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Ceramic nanotubes are a new type of material with a number of exciting properties. They are made from a single layer of ceramic material that is rolled into a tube with a diameter of only a few nanometers. This makes them extremely small and light, yet very strong and resistant to many forms of damage.
The structure of ceramic nanotubes makes them well-suited for use in a wide range of applications. For example, they can be used to construct lightweight but strong structures such as bridges and buildings. They can also be used to create nanoscale sensors, due to their high surface area-to-volume ratio.
Additionally, they are a promising material in the field of energy storage, as they can hold a large amount of energy in a small volume.
Ceramic nanotubes are also highly versatile. They can be tailored to meet specific requirements by varying their composition, size, and shape. This allows them to be used in a wide variety of applications, from medical implants to aerospace components.
The unique properties of ceramic nanotubes make them an exciting new material for scientists and engineers. With further research, they could become an important tool for a wide range of industries.
The Global Ceramic Nanotube market accounted for $XX Billion in 2023 and is anticipated to reach $XX Billion by 2030, registering a CAGR of XX% from 2024 to 2030.
The first implantations of Nano FortiFix, the only nanotechnology-designated titanium-surfaced pedicle screw, the Bioceramic Nanotube-Enhanced pedicle screw system, have been announced by Nanovis, an award-winning technology company with unique and differentiated nanotechnology surfaces for promoting bone growth and thwarting infection. Patent-protected bio-ceramic nanotube surface technology is used in the creation of Nano FortiFix pedicle screws.
“The nanotube arrays have been shown to increase and accelerate calcified extracellular matrix production in vitro,” the label specifically states, in contrast to other technologies.
This is why Nanovis’s bioceramic nanotubes were awarded a nanotechnology classification. Data on the development of calcified extracellular matrices by human osteoblasts and mesenchymal stem cells that are statistically considerably better than those on other surfaces are also included in the Nano Fortifix label.
When choosing a technology that is clearly differentiated for their patients seeking the finest care, surgeons and hospital contracting executives can make decisions with unusual clarity due to this label on nanotechnology and the associated comparative statistics.
As the first and only company to gain nanotechnology designation for titanium-surfaced pedicle screws, Nanovis was also the first to receive it for PEEK enhanced titanium interbodies.
They have been providing my patients with a fusion using 360˚ nanotechnology by combining Nano FortiFix pedicle screws with Nano FortiCore interbodies. The fact that nanotechnology is now not confined to the interbody space is interesting.
Surgeons and distributors who are astute and creative have given them constructive and encouraging feedback, which prepares them for the complete commercial launch of the open and MIS solutions. With a bioceramic nanotube surface that has established a well-understood regulatory mechanism, this is Nanovis’ fifth implant system to be cleared. With a stronger dedication than ever, Nanovis aims to lessen the discomfort and suffering caused by implant loosening.
They are appreciative of the doctors, scientists, and staff who have developed this potent blend of technologically advanced systems. Bioceramic nanotube enhanced Nano FortiCore interbodies and Nano FortiFix pedicle screws are being actively distributed by Nanovis.