The purpose of this study was to quantify the in-vitro human skin transdermal flux of Delta8-tetrahydrocannabinol (Delta8-THC), cannabidiol (CBD) and cannabinol (CBN). These cannabinoids are of interest because they are likely candidates for transdermal combination therapy. Differential thermal analysis and in-vitro diffusion studies with human tissue were completed for the compounds. Heats of fusion, melting points and relative thermodynamic activities were determined for the crystalline compounds, CBD and CBN. Flux, permeability, tissue concentration and lag times were measured in the diffusion experiments. CBN had a lower heat of fusion and corresponding higher calculated relative thermodynamic activity than CBD. Ethanol concentrations of 30 to 33% significantly increased the transdermal flux of Delta8-THC and CBD. Tissue concentrations of Delta8-THC were significantly higher than for CBN. Lag times for CBD were significantly smaller than for CBN. The permeabilities of CBD and CBN were 10-fold higher than for Delta8-THC. Combinations of these cannabinoids with ethanol will be further studied in transdermal patch formulations in vitro and in vivo, as significant flux levels of all the drugs were obtained. CBD, the most polar of the three drugs, and other more polar cannabinoids will also be the focus of future drug design studies for improved transdermal delivery rates.
The aim of this study was to explore the nasal route as an alternative to daily subcutaneous injections of hPTH (1-34). Anesthetized rats were surgically prepared and nasally dosed with aqueous solutions of hPTH (1-34). Plasma samples were assayed by radioimmunoassay and data generated fit to two-(intravenous) and one-(intranasal) compartment pharmacokinetic models using WinNonlin. The toxicity of hPTH (1-34) solution administered to the rats was assessed by screening its effect on transepithelial electrical resistance, potential difference, paracellular marker permeation, tissue viability, and protein leakage using the EpiAirway tissue model. The intranasal absorption of hPTH (1-34) was rapid; the absorption rate constants (alpha) were 33.2+/-24 h(-1) [without bovine serum albumin (BSA)] and 9.8+/-5.1 h(-1) (with 1% BSA). The maximum plasma concentrations (Cmax): 151+/-24 pg/mL (without BSA) and 176+/-37 (with 1% BSA) were attained within approximately 15 min. The intranasal bioavailabilities (Fabs) were 12.1+/-3.4% (without BSA) and 17.6+/-1.5% (with 1% BSA). The hPTH (1-34) formulation administered to the rats had no detrimental effect on the EpiAirway tissue epithelial electrical parameters and functional integrity. Based on the results of this study, the nasal route appears to be a prospective alternative to subcutaneous injections of hPTH (1-34).
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