Strategies to Reduce Nitrosamine Contamination of Drug Products

Nitrosamines contamination of drug products are a concern for pharmaceutical companies. N-Nitrosamines are compounds, which are either proven, or potential carcinogens in humans. With the 2018 report of N-Nitrosodimethylamine (NDMA) found in various Sartan-type drug products, the regulatory bodies imposed a strict limit of acceptable intake of 96 ng/day (nanograms/day) for this specific nitrosamine. In these cases, the API was already contaminated with NDMA during drug synthesis. In the recent years, more and more drug products have been found to contain different nitrosamine impurities leading to recalls and shortages of medicines world-wide. [1]

The list of drug products besides the sartan drugs includes Metformin HCl, Ranitidine, Nizatidine, Rifampin and Rifapentine. Recently, API derived nitrosamines, so called nitrosamine drug substance related impurities (NDSRIs) were reported for several drug products. The list includes varenicline (N-nitrosovarenicline), quinapril HCl (N-nitrosoquinapril), propranolol HCl (N-nitrosopropanolol) and orphenadrine-citrate (N-nitrosoorphenadrine) with an established limit of 18 ng/day for these NDSRIs. [2]

 

𝙉-Nitrosamine CompoundAcceptable intake (ng/day) [2,3]
𝙉-Nitrosodimethylamine (NDMA)96
𝙉-Nitrosodiethylamine (NDEA)26.5
𝙉-Nitroso-𝙉-methyl-4-aminobutanoic acid (NMBA)96
𝙉-Nitrosomethylphenylamine (NMPA)26.5
𝙉-Nitrosoisopropylethylamine (NIPEA)26.5
𝙉-nitrosodiisopropylamine (NDIPA)26.5
Nitrosamine related drug substance impurities (NDSRIs)18

Table 1: References on N-nitrosamine limits in drug products.

 

Different routes of introduction, either in drug synthesis, drug product formulation, or during drug product packaging, were proposed. However, most of these routes involve the reaction of nitrite with a secondary amine (or a less reactive tertiary amines) under acidic conditions. [2]

Besides reaction of nitrite with secondary amines to form nitrosamines, there has been a recent report on the reaction of hydrogen peroxide with DMA to form NDMA through a degradation pathway. This pathway however also involves nitrite generated by degradation of DMA by hydrogen peroxide. [4]

 

How can I mitigate nitrosamines risk in the formulation step?

  1. Reducing secondary amines impurities in the API, as these are precursors for the related nitrosamines and react with nitrite under acidic condition. Avoid nitrite in API synthesis. [5]
  2. Formulating the drug product with excipients showing low nitrite level and low level of hydrogen peroxide. [5–7]
  3. pH Modulation. The reaction of secondary amines with nitrite requires acidic conditions. Adding sodium carbonate as pH modifier might be able to reduce nitrosamine formation. [3]
  4. Recent reports suggest that scavengers as propyl gallate or other antioxidants are reducing nitrosamine generation. [8,9]

While strategies 1 and 2 are feasible for existing formulations and new developments, strategies 3 and 4 are more feasible for new developments. When considering excipient suppliers, qualification of a supplier with low nitrite levels is key. A first report on nitrite level of excipients with values up to 285 ppm for certain excipients was published in 2011, however it did not include hypromellose (HPMC). [6]

Meanwhile, several reports have been published including nitrite values for hypromellose (table 1). [5,7,9]

The references indicate that hypromellose nitrite level might be varying depending on the supplier.

 

Number of batches testedNumber of suppliers testedNitrite range (ppm) reportedReference
2430.01 - 3.7[5]
4950.01 - 5.0[7]
222.2 and 3.0[9]

Table 2: References on nitrite in hypromellose from different suppliers

 

Shin-Etsu tested their cellulose ether and competitors and found lowest nitrite levels in Shin-Etsu hypromellose (low and high viscosity (reference PHARMACOAT® / TYLOPUR® and METOLOSE® SR / TYLOPUR® SR) using a validated analysis method, limiting risk of nitrosamine formation. The data was summarized in a Whitepaper in 2023, which can be downloaded (download here). [10]

Nitrite testing is a rather new topic for excipient manufacturers there is no historical data available and testing is not harmonized (there are UV, HPLC-UV, IC methods reported for e.g. hypromellose). It is noted by the International Pharmaceutical Excipients Council (IPEC) in their questionnaire on nitrosamines risk assessment, that nitrite test results from suppliers may vary and encourages excipient users to develop their own nitrite test for excipients. [11]

Shin-Etsu provides support in the development of analytical methods to enable pharmaceutical companies to test for nitrite in hypromellose.

 

Summary

Nitrosamines contamination of drug products are a concern for pharmaceutical companies. Nitrite plays an important role in the formation of nitrosamines in drug products, and nitrite levels may vary among excipients and suppliers for the same excipient. Shin-Etsu provides high quality excipients with low nitrite levels, supporting the pharmaceutical industry in supplying safe medicines to the patients. Please see the whitepaper for further details.
 

References

  1. Bharate, S.S. Critical Analysis of Drug Product Recalls Due to Nitrosamine Impurities. J. Med. Chem. 2021, doi:10.1021/acs.jmedchem.0c02120.
  2. Schlingemann, J.; Burns, M.J.; Ponting, D.J.; Avila, C.M.; Romero, N.E.; Jaywant, M.A.; Smith, G.F.; Ashworth, I.W.; Simon, S.; Saal, C.; et al. The Landscape of Potential Small and Drug Substance Related Nitrosamines in Pharmaceuticals. J. Pharm. Sci. 2022, 000, doi:10.1016/j.xphs.2022.11.013.
  3. FDA Updates on Possible Mitigation Strategies to Reduce the Risk of Nitrosamine Drug Substance-Related Impurities in Drug Products Available online: www.fda.gov/drugs/drug-safety-and-availability/updates-possible-mitigation-strategies-reduce-risk-nitrosamine-drug-substance-related-impurities.
  4. Jireš, J.; Douša, M.; Gibala, P.; Kubelka, T. N-Nitrosation in the Absence of Nitrosating Agents in Pharmaceuticals? J. Pharm. Biomed. Anal. 2022, 218, 114872, doi:https://doi.org/10.1016/j.jpba.2022.114872.
  5. Schlingemann, J.; Boucley, C.; Hickert, S.; Bourasseau, L.; Walker, M.; Celdran, C.; Chemarin, T.; Pegues, C.; Fritzsche, M.; Keitel, J.; et al. Avoiding N-Nitrosodimethylamine Formation in Metformin Pharmaceuticals by Limiting Dimethylamine and Nitrite. Int. J. Pharm. 2022, 620, 121740, doi:10.1016/j.ijpharm.2022.121740.
  6. Wu, Y.; Levons, J.; Narang, A.S.; Raghavan, K.; Rao, V.M. Reactive Impurities in Excipients: Profiling, Identification and Mitigation of Drug-Excipient Incompatibility. AAPS PharmSciTech 2011, 12, 1248–1263, doi:10.1208/s12249-011-9677-z.
  7. Boetzel, R.; Schlingemann, J.; Hickert, S.; Korn, C.; Kocks, G.; Luck, B.; Blom, G.; Harrison, M.; François, M.; Allain, L.; et al. A Nitrite Excipient Database: A Useful Tool to Support N-Nitrosamine Risk Assessments for Drug Products. J. Pharm. Sci. 2022, doi:10.1016/j.xphs.2022.04.016.
  8. Homšak, M.; Trampuž, M.; Naveršnik, K.; Kitanovski, Z.; Žnidarič, M.; Kiefer, M.; Časar, Z. Assessment of a Diverse Array of Nitrite Scavengers in Solution and Solid State: A Study of Inhibitory Effect on the Formation of Alkyl-Aryl and Dialkyl N-Nitrosamine Derivatives. Processes 2022, 10, 2428, doi:10.3390/pr10112428.
  9. Hao, G.; Hu, R.; Wang, X.; Gao, P.; Wang, L.; Jiang, M.; Xin, L.; Tan, G.; Zhao, Y.; Sun, F.; et al. N-Nitrosodimethylamine Formation in Metformin Hydrochloride Sustained-Release Tablets: Effects of Metformin and Hypromellose Used in Drug Product Formulation. J. Pharm. Biomed. Anal. 2023, 222, 115066, doi:10.1016/j.jpba.2022.115066.
  10. Shin-Etsu Strategies to Reduce Nitrosamine Contamination of Drug Products; 2023.
  11. IPEC Federation IPEC Questionnaire for Excipient Nitrosamines Risk Evaluation; 2023.

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