The role of physiatry in regenerative medicine: the past, the present, and future challenges.

Historically, the foundation of physical medicine and rehabilitation training has provided the capabilities to optimize nonoperative treatments of a variety of musculoskeletal conditions, including acute and chronic muscle, tendon, ligament, and cartilage disorders. Such treatments include the use of nonsteroidal anti-inflammatory drugs (NSAIDs), therapeutic modalities (eg, thermal and manual therapies), and corticosteroid injections in conjunction with specific rehabilitation exercises. Although NSAIDs, modalities, and corticosteroids may be helpful for short-term pain reduction and early recovery of function, they do not typically reverse the structural changes associated with degenerative conditions and may contribute to worse long-term outcomes by potentially interfering with tissue healing. Regenerative interventions, including platelet-rich plasma and mesenchymal stem cells, recently have been used to treat refractory painful conditions such as chronic tendinopathies because of the potential of these interventions to facilitate tissue healing. The future development of these regenerative techniques will require a variety of conditions to be met, including determining the most appropriate procedures based on the disease being treated; establishing the optimal preparations of these regenerative techniques; and providing clinicians, patients, and regulatory agencies with high-quality evidence demonstrating the safety, effectiveness, and long-term results of these treatments. Clarification of current regulatory uncertainty, improved access for all patients, proper training for clinicians who incorporate these techniques into their practice, and determination of the most appropriate postinjection protocols will allow physical medicine and rehabilitation specialists to play a unique role in the long-term management of patients with musculoskeletal and sports injuries. This article will also address the role physiatrists should have in the inevitable growth of regenerative medicine applications.

Basic principles regarding strength, flexibility, and stability exercises.

Strength, flexibility, and stability are physiologic parameters associated with health-related physical fitness. Each of these domains affects health in general, the risk of injury, how an injury is treated, and performance in activities of daily living and sports. These domains are affected by individual phenotype, age, deconditioning, occupational activity, and formal exercise. Deficits or loss of strength, flexibility, and stability can be prevented or reduced with exercise programs. Normal muscle strength has been associated with general health benefits, increased life expectancy, psychological benefits, prevention of illness, and reduction of disability in older adults. Static flexibility programs have been shown to improve joint range of motion and tolerance to stretch but do not appear to reduce the risk of musculoskeletal injury and may impair muscle performance immediately after a static stretch. Dynamic flexibility, on the other hand, may enhance power and improve sports-specific performance. Stability training leads to improved balance and neuromuscular control, may prevent injury to the knee and ankle joints, and can be used for treatment of patients with low back pain.

The effects of blood and fat on Morse taper disassembly forces.

Biological debris between modular components using Morse tapers in hip arthroplasty can lead to weakening of the implant construct. We conducted a study to determine the effect of blood and fat within the taper interface. Tapers were divided into groups 1 (clean), 2 (surface covered with blood and fat), and 3 (blood and fat wiped off). Each taper was impacted and disassembled 5 times. There was a difference in mean disassembly force between pulls within group 2. Thus, blood and fat contamination can have a significant effect on the potential for disassembly.