Katherine Vanesa Hinostroza Quispe - Academia.edu (original) (raw)
Estudiante destacada de pregrado en Ingeniería Biomédica, con alta capacidad para la gestión y organización de proyectos, con excepcionales habilidades sociales e indicadores claros de liderazgo, proactividad, organización, asertividad y trabajo en equipo. Apasionada por la innovación y el desarrollo de servicios o tecnología disruptiva, en el Perú. Dispuesta a afrontar todo tipo de desafíos.
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Papers by Katherine Vanesa Hinostroza Quispe
Ticllacuri, V. et al. (2021). Design of Biomedical Soft Robotic Device for Lower Limbs Mechanical Muscle Rehabilitation and Electrochemical Monitoring under Reduced-Gravity Space Environment. In Proceedings of the ACM/IEEE URUCON Conference (pp. 227-231). Montevideo, Uruguay., 2021
Space travel is one of humanity's most fantastic aspirations. However, space is the most dangerou... more Space travel is one of humanity's most fantastic aspirations. However, space is the most dangerous environment due to extreme conditions. Reduced-gravity generates disuse muscle atrophy and impaired blood circulation in lower limbs. Therefore, this paper proposes a new biomedical soft robotic system to improve muscle development and promote blood circulation by applying energetically efficient mechanical stimulation to the soft tissues of the astronaut's lower limb and, additionally, to monitor their performance by cottonbased carbon nanotubes biosensors. The computational mechanical simulations performed show a maximum increase in energy optimisation of 89% and a maximum safety factor of 2.75. These preliminary results suggest an increase in the efficiency and safety of the soft robotic device.
Ticllacuri, V. et al. (2021). Design of Biomedical Soft Robotic Device for Lower Limbs Mechanical Muscle Rehabilitation and Electrochemical Monitoring under Reduced-Gravity Space Environment. In Proceedings of the ACM/IEEE URUCON Conference (pp. 227-231). Montevideo, Uruguay., 2021
Space travel is one of humanity's most fantastic aspirations. However, space is the most dangerou... more Space travel is one of humanity's most fantastic aspirations. However, space is the most dangerous environment due to extreme conditions. Reduced-gravity generates disuse muscle atrophy and impaired blood circulation in lower limbs. Therefore, this paper proposes a new biomedical soft robotic system to improve muscle development and promote blood circulation by applying energetically efficient mechanical stimulation to the soft tissues of the astronaut's lower limb and, additionally, to monitor their performance by cottonbased carbon nanotubes biosensors. The computational mechanical simulations performed show a maximum increase in energy optimisation of 89% and a maximum safety factor of 2.75. These preliminary results suggest an increase in the efficiency and safety of the soft robotic device.