Huntington’s disease (HD) is a neurodegenerative disease caused by the CAG trinucleotide expansion in the huntingtin gene. So far, there is no effective drug for HD treatment and many studies have been carried out to explore the therapeutic targets to alleviate the symptoms of HD. Recently, some studies indicated that modulating the adenosinergic system may be a feasible strategy. Compound A, an adenosine analogue extracted from Gastrodia elata (GE), has the dual function of ENT1 inhibition and A2A receptor activation. In addition to compound A, two adenosine analogues derived from compound A, compound B and compound C, were synthesized. Considering the fact that oral drug is convenient, in this study, MDCK II uptake study, in situ intestinal perfusion, and bioavailability (BA) study were performed to evaluate oral absorption of these compounds. For brain distribution, ARBEC uptake study was conducted to investigate the ability of these compounds to pass through the blood-brain barrier (BBB). Blood to brain ratios (brain/blood ratios) were measured in ICR mice given compounds by tail vein injection. Also, compounds were administrated to the Wistar rats by intraperitoneal injection and the concentrations of compounds and adenosine in striatum were detected by in-vivo brain microdialysis. The predicted fraction absorbed (Fa) in human of compound A, compound B and compound C were 0.41 ± 0.12, 0.77 ± 0.07 and 0.87 ± 0.01, respectively. The bioavailability (BA) values in mice were 5.48 %, 7.13 %, and 25.99 % for compound A, compound B and compound C, respectively. With regard to the distribution in the brain, the blood to brain ratio of compound C was increased over time in the ICR mice, whereas the blood to brain ratio was decreased over time in other two compounds. In the brain microdialysis study, the concentrations of compound C and adenosine are unchanged, but the concentrations of compound A, compound B and adenosine have the trend of increase after intraperitoneal injection of these compounds. The discrepancy between blood to brain ratio and microdialysis for compound C may attribute to its high tissue binding. In conclusion, the pharmacokinetic study suggests that compound C may have the potential to be developed as an oral drug with respect to oral absorption property, whereas its distribution in the brain need to be further elucidated.