Here’s a breakdown of the provided text, focusing on the key details about the device and its implications:
The Device’s Capabilities:
Sterile and Controlled Environment: The device can maintain sterile conditions and controlled temperatures, crucial for experiments involving bone and muscle cells.
Environmental Simulation: it can create specific environmental conditions by mixing carbon dioxide (CO2) and oxygen.
Mechanical Stimulation: The device provides mechanical stimulation,mimicking conditions in the human body. This allows in-vitro cells to react in ways that promote thier growth, strengthening, and development of responses.
Applications and Target Audience:
biomedicine Professionals: The device is intended for use by professionals in biomedicine.
Fabric/Tissue Engineering: It’s relevant for those working wiht fabrics (likely meaning tissue engineering).
Materials engineering, Physics, and Similar Fields: Specialists in materials engineering, physics, and related areas can also utilize the device.
Future Exploration: The text suggests there are other areas of application yet to be discovered.
Significance and Innovation:
advance in Engineering and Biomedicine: The development represents a notable step forward in both engineering and biomedicine.
National Ingenuity: It highlights the potential and ingenuity of Costa Rican researchers in conducting high-level scientific research and innovating in tissue engineering.
Intellectual Property and Problem Solving: Investment in national research projects fosters patent development, promotes intellectual property, and offers new solutions to real-world problems.
The Patent:
Regional Achievement: The device is considered an innovation not just for costa Rica but for the region.
Intellectual Property Protection: Protection has been sought through intellectual property mechanisms.
development Rights: TEC holds the right to develop the device until 2041.
Future Collaboration: The plan is to collaborate with medical device companies, research centers, universities, and other interested parties to further develop and utilize the device.
Challenges and Future Steps:
Costa Rican Regulations: Current regulations in Costa Rica do not permit experimentation with human cells, which has slowed scientific progress.
Clinical Application Alliances: To apply the technology in clinical settings, alliances with universities or companies will be necessary to continue and strengthen its development.
The Inventor:
Dr. Laura Rojas Rojas: A teacher and researcher at the School of Physics at the Technological of Costa Rica (TEC).
Educational Background: Holds a physics baccalaureate from the University of Costa Rica, a master’s in Nanotechnology from Finland, and a doctorate in engineering from the TEC-UCR Interuniversity Program.
Research Focus: Her career centers on interdisciplinary research in applied physics, including studying bacteria and proteins using spectroscopic methods and biomechanical stimulation.
Scientific Dissemination: Dr. Rojas is also involved in projects to engage children and young people in science.
In essence, the text describes a novel device developed by TEC researchers that simulates human body conditions for cell research, particularly for bone and muscle cells. It’s a significant innovation with broad applications, protected by a patent, and aims to advance tissue engineering and biomedicine, despite regulatory hurdles in Costa Rica.