ᱱᱚᱶᱟ ᱠᱷᱚᱱ ᱵᱟᱰᱟᱭ ᱟᱠᱟᱱᱟ ᱡᱮ ᱱᱚᱶᱟ ᱠᱚ ᱢᱩᱫᱽ ᱨᱮ ᱢᱤᱫ ᱦᱚᱲ ᱫᱚ ᱵᱟᱝ ᱵᱟᱰᱟᱭ ᱟᱠᱟᱱᱟ, ᱚᱱᱟ ᱫᱚ ᱵᱟᱝ ᱵᱟᱰᱟᱭ ᱟᱠᱟᱱ ᱠᱚ ᱫᱚ ᱵᱟᱝ ᱛᱟᱦᱮᱱ ᱠᱟᱱᱟ, ᱟᱨ ᱱᱚᱶᱟ ᱨᱮᱭᱟᱜ ᱵᱮᱵᱚᱦᱟᱨ ᱠᱚ ᱫᱚ ᱵᱟᱝ ᱛᱟᱦᱮᱱ ᱠᱟᱱᱟ.
ᱚᱱᱟ ᱠᱷᱟᱹᱛᱤᱨ ᱛᱮ, ᱱᱚᱶᱟ ᱫᱚ ᱟᱹᱰᱤ ᱠᱚᱢ ᱜᱮᱭᱟ, ᱚᱱᱟ ᱫᱚ ᱜᱞᱩᱠᱚᱡᱽ, ᱟᱨ ᱚᱱᱟ ᱨᱮᱭᱟᱜ ᱢᱟᱨᱟᱝ ᱮᱥᱮᱨ ᱠᱟᱱᱟ, ᱡᱟᱦᱟᱸ ᱨᱮ ᱵᱟᱹᱲᱛᱤ ᱫᱟᱲᱮ ᱠᱚ ᱠᱚᱢ ᱟᱠᱟᱱᱟ, ᱚᱱᱟ ᱛᱮ hiptions ᱠᱚ ᱫᱚ ᱟᱹᱰᱤ ᱠᱚᱢ ᱜᱮᱭᱟ, ᱚᱱᱟ ᱫᱚ https: ᱜᱡᱚᱴᱱᱟ ᱨᱮᱭᱟᱜ ᱰᱟᱴᱟ ᱫᱚ ᱥᱟᱯᱷᱟ ᱥᱛᱤᱛᱤ ᱨᱮ ᱧᱮᱞᱚᱜ ᱠᱟᱱᱟ ᱟᱨ ᱵᱟᱝ ᱵᱮᱥ ᱞᱮᱠᱟ ᱧᱮᱞᱚᱜ ᱠᱟᱱᱟ 27 ᱢᱮᱴᱨᱤᱠᱥ ᱨᱮᱭᱟᱜ ᱵᱮᱵᱷᱟᱨ᱾
In terms of materials, the bone cement used in the new generation of vertebroplasty systems has better biocompatibility and mechanical properties, can better combine with vertebral tissue, and provide stronger support. At the same time, these bone cements generate less heat during the curing process, reducing the risk of postoperative pain in patients.
Ease of operation is also an important indicator to distinguish different vertebroplasty systems. Modern systems often integrate advanced imaging technology, and doctors can observe the distribution of bone cement in real time during surgery, adjust the injection speed and amount, and ensure the effectiveness of the surgery. In addition, some systems are equipped with automatic injection devices, which improve surgical efficiency and reduce the operating burden of doctors.
In terms of safety, modern vertebroplasty systems reduce surgical risks through multiple safety protection mechanisms, such as pressure monitoring and temperature control. At the same time, these systems are also equipped with emergency response functions to deal with possible emergencies.
ᱠᱷᱟᱥ ᱠᱟᱛᱮ, ᱟᱭᱢᱟ ᱦᱚᱲ ᱠᱚ ᱞᱟᱹᱜᱤᱫ ᱵᱮᱵᱚᱦᱟᱨᱚᱜ ᱠᱟᱱ, ᱟᱨ ᱮᱴᱟᱜ ᱠᱚ ᱞᱟᱹᱜᱤᱫ, ᱟᱨ ᱮᱴᱟᱜ ᱠᱚ ᱫᱚ 5000/mintionshims ᱠᱚ ᱵᱮᱵᱚᱦᱟᱨ ᱮᱫᱟ, ᱡᱟᱦᱟᱸ ᱨᱮ ᱟᱹᱰᱤ ᱜᱟᱱ ᱵᱟᱹᱲᱤᱡ ᱠᱚ ᱢᱮᱱᱟᱜ-ᱟ ᱾