The Anti-Inflammatory Action of Pulsed Radiofrequency-A Hypothesis and Potential Applications.

In 2013, it was reported that pulsed radiofrequency (PRF) could be applied to obtain a systemic anti-inflammatory effect. Patients with chronic pain and patients with an inflammatory condition from other disciplines could potentially profit from this finding. At that time, intravenous application was used, but since then, it became clear that it could be applied transcutaneously as well. This procedure was named RedoxPRF. This can be used both for regional and for systemic application. Recently, the basic element of the mode of action has been clarified from the analysis of the effects of PRF on a standard model of muscle injury in rats. The objective of this paper is to present a hypothesis on the mode of action of RedoxPRF now that the basic mechanism has become known. Cell stress causes an increased production of free radicals, disturbing the redox equilibrium, causing oxidative stress (OS) either directly or secondarily by other types of stress. Eventually, OS causes inflammation and an increased sympathetic (nervous) system activity. In the acute form, this leads to immune paralysis; in the chronic form, to immune tolerance and chronic inflammation. It is hypothesized that RedoxPRF causes a reduction of free radicals by a recombination of radical pairs. For systemic application, the target cells are the intravascular immune cells that pass through an activated area as on an assembly line. Hypothesis conclusions: 1. RedoxPRF treatment works selectively on OS. It has the unique position of having a point of engagement at the most upstream level of the train of events. 2. RedoxPRF has the potential of being a useful tool in the treatment of inflammatory diseases and possibly of stage 4 cancer. 3. In the treatment of chronic pain, RedoxPRF is an entirely new method because it is different from ablation as well as from stimulation. We propose the term "functional restoration". 4. Controlled studies must be conducted to develop this promising new field in medicine further.

Effects of Pulsed Radiofrequency on a Standard Model of Muscle Injury in Rats.

BACKGROUND: Pulsed radiofrequency (PRF) affects animal and plant tissues; however, the mechanism has not been defined. We hypothesized that the magnetic field produced by PRF exerts its effects by the magnetic sensitivity of transitions between spin states -a spin-correlated radical-pair mechanism (SCRPM)- which, in turn, affects the rates of chemical reactions with participation of paramagnetic species. OBJECTIVES: This study aimed to evaluate the effects of PRF on redox equilibrium and inflammatory status in a standard model of muscle injury in rats. METHODS: Twenty-four animals were subjected to a single impact trauma to the left quadriceps and the groups exposed and not exposed to PRF were compared. On day 7 of the experiment, the animals were killed and the quadriceps muscles were removed for analysis. RESULTS: There was a significant increase in the concentration of thiobarbituric acid reactive substances (TBARS) in the muscle of animals from the trauma group (+233%), and this increase was eliminated by PRF administration. Superoxide dismutase (SOD) activity was increased (+411%) by trauma, resulting in significantly higher consumption of catalase (-72%), while PRF administration brought both of these markers back to levels close to those of the control group. Trauma induced considerable production of interleukins TNF-α, IL-1ß, and IL-6 (+215%, +262%, and +326% vs. controls, respectively) and these effects were also significantly reduced by PRF administration. CONCLUSIONS: In total, PRF inhibits oxidative stress and restores antioxidant enzymes to control levels and may block production of inflammatory markers in muscles of animals subjected to trauma. By modulating redox equilibrium, PRF treatment might block production of noxious mediators involved in development of trauma-induced injury.

[Experimental model of liver oxidative damage induction in rats by halothane]. / Modelo experimental de indução de lesão oxidativa hepática em ratos por halotano.

BACKGROUND: The anesthetic halothane can be reductively metabolized to reactives intermediates that may initiate lipid peroxidation accompanied by hepatic injury. Hypoxia and phenobarbital pretreatment in rats increases metabolism of halothane, the oxidative stress, cause liver antioxidant enzymes changes and tissue damage. AIMS: We investigated the effect of halothane on hepatic lipid peroxidation and on hepatic histology after increases reductive metabolism of halothane caused by hypoxia and phenobarbital pretreatment. METHODS: Twenty-five male wistar rats were divided in five equals groups: CO (Control), HO14 (Halothane/Hypoxia), F (fenobarbital alone), O14 (Hypoxia alone) and H (Halothane alone). After 24 hours the rats were killed, their livers removed to determine chemoluminescence, thiobarbituric acid-reactive substances, catalase, superoxide dismutase, and blood samples were taken to determine AST and ALT. The histopathologic evaluation was performed with hematoxylin and eosin staining. Histopathologic scores are presented as 25th-75th percentile/range values and median +/- range. RESULTS/CONCLUSION: Halothane-hypoxic exposure resulted in a significant changes in the activities of antioxidant enzymes, and induced hepatic lipoperoxidation. Moreover it resulted in histopathologic liver injury as well as significant increase of serum activity of AST and ALT.

Modelo experimental de indução de lesão oxidativa hepática em ratos por halotano / Experimental model of liver oxidative damage induction in rats by halothane

RACIONAL: O anestésico halotano pode ser metabolizado redutivamente a intermediários reativos que podem iniciar a lipoperoxidação acompanhada de injúria hepática. O tratamento prévio com hipóxia e fenobarbital em ratos aumenta o metabolismo do halotano e o estresse oxidativo e causa mudanças nas enzimas antioxidantes no fígado com dano hepático. MÉTODOS: Investigou-se o efeito do halotano na lipoperoxidação e histologia hepáticas após o aumento do metabolismo redutor do halotano induzido pela hipóxia e fenobarbital. Vinte e cinco ratos machos Wistar foram divididos em cinco grupos: Co (controle), HO14 (Halotano/Hipóxia), F (Fenobarbital), O14 (Hipóxia) e H (Halotano). Após 24 horas os ratos foram sacrificados, seus fígados foram retirados para determinar quimiluminescência, substâncias que reagem ao ácido tiobarbitúrico, enzimas antioxidantes, superóxido dismutase, catalase e amostras de sangue foram tomadas para determinar AST e a ALT. A avaliação histopatológica foi realizada pela técnica de hematoxilina-eosina. Os dados da avaliação histológica foram apresentados através de mediana e amplitude entre quartis. RESULTADOS E CONCLUSÕES: A exposição ao halotano/hipóxia causou lipoperoxidação hepática e mudanças significativas na atividade das enzimas antioxidantes. Além disso, provocou lesão histopatológica do fígado e aumento significativo dos níveis plasmáticos de AST e ALT.

BACKGROUND: The anesthetic halothane can be reductively metabolized to reactives intermediates that may initiate lipid peroxidation accompanied by hepatic injury. Hypoxia and phenobarbital pretreatment in rats increases metabolism of halothane, the oxidative stress, cause liver antioxidant enzymes changes and tissue damage. AIMS: We investigated the effect of halothane on hepatic lipid peroxidation and on hepatic histology after increases reductive metabolism of halothane caused by hypoxia and phenobarbital pretreatment. METHODS: Twenty-five male wistar rats were divided in five equals groups: CO (Control), HO14 (Halothane/Hypoxia), F (fenobarbital alone), O14 (Hypoxia alone) and H (Halothane alone). After 24 hours the rats were killed, their livers removed to determine chemoluminescence, thiobarbituric acid-reactive substances, catalase, superoxide dismutase, and blood samples were taken to determine AST and ALT. The histopathologic evaluation was performed with hematoxylin and eosin staining. Histopathologic scores are presented as 25th-75th percentile/range values and median ± range. RESULTS/CONCLUSION: Halothane-hypoxic exposure resulted in a significant changes in the activities of antioxidant enzymes, and induced hepatic lipoperoxidation. Moreover it resulted in histopathologic liver injury as well as significant increase of serum activity of AST and ALT.