The Treatment of Joint Pain with Intra-articular Pulsed Radiofrequency

A study is carried out of the spatial distribution and time dependence of electric and thermal fields in the tissue around a radiofrequency (RF) electrode used in pain therapy. Finite-element calculation of the fields is performed, and results are compared with ex vivo tissue data. Field predictions are made for continuous and for pulsed RF applications. A special RF cannula electrode is constructed with both macro and micro thermocouple sensors to measure both average and rapid, transitory temperature effects. Temperatures and impedances are recorded in liver and egg-white models using signal outputs from a commercially available RF lesion generator. These data are compared with the results of finite-element calculations using electric field equations and the bio-heat equation. Average and pulsatory temperatures at the RF electrode are measured. Rapid temperature spikes during pulsed RF bursts are observed. These data compared well with theoretical calculations using known electrical and thermal tissue parameters. Continuous RF lesioning causes heat destruction of neurons. Pulsed RF lesioning (PRFL) produces heat bursts with temperatures in the range associated with destructive heat lesions. PRFL also produces very high electric fields that may be capable of disrupting neuronal membranes and function. Finite-element calculations agree substantially with the measured data, giving confidence to their predictions of fields around the RF electrode.

To review the mechanisms for the production of pain in knee osteoarthritis. Nociception is produced by stimulation of unmyelinated and small myelinated fibers in the joint and surrounding tissue. To produce pain, the stimuli must be either repeated or spatially clustered. When they reach the spinal cord, stimuli are subject to two inhibitory effectors: interneurons and descending central neurons. Inflammation lowers the threshold for nociception. In the joint, tissues containing nociceptors include primarily the joint capsule, ligaments, synovium, bone, and in the knee, the outer edge of the menisci. Nociceptive stimuli are likely to emanate from one or more of these locations in people with knee pain. This review does not cover psychological aspects of pain. Nociception in the knee is complex, and the nociceptive stimuli are related to but fundamentally different from those producing cartilage loss. Better appreciation for these processes will facilitate the development of new treatments.