Magnolol attenuates inflammatory pain by inhibiting sodium currents in mouse dorsal root ganglion neurons.

Voltage-gated sodium channels are currently recognized as one of the targets of analgesics. Magnolol (Mag), an active component isolated from Magnolia officinalis, has been reported to exhibit analgesic effects. The objective of this study was to investigate whether the analgesic effect of Mag was associated with blocking Na+ channels. Inflammatory pain was induced by the injection of carrageenan into the hind paw of mice. Mag was administered orally. Mechanical hyperanalgesia was evaluated by using von Frey filaments. Na+ currents and neuronal excitability in acutely isolated mouse dorsal root ganglion (DRG) neurons were recorded with the whole-cell patch clamp technique. Results showed that Mag (10 ~ 40 mg/kg) dose-dependently inhibited the paw edema and reduced mechanical pain in the inflammatory animal model. Injection of carrageenan significantly increased the amplitudes of TTX-sensitive and TTX-resistant Na+ currents. Compared with the carrageenan group, Mag inhibited the upregulation of two types of Na+ currents induced by carrageenan in a dose-dependent manner. Mag 40 mg/kg shifted the inactivation curves of two types of Na+ currents to hyperpolarization and returned to normal animal level without changing their activation curves. Mag 40 mg/kg significantly reduced the percentage of cells firing multiple spikes and inhibited the neuronal hyperexcitability induced by carrageenan. Our data suggest that the analgesic effect of Mag may be associated with a decreased neuronal excitability by blocking Na+ current.

Magnolol inhibits sodium currents in freshly isolated mouse dorsal root ganglion neurons.

The voltage-gated sodium channel (VGSC) currents in dorsal root ganglion (DRG) neurons contain mainly TTX-sensitive (TTX-S) and TTX-resistant (TTX-R) Na+ currents. Magnolol (Mag), a hydroxylated biphenyl compound isolated from the bark of Magnolia officinalis, has been well documented to exhibit analgesic effects, but its mechanism is not yet fully understood. The aim of the present study was to investigate whether the antinociceptive effects of Mag is through inhibition of Na+ currents. Na+ currents in freshly isolated mouse DRG neurons were recorded with the whole cell patch clamp technique. Results showed that Mag inhibited TTX-S and TTX-R Na+ currents in a concentration-dependent manner. The IC50 values for block of TTX-S and TTX-R Na+ currents were 9.4 and 7.0 µmol/L, respectively. Therefore, TTX-R Na+ current was more susceptible to Mag than TTX-S Na+ current. For TTX-S Na+ channel, 10 µmol/L Mag shifted the steady state inactivation curve toward more negative by 9.8 mV, without affecting the activation curve. For TTX-R Na+ channel, 7 µmol/L Mag shifted the steady state activation and inactivation curves toward more positive and negative potentials by 6.5 and 11.7 mV, respectively. In addition, Mag significantly postponed recovery of TTX-S and TTX-R Na+ currents from inactivation, and produced frequency dependent blocks of both subtypes of Na+ currents. These results suggest that the inhibitory effects of Mag on Na+ channels may contribute to its analgesic effect.

Characteristics of voltage-gated potassium currents in monosodium urate induced gouty arthritis in mice.

OBJECTIVE: To evaluate the role of K+ channels in pain following gouty arthritis. METHODS: The model of acute gouty arthritis was induced by monosodium urate (MSU) in mice. The swelling degree was determined by measuring the circumference of the ankle joint. Mechanical hyperalgesia was detected by von Frey filaments. Two types of K+ currents, A-type currents (IA) and delayed rectifier currents (IK), were recorded in dorsal root ganglion (DRG) neurons using patch-clamp techniques. RESULTS: The swelling degree reached its maximum at 10 h and the minimum pain threshold was maintained between 8 and 48 h after MSU treatment in mice. The amplitudes of IA and IK in DRG neurons were moderately increased on day 1 after MSU treatment, and then, they were gradually decreased with times and reached their minimums on day 4 (for IA) or 5 (for IK). Compared with control group, the activation curve of IA was significantly shifted to more positive potential and the recovery time of IA from inactivation was markedly prolonged, but inactivation and frequency dependence of IA appeared unaffected in MSU-treated group. Additionally, no change was observed in the activation curve of IK after MSU treatment. The excitability was significantly higher in the MSU group than in the control group. CONCLUSIONS: MSU-induced gout pain may be related to the hyperexcitability of DRG neurons elicited by decreasing K+ currents.

The Distributions of Voltage-Gated K+ current Subtypes in Different Cell Sizes from Adult Mouse Dorsal Root Ganglia.

Voltage-gated K+ (KV) currents play a crucial role in regulating pain by controlling neuronal excitability, and are divided into transient A-type currents (IA) and delayed rectifier currents (IK). The dorsal root ganglion (DRG) neurons are heterogeneous and the subtypes of KV currents display different levels in distinct cell sizes. To observe correlations of the subtypes of KV currents with DRG cell sizes, KV currents were recorded by whole-cell patch clamp in freshly isolated mouse DRG neurons. Results showed that IA occupied a high proportion in KV currents in medium- and large-diameter DRG neurons, whereas IK possessed a larger proportion of KV currents in small-diameter DRG neurons. A lower correlation was found between the proportion of IA or IK in KV currents and cell sizes. These data suggest that IA channels are mainly expressed in medium and large cells and IK channels are predominantly expressed in small cells.