ZSFab marked the first clinical utilization of its recently launched InterConnect 3D-printed Ti Lumbar Interbody System.
The first procedures employed ZSFab’s digitally structured P-TLIF interbody cages designed with porous titanium. The implants, featuring a combination of triply periodic minimal surface (TPMS) and stochastic lattice structures, are designed to enhance osseointegration and promote faster, more robust fusion by mimicking the natural architecture of bone.
“ZSFab specializes in creating implants that better harmonize with the patient’s biomechanics by addressing issues like load distribution, stress on adjacent segments, and construct stability,” says David Ma, PhD, Director of Research and Development for ZSFab. “To help ensure lasting stability, our optimized designs also help promote beneficial elastic deformation within the lattice structures to induce mechanical stress, activating osteoblasts for new bone growth and achieving a more efficient fusion process.”
ZSFab marked the first clinical utilization of its recently launched InterConnect 3D-printed Ti Lumbar Interbody System.
The first procedures employed ZSFab’s digitally structured P-TLIF interbody cages designed with porous titanium. The implants, featuring a combination of triply periodic minimal surface (TPMS) and stochastic lattice...
ZSFab marked the first clinical utilization of its recently launched InterConnect 3D-printed Ti Lumbar Interbody System.
The first procedures employed ZSFab’s digitally structured P-TLIF interbody cages designed with porous titanium. The implants, featuring a combination of triply periodic minimal surface (TPMS) and stochastic lattice structures, are designed to enhance osseointegration and promote faster, more robust fusion by mimicking the natural architecture of bone.
“ZSFab specializes in creating implants that better harmonize with the patient’s biomechanics by addressing issues like load distribution, stress on adjacent segments, and construct stability,” says David Ma, PhD, Director of Research and Development for ZSFab. “To help ensure lasting stability, our optimized designs also help promote beneficial elastic deformation within the lattice structures to induce mechanical stress, activating osteoblasts for new bone growth and achieving a more efficient fusion process.”
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