrations of this molecule (10 nM - 1 μM). The ease of oxidation of dopamine makes it possible to detect it by electrochemical methods. An additional requirement in this kind of experiments when run in water, though, is to have a large potential window inside which no redox reactions with water take place. A promising class of materials which are being explored is the one of pyrolyzed photoresists. Photoresists can be lithographically patterned with micrometric resolution and after pyrolysis leave a glassy carbon material which is conductive, biocompatible and has a large electrochemical water window. In this work I developed a fabrication procedure for microelectrode arrays with three dimensional electrodes, making the whole device using just a negative photoresist called SU8. Making 3D electrodes could be a way to enhance the sensitivity of the electrodes without occupying a bigger footprint on the device. I characterized the electrical, morphological, and electrochemical properties of these electrodes, in particular their sensitivity to dopamine. I also fabricated and tested a two dimensional device for comparison. The three dimensional devices fabricated showed inferior properties to their two dimensional counter parts. I found a possible explanation and suggested some ways in which the fabrication could be improved.