How does the spinal implant scorpn 3d-printing cage adapt to the lumbar anatomical structure of different patients through its scalability?
Publish Time: 2025-01-20
In the field of spinal surgery, lumbar fusion is an effective means to treat a variety of lumbar diseases. The scorpn 3d-printing cage, as a key implant for this operation, successfully solves the problem that traditional fusion cages are difficult to adapt to the lumbar anatomical structure of different patients with its unique scalability design.
Titanium alloy, as a lightweight, high-strength and biocompatible material, has been widely used in spinal implants. The scorpn 3d-printing cage utilizes these characteristics of titanium alloys and realizes the scalability of the fusion cage through precise design and manufacturing processes.
The scalability of the fusion cage is mainly reflected in its structural design. The fusion cage is usually composed of two upper and lower titanium alloy shells, which are filled with materials that promote bone fusion. Between the two shells, a precise mechanical connection mechanism is designed, so that after implantation, the fusion cage can expand or contract to a certain extent according to the patient's lumbar anatomical structure and surgical needs.
During the operation, the doctor will first accurately measure the key parameters such as the height, width and anterior-posterior diameter of the lumbar intervertebral space based on the patient's lumbar CT or MRI imaging data. Then, according to these parameters, the appropriate scorpn 3d-printing cage is selected and accurately placed and adjusted during the operation.
After the fusion device is implanted into the lumbar intervertebral space, the doctor can operate the adjustment mechanism on the fusion device to gradually expand or contract it until it perfectly matches the patient's lumbar anatomical structure. This precise matching can not only ensure the stability of the fusion device in the lumbar intervertebral space, but also minimize the damage to the surrounding tissues during the operation and promote rapid recovery after surgery.
In addition, the scorpn 3d-printing cage's scalable design also provides more possibilities for its application in the treatment of complex lumbar diseases. For example, in operations such as lumbar spondylolisthesis and lumbar spinal stenosis, due to the complexity of the lumbar anatomical structure, traditional fusion devices are often difficult to achieve ideal fusion effects. The scorpn 3d-printing cage can be personalized according to the patient's specific situation, thereby ensuring the success rate of the operation and the patient's rehabilitation effect.
In summary, the Scorpn 3D-printing cage successfully solves the problem that traditional fusion cages are difficult to adapt to the anatomical structure of the lumbar spine of different patients through its unique scalable design. This innovative design not only improves the accuracy and safety of the surgery, but also provides patients with better rehabilitation effects and a higher quality of life.
