Design of acoustic lenses for ultrasound focusing applications

Resumen

Ultrasound focusing has many applications in a wide range of fields. Focused ultrasound is one of the main tools used by doctors all over the world to obtain biomedical images of different kind of tissues non-invasively. In the past decades, high intensity focused ultrasound (HIFU) appeared as one of the fundamental techniques for cancer treatment through non-invasive thermal tumor ablation. In addition, focused ultrasonic waves are recently emerging as one of the main tools to treat brain diseases, with novel disruptive techniques such as blood-brain barrier opening or neuromodulation. In industrial environments, ultrasonic waves are widely employed as one of the primary methods for the non-destructive evaluation (NDE) of materials and structures, as acoustic waves are able to penetrate deep into objects otherwise opaque using optical techniques. In this sense, designing structures capable of focusing ultrasonic waves is of great interest and relevance for the scientific, the industrial, and the biomedical sectors. This thesis devises new designs of acoustic lenses capable of controlling the main parameters of the focused ultrasound beam, achieving different kinds of focusing profiles suitable for a wide variety of scenarios. In particular, Fresnel Zone Plates (FZPs), commonly used in optics, are designed and adapted to the ultrasound domain. A novel spatio-temporal modulation technique capable of controlling the ultrasound focus location in both time and space is presented, increasing the versatility of this kind of devices. New design techniques based on applying a binary sequence to FZPs are also demonstrated, such as Cantor fractal sequences or generalized M-bonacci sequences, which modify the focusing properties of the lens, including the number, location, and shape of the different acoustic foci. In addition, acoustic jets generated by liquid-filled spherical lenses are devised for near-field high resolution imaging, demonstrating their applicability in the ultrasound domain. It is demonstrated that, by changing the inner liquid of the spherical lens or by tuning the mixing ratio between two liquids, the main focal parameters of the ultrasonic jet can be accurately controlled. The proposed designs are validated using both numerical simulations and experimental measurements, paving the way for the use of these kind of structures in focused ultrasound applications.