Maciej Stawny

Identification of radiolysis products of solid thiamphenicol

Spectroscopic and chromatographic methods (HPLC, HPLC-MS, NMR) were used to observe, separate and identify products of radiolysis of thiamphenicol (TF), irradiated in the solid state at room temperature and atmospheric pressure with an electron beam from a linear accelerator to doses between 25 and 800 kGy. Nine products of radiolysis of thiamphenicol were identified, among them were TF amine, dichloroacetic acid, 4-methylsulfonylbenzoic acid, demono- and dedichloroderivative of TF, 2,2-dichloro-N-{3-hydroxy-1-[4-(methylsulfonyl)phenyl]-1-oxopropan-2-yl}acetamide and 3-({1,3-dihydroxy-1-[4-(methylsulfonyl)phenyl]propan-2-yl}amino)-3-oxopropanoic acid. The process of radiodegradation of TF was proposed as consisting of several parallel primary reactions (dehalogenation, oxidation of the OH group at C(1), hydrolysis of the amide bond, a rapture of the C(2)-C(3) bond of propan-1-ol) and secondary reactions (carboxylation and oxidation). The use of high doses, well above the sterilization dose of 25 kGy, allowed observation of changes of TF content as a function of radiation dose, calculation of radiolytic yield (G(-TF)) and kinetic parameters of the degradation reaction. It was found that the standard sterilizing dose lowers the content of TF by only 0.1% and the radiolytic efficacy of the process of radiodegradation is 0.76 molecules/100eV. Further increase in the dose lowers the content of TF to 92.1% for 800 kGy dose and leads to an increase in the value of G(-TF). It was also found that the summative process of radiodegradation of TF exposed to a beam of electrons of 10 kGy/s follows the first order reaction kinetics with a degradation constant of k=0.001s(-1). On the basis of the experiments conducted it can be stated that the radiolysis of TF in the presence of an E-beam, in substantia, follows multidirectional course in the same way as radiolysis of chloramphenicol. TF exposed to the standard sterilizing dose of 25 kGy degrades only by 0.1%, the amount acceptable by the ICH, and forms only one product of radiolysis (TF amine) and therefore we conclude that it can be sterilized by ionizing radiation under the conditions described above.

Formulation and characterization of EGCG for the treatment of superficial bladder cancer

In the United States, the annual incidence of bladder cancer is approximately 70,000 new cases, with a mortality rate of approximately 15,000/year. The most common subtype (70%) of bladder cancer is superficial, namely hte non-muscle invasive disease form limited to the urothelium. The rate of progression and recurrence is up to 40 and 70%, respectively. Urothelial cell carcinoma of the bladder is typically treated with transurethral resection. The cancerous cells can float onto the adjacent epithelium, increasing the risk of recurrence. The standard of care is to offer adjuvant intravesical agents to reduce the risk of progression and recurrence. Current intravesical treatments are costly and are associated with special biohazard handling protocols. Patients are treated with intravesical therapy with bacillus Calmetter-Guerin (BCG) bacterium, or mitomycin C (MMC) following resection, both of which can cause moderate to severe side-effects which are rarely life-threatening. We previously examined the efficacy of epigallocatechin-3-gallate (EGCG)in comparison with MMC to prevent tumor cell implantation/growth in an animal model of superficial bladder cancer. Experiments revile that EGCG is slightly more effective than MMC at decreasing tumor cell implantation and consequent cancer growth in a bladder. This treatment requires the stringent sterile requirement of EGCG. EGCG can be unstable when sterilized at high temperatures. Thus, we evaluated two low temperature sterilization methods, such as ionizing radiation or the filtration method followed by freeze-drying. Both methods ensure the sterility of the sample; however, infrared and HPLC analysis revealed a slightly better stability of irradiated EGCG over the filtration method. The concentration of stable free radicals following irradiation was low, which are unlikely to exert any damaging effects to EGCG. Therefore, we consider that radiation will be the preferred method of EGCG sterilization, and that this may prove useful for the effective use of EGCG in the treatment of bladder cancer.

Analysis of Drug Impurities

Although the development of trace analysis is considered to have begun with studies related to the determination of trace elements, from the pharmaceutical point of view, the beginning of this field of science should be sought in the analysis of drugs and especially in the search for active compounds in different types of pharmaceutical decoctions, tinctures, and macerations. Isolation of opium and later morphine from poppy juice, or isolation of quinine from cinchona tree bark, were nothing other than preparation and concentration of a sample before performing trace analysis [1–3].