History
During the past two decades, massive developments of various categories of anti-cancer drugs have been observed. Chemotherapy is definitely one of the fundamental weapons in the treatment for cancer patients by destroying tumour cells and lengthening the lifetime of patients who suffer from a malignant tumour. A lot of attention is paid to semustine, considered as one of the members of the chloroethyl nitrosourea (CENU) family, a drug family consisting of alkylating anti-tumour agents that can be employed for treatment of human cancer. CENU’s exert their anti-cancer activity by stimulating the formation of DNA interstrand (between two opposite strands) cross-links. Preclinical toxicity studies discovered that the kidney was a target organ for semustine toxicity. However, renal failure due to the nitrosoureas was not reported until 1978. More recently, a relationship between semustine and often fatal nephrotoxicity in patients was indeed established.Structure and reactivity
Semustine (Me-CCNU) is an organochlorine compound that is urea in which the two hydrogens on one of the amino groups are replaced by nitroso and 2-chloroetyl groups and one hydrogen from the other amino group is replaced by a 4-methylcyclohexcyl group. Semustine is also known as a 4-methyl derivative of lomustine.Synthesis
The synthesis of semustine originates from a systematic synthesis scheme revolving around N-Nitrosourea compounds. Phosgene is reacted with Aziridine to produce the chemical intermediate di(aziridin-1-yl) methanone. This reacts with the subsequently released HCl from the production of the intermediate to open the Aziridine rings and it will form 1,3-bis(2-chloroethyl)-urea. The next step is to nitrosate this compound with the sodium nitrite in formic acid. This will give one of the nitrogen’s a nitroso functional group. With this step carmustine (BCNU), another medication used for chemotherapy, is formed. BCNU is subsequently decomposed in the presence of 4-Methylcyclohexylamine. The aliphatic amine is in two equivalents present during the decomposition. During the decomposition, the compound loses its nitroso group and only one methyl cyclohexyl group will be found on the compound. The final step is to repeat the nitrosation of the compound under the same conditions and Semustine (Me-CCNU) is synthesised. This whole synthesis is shown in Figure 1. More recent studies suggest using 1-chloro-2-isocyanatoethyl as a starting material alongside cyclohexylamine. For this, TEA can be used as a catalyst to get to the same final step as the previously mentioned synthesis route. In this final step, the nitrosation can be done again with sodium nitrite (1) or with tert-Butyl nitrite (2). In this synthesis R = H, CH3 or OH. This whole synthesis is shown in Figure 2.Available forms
Since the synthesis yields a stable substance, this compound is usually delivered as pure substance and not as a salt. When supplied as medicine, the most common forms of administration are pills with a range from 3.0 to 100 mg semustine per pill.Mechanism of action
DNA is the most significant part of the cell, performing the most important processes, replication, and transcription. These processes and DNA itself can be targeted with small molecules or ligands with possible antitumor activity, resulting in prevention of continuous growth and proliferating of cancer cells. The common property of alkylating agents, including semustine, is their capacity to become very strong electrophiles through the formation of (chloro-) carbonium ion intermediates, which are products of the hydrolysis of the semustine drug. This reaction yields covalent cross-links between various nucleophilic DNA bases by alkylation, causing denaturation of the double helix and inhibiting separation of the DNA strand. By this mechanism, semustine interferes with rapidly proliferating cells and exerts its anti-tumour effects. Targets of the interstrand cross-link forming are specifically the N-7 of guanine, O-6 of adenine and other sites on the purine bases. This is depicted in Figure 3. The electrophilic property of semustine increases under acidic conditions, which makes the nucleophilic attack occur much faster. In general, acidic pH conditions cause a significant increase in the reaction rate of the semustine drug.Metabolism
After oral administration and absorption from the gastrointestinal tract, semustine undergoes rapid chemical decomposition and oxidative metabolism. Due to the lipophilic nature of semustine, the distribution is quickly across the tissue. Semustine is metabolised by the cytochrome P450 (CYP) mono-oxygenase system on the cyclohexyl ring carbons and the 2-chloroethyl sidechain resulting hydroxylated metabolites, which remains alkylating and anti-tumour active. Most of the biological effect is due to the generation of the chloroethyl carbonium ion from the ring hydroxylated metabolite. Ring hydroxylation occurs during the “first pass” through the gut wall and liver. The metabolites and decomposition products are excreted by the kidneys into the urine. Up to 60% of the dose is excreted by urine within 48 hours. The decomposition products present in the urine are cis-3-hydroxy-trans-4-methylcyclohexylamine, trans-4-methylcyclohexylamine, trans-4-hydroxymethylcyclohexylamine and trans-3-hydroxy-trans-4-methyl-cyclohexylamine. These are shown in Figure 4.Indications
Nitrosoureas such as semustine frequently cause nausea and vomiting, after admission (4 to 6 hours). The major toxic effects of semustine are thrombocytopenia and leukopenia caused by cumulative doses. Secondly the nephrotoxicity and hepatotoxicity of the semustine cause pulmonary fibrosis and renal dysfunction. Semustine nephrotoxicity is cumulative, the cumulative dose at which nephrotoxicity is likely to occur has been estimated to be near 2,000 mg/m2. This problem generally appears only in patients being treated for more than 1 year, which requires a prolonged survival time.Efficacy and side effects
Efficacy
Semustine was used to treat several different types of cancers. The main one was L1210 leukaemia and Hodgkin lymphoma. Other types are metastatic brain tumours, Lewis lung tumours, cancers of the digestive tract, lymphoma, malignant melanoma, and epidermoid carcinoma of the lung. It has however not shown desired results as an antineoplastic drug and thus has never been approved for it. Combinations with other drugs have also been done in the 70’s but have not shown more beneficial results. InAdverse effects
During the trials of semustine, sufficient evidence was found that semustine is a carcinogen. During a trail of 2067 patients, 14 cases of acute leukaemia were found. This was combined with a roughly 4% chance to acquire leukaemia disorder within six years. This trail was done on patients with gastrointestinal cancer and before the use of this antineoplastic drug, there were no recorded cases in the medical history of Connecticut that these combinations of cancer occur. This could be derived back to the start of the nitrosourea chemotherapy. Providing quantitative evidence that semustine is a carcinogen. For this reason it is also added to IARC group 1 for carcinogenic agents to humans.Effects on animals
The described carcinogenicity of semustine to humans has not been found in animals, specifically mice and rats. It is however still a carcinogen. There was an increase found in peritoneal sarcoma and lung tumours, indicating a different toxicity to animals.References
{{Chemotherapeutic agents Alkylating antineoplastic agents IARC Group 1 carcinogens Nitrosamines Nitrosoureas Organochlorides Withdrawn drugs Cyclohexyl compounds Chloroethyl compounds