Altered osteogenesis
Altered Osteogenesis: What You Need to Know
Altered osteogenesis is a process in which regenerative bones are formed from stem cells. It's most commonly used to repair and sustain bone fractures, and is critical in bone recovery. The process of altered osteogenesis is complex but can be explained in a few steps:
Step 1: Bone stem cell, also known as an osteoblast, is taken from the patient. These cells are taken from fat or soft tissue surrounding the fracture or injury. The osteoblast will be used to create new bone.
Step 2: An artificial matrix is developed. This matrix is made of biodegradable materials and designed to support the growth of the osteoblasts. It's made with nanofibers that are highly porous and allow for growth.
Step 3: The osteoblasts are put into the matrix and exposed to growth factors that will stimulate the bone growth. These include proteins, hormones, nutrients, and other biological stimuli.
Step 4: The osteoblasts are left to grow and form new bones. This process is designed to be as natural and minimally invasive as possible, mimicking the body's natural process of bone healing.
Altered osteogenesis has become an increasingly popular technique for bone reconstruction, especially among orthopedic surgeons looking to treat fractures and other injuries. The process is minimally invasive and has been proven to have over a 90% success rate when it comes to healing and recovering bones. The end result of the procedure is a healthier, more secure bone that will allow for the patient to have full use of the injured area faster.
Benefits of Altered Osteogenesis:
- Minimally invasive and quick
- High success rate (over 90%)
- Faster healing and recovery time
- Replacing damaged bones with healthy bones
Altered osteogenesis is becoming a more commonly used method for reconstructing damaged or lost bones. With its high success rate and minimal invasiveness, it has become the go-to technique for orthopedic surgeons looking to heal their patients.