One of the problems of aging is a lifetime accumulation of damage to knee and hip joints from work and recreation activities. While younger such damages may be temporarily painful yet the body has some spare capacity and sometimes the injured joints may return to a nearly normal condition with conservation at a somewhat lower maximum capacity. With advancing age however those injuries reappear at a level that can impact the ability to work for the hours in physical activities that would have been unchallenging when younger. Progress at growing new cartilage is an ongoing project taken up by many researchers. Millions of senior citizens could return to work if they wanted if their joints were renewed to a healthy status. That could be useful for people that need to work until they drop dead in the traces for socio-economic reasons.
Here is what A.I had to say about the research;
"AI Overview
Significant progress is being made in growing new cartilage, particularly with new biomaterials and regenerative techniques, though it remains a complex challenge for hip and knee joints. Recent advancements include using 3D scaffolds with stem cells, like at Washington University Orthopedics, and bio-integrated materials that stimulate the patient's own cells, such as the technology developed by Northwestern University. While these methods are currently in experimental stages for humans, they show promise for future joint preservation and could reduce the need for total joint replacements.
Current Research & Techniques
3D Scaffolds:Scientists are developing biodegradable, 3D scaffolds shaped like the joint to guide stem cells from fat or other sources to grow into new cartilage.
Biomaterials:New biomaterials are being engineered with bioactive signals to encourage the body's own cells to repair cartilage defects. These materials degrade as new cartilage forms, ensuring a quality repair.
Mesenchymal Stem Cells (MSCs):These cells are being explored for their ability to differentiate into cartilage cells (chondrocytes) and promote repair, often combined with other techniques like growth factors or scaffolding.
Single-Stage Techniques:Research is also focused on single-stage procedures that recycle the patient's own cartilage in the same surgery, such as the Reclaim trial at Mayo Clinic.
Promising Results
Animal Models:.Studies in sheep, which have joints similar to humans, have shown that these new materials and techniques can successfully regenerate new, high-quality cartilage to fill defects.
Potential for Joint Preservation:.The ultimate goal is to create lab-grown cartilage and other regenerative therapies that could preserve joints, prevent further damage, and potentially make total joint replacements unnecessary in the future.
Key Challenges
Complexity: Cartilage repair is a complex process, and effective treatments require a combination of approaches, including cell-based therapies, biologics, and physical therapy to be successful.
Natural Limits: In adults, articular cartilage has very limited natural regenerative capacity, making it difficult for the body to repair itself after injury. "
