Relationship between Laser Intensity at the Peripheral Nerve and Inhibitory Effect of Percutaneous Photobiomodulation on Neuronal Firing in a Rat Spinal Dorsal Horn.

Photobiomodulation is an effective treatment for pain. We previously reported that the direct laser irradiation of the exposed sciatic nerve inhibited firing in the rat spinal dorsal horn evoked by mechanical stimulation, corresponding to the noxious stimulus. However, percutaneous laser irradiation is used in clinical practice, and it is unclear whether it can inhibit the firing of the dorsal horn. In this study, we investigated whether the percutaneous laser irradiation of the sciatic nerve inhibits firing. Electrodes were inserted into the lamina II of the dorsal horn, and mechanical stimulation was applied using von Frey filaments (vFFs) with both pre and post laser irradiation. Our findings show that percutaneous laser irradiation inhibited 26.0 g vFF-evoked firing, which corresponded to the noxious stimulus, but did not inhibit 0.6 g and 8.0 g vFF-evoked firing. The post- (15 min after) and pre-irradiation firing ratios were almost the same as those for direct and percutaneous irradiation. A photodiode sensor implanted in the sciatic nerve showed that the power density reaching the sciatic nerve percutaneously was attenuated to approximately 10% of that on the skin. The relationship between the laser intensity reaching the nerve and its effect could be potentially useful for a more appropriate setting of laser conditions in clinical practice.

Room-temperature Ia3̄d phase obtained for the binary mixture containing different sizes of siloxanyl terminals.

Two types of binary mixtures were examined to optimize the siloxanyl fraction by filling the gap between the two Cub-phase-forming molecules with di- and tri-siloxanyl terminals. Adding siloxanyl to the disiloxanyl system largely inhibited crystallization, increasing the stability at room temperature of the meta-stable Ia3̄d phase obtained by cooling from the high-temperature phase. The effect was prominent for the mixtures containing both di- and tri-siloxanyl compounds. The most prominent result was obtained for the 50 : 50 mixture; the Ia3̄d phase was quite stable and survived at room temperature after more than 1 year, as if it were like a thermodynamically stable phase.

Near-Infrared Photobiomodulation of the Peripheral Nerve Inhibits the Neuronal Firing in a Rat Spinal Dorsal Horn Evoked by Mechanical Stimulation.

Photobiomodulation has analgesic effects via inhibition of nerve activity, but few reports have examined the effects on the spinal dorsal horn, the entry point for nociceptive information in the central nervous system. In this study, we evaluated the effects of laser irradiation of peripheral nerve axons, which are conduction pathways for nociceptive stimuli, on the neuronal firing in lamina II of the spinal dorsal horn of a rat evoked by mechanical stimulation with von Frey filaments (vFF). In order to record neuronal firing, electrodes were inserted into lamina II of the exposed rat spinal dorsal horn. The exposed sciatic nerve axons were irradiated with an 808 nm laser. The 26.0 g vFF-evoked firing frequency was inhibited from 5 min after laser irradiation and persisted for 3 h. Sham irradiation did not alter the firing frequency. Laser irradiation selectively inhibited 15.0 and 26.0 g vFF-evoked firing, which corresponded to nociceptive stimuli. Histopathological evaluation revealed no damage to the sciatic nerve due to laser irradiation. These results indicate that neuronal firing is inhibited in lamina II of the spinal dorsal horn, suggesting that laser irradiation inhibits Aδ and/or C fibers that conduct nociceptive stimuli.

Molecular design of anti-spindle-like molecules by use of siloxanyl terminals for a thermotropic bicontinuous cubic phase.

Selecting 1,2-bis(aryloyl)hydrazine as a model molecular framework, this article examines how the combined modification of two molecular moieties, i.e., variation of the molecular core motif (benzene B or naphthalene N as two aromatic rings) and use of bulky and flexible siloxane segments (disiloxane Si2, trisiloxane Si3, or its branched type iSi3) at the end of both chains, affects the phase behavior including the cubic (Cub) phases such as well-known achiral Ia3d or the so-called "Im3m" phase mostly recognized as a chiral one. It was found that the use of a naphthalene core as a larger core effectively provides the compound with improved thermal stability, and the clearing temperature in the N series is ca. 50 K higher than that of the B series. On the other hand, the introduction of siloxane segments at their terminals is effective for lowering the LC-phase temperature range by several tens of K. Focusing on the Cub phases, only the introduction of the disiloxane Si2 segment was useful for their formation, and we envisioned how much degree the anti-spindle shape of the average molecular shape is in the Ia3d phase. The use of the trisiloxane Si3/iSi3 segment primarily led to the formation of columnar (Col) phases. Consideration of the chemical composition revealed that the delicate balance between the three molecular moieties, siloxane terminal, alkyl spacer, and aromatic core part, is critical for the Cub phase formation, and it can be summarized as the threshold weight fraction of the alkyl spacer in the three moieties being 0.284 or larger, which derives an anti-spindle shape favorable for the formation of the Ia3d-Cub phase.

Effects of photodynamic therapy with talaporfin sodium on squamous cell carcinoma and sarcoma cells.

BACKGROUND: Photodynamic therapy (PDT) uses a photosensitizer and light to destroy abnormal cells. Talaporfin sodium (NPe6) is a second-generation photosensitizer. METHODS: We evaluated the toxic effects of different combinations of laser and NPe6 doses on squamous cell carcinoma (KLN205) and sarcoma (Meth A) cell lines. The cells were incubated with 0, 5, 10, or 30µg/mL NPe6 for 24h. The cells were then irradiated with 0, 5, 15, or 30mW/cm2 of laser power, and 0, 1, 5, 10, or 20J/cm2 of laser energy. Cell viability was evaluated after 24h. We also evaluated the cytotoxic effects of continuous wave or square-wave modulated laser irradiations (2, 5, or 10Hz, 50% duty) on Meth A cells. RESULTS: The median lethal doses of NPe6 against the KLN205 and Meth A cells after treatment at a fluence rate of 15mW/cm2 and a light dose of 20J/cm2 were 18.6 and 5.0µg/mL, respectively. Meth A cells were more sensitive to PDT than KLN205 cells. There was no significant difference between the effects of continuous wave and square-wave modulated lasers on Meth A cell viability. CONCLUSIONS: NPe6 PDT induced cell death in a dose-dependent manner in KLN205 and Meth A cells. More work is required to evaluate the cytotoxic effects of square-wave modulated laser therapy at low light doses.

Parameter-finding studies of photodynamic therapy for approval in Japan and the USA.

OBJECTIVE: The purpose of this study is to investigate methods of evaluating therapeutic parameters used in the premarket evaluation of photodynamic therapy (PDT) drugs that have previously been approved in Japan and the United States, in order to establish a methodology that allows optimization of the therapeutic parameters of PDT, and to analyze current issues. MATERIALS AND METHODS: We examined the details of premarket evaluation of drug dose, drug-light intervals, as well as wavelengths, power density, and energy density of illumination sources used for the PDT drugs that have been approved in Japan the United States. RESULTS: There was a tendency for optimal drug dose and light energy density to be assessed in clinical studies. Drug-light intervals were assessed in the United States in clinical studies, and in Japan only in non-clinical studies. For various drugs, drug-light intervals were assessed based on fluorescence. For most drugs, the wavelength at which the drug can be photo-activated was determined in non-clinical studies. We found only few examples regarding the optimization of light power density as compared to the other therapeutic parameters. CONCLUSIONS: Drug dose, drug-light interval, and light energy density are particularly important parameters with regard to the efficacy and safety of PDT drugs. In order to determine the optimal therapeutic parameters of PDT more effectively, appropriate clinical studies need to be designed. Also the use of biomedical engineering, such as fluorescence measurement, is effective for optimizing PDT therapeutic parameters. We believe that in the future there will be a greater number of regulatory science related studies like ours will lead to the further spread of PDT.