"Bionics" Example Sentences
1. Bionics holds great potential for improving the lives of people with disabilities.
2. With advances in bionics and robotic prosthetics, amputees can regain near-normal mobility and functionality.
3. Researchers in bionics are developing artificial limbs that can be controlled by a person's thoughts.
4. Bionics aims to mimic biological systems using mechanical and electronic devices.
5. The bionic eye could one day restore sight to the blind.
6. Bionic limbs powered by the user's own muscles offer more natural movement and control.
7. Bionics researchers study biological systems to determine how they can be modeled using technology.
8. Advances in bionics allow some paralyzed people to operate computers and prosthetic limbs using only their thoughts.
9. Bionics combines biology, engineering, materials science and medicine to create technologies that mimic nature.
10. The Defense Advanced Research Projects Agency invests heavily in bionics research to develop advanced prosthetics for wounded veterans.
11.The field of bionics seeks to produce devices that mimic and augment natural functions of the human body.
12. Many athletes see enormous potential in bionics to enhance human performance through artificial means.
13. Bionics researchers aim to re-create the dexterity, sensitivity and finesse of natural biological systems.
14. The bionic ear could one day restore hearing to those with profound deafness.
15. Microbionics seeks to miniaturize bionic implants for medical devices.
16. Researchers hope that bionics could one day lead to bionic limbs that closely mimic the function of natural limbs.
17. Bionics focuses on developing the technology to interconnect humans and machines.
18. A bionic arm uses sensors, motors and a microprocessor to move like a natural arm.
19. In science fiction, bionics often refers to human augmentation through cybernetic implants.
20. Nanobionics seeks to create miniaturized devices that mimic functions of tissues and organs.
21. Bionic engineering research aims to copy the form and functionality of biological systems.
22. Advances in material science and miniaturization are driving rapid progress in the field of bionics.
23. A bionic pancreas uses sensors and a computer to monitor and regulate blood sugar levels.
24. Bionic solutions leverage biological insights to inform the design of artificial systems.
25. Cutting-edge research in bionics could one day lead to revolutionary medical treatments and technologies.
26. While still in its early stages, research in bionics has the potential to transform how we live and work.
27. Hard tissue bionics focuses on replicating and improving the functions of bones, teeth and cartilage.
28. Soft tissue bionics aims to replicate and augment the functions of muscles, skin and organs.
29. Bionics combines biology, electrical and mechanical engineering, and materials science.
30. Advances in robotics and artificial intelligence are driving rapid growth in the field of bionics.
31. Researchers in bionics are working to develop bionic organs that can replace failed biological organs.
32. A bionic spine uses sensors, electrodes and actuators to restore mobility in paralyzed patients.
33. Applications of bionics range from creating prosthetics and exoskeletons to developing artificial organs.
34. The field of biomimicry overlaps significantly with bionics in its goal of replicating biological systems.
35. Exoskeletons developed through bionics aim to augment human strength and endurance.
36. Researchers in bionics study the information processing and control systems found in biological systems.
37. Bionic solutions leverage biological mechanisms to inform the design of mechanical and electrical systems.
38. Bionics research aims to create machines that mimic not just the form, but also the function of biological systems.
39. Advances in bionics could one day revolutionize medicine through the creation of artificial tissues and organs.
40. A key goal of bionics is making artificial systems that are as sophisticated and adaptive as their biological counterparts.
41.The bionic man refers metaphorically to a human being enhanced through bionic implants and prosthetics.
42. Engineers working in bionics aim to recreate the sensory abilities of biological receptors.
43. Bionic systems mimic aspects of biological entities ranging from cells to complex organisms.
44. Researchers in bionics strive to replicate both the macro form and micro functions of biological systems.
45. A central challenge in bionics is developing materials that can interface safely and effectively with living tissue.
46. While still in its infancy, the field of bionics has the potential to revolutionize medicine and human capability.
47.Microbionics aims to develop microscopic bionic devices that could augment or replace cells and tissues inside the body.
48. Bionically engineered solutions must operate safely and seamlessly within complex biological environments.
49. Bionics interfaces aim to provide intuitive, secure connections between bionic devices and the human body.
50.The main goal of bionics is to leverage insights from biological systems to create artificial equivalents.
51. Advances in intelligent materials are driving progress in fields like neurobionics and soft bionics.
52. Researchers hope bionics will one day help restore functions in patients who have lost sensory, motor or cognitive abilities.
53. Bionics interfaces seek to establish secure, high-bandwidth connections between bionic devices and the peripheral or central nervous system.
54. Soft bionics focuses on developing artificial systems that replicate the properties and functions of soft biological tissues.
55. Neurobionics aims to develop technologies that can interface directly with the nervous system.
56. Researchers in bionics focus on developing artificial organs, limbs and sensory extensions that improve or extend human capabilities.
57. A key difference between bionics and robotics is the focus on replicating biological form and function in bionically engineered systems.
58. Bionically inspired solutions aim to retain many features found in biological systems, including adaptability, self-repair and energy efficiency.
59. Advances in bionics will likely have profound impacts on everything from medicine and health to human potential and capabilities.
60. While promising, further breakthroughs will be needed before bionic solutions match the sophistication and effectiveness of their biological counterparts.
Common Phases
1. Bionic implant - An artificial device implanted to replace or enhance a body part.
2. Bionic prosthesis - An artificial limb or device that incorporates bionic technology.
3. Bionic engineering - The application of engineering principles to create bionic systems.
4. Bionic solution - An approach or technology inspired by biological systems.
5. Bionically enhanced - Improved or augmented through bionic technology.
6. Bionic limb - An artificial limb with enhanced capabilities enabled by
bionics.
7. Bionically inspired - Drawn from or motivated by insights from biological systems.