Bioanalytical laboratories are highly important in the development of new drugs and new drug formulations in the pharmaceutical industry. Thus, identification and quantification of drug substances and metabolites in biological samples like blood plasma, urine, and tissue play a very important role during drug development. Drug development begins with the identification of a medical need and hypotheses on how therapy can be improved. Drug discovery is the identification of new drug candidates based on combinatorial chemistry, high-throughput screening, genomics, and ADME (absorption, distribution, metabolism, and elimination). By combinatorial chemistry, a great number of new drug candidates are synthesized, and these are tested for pharmacological activity and potency in high-throughput screening (HTS) systems. The HTS systems simulate the interaction of the drug candidates with a specific biological receptor or target. Once a lead compound is found, a narrow range of similar drug candidates is synthesized and screened to improve the activity toward the specific target. Other studies investigate the ADME profile of drug candidates by analyzing samples collected at different time points from dosed laboratory animals (in vivo testing) and tissue cultures (in vitro testing).

Drug candidates passing the discovery phase are subjected to toxicity testing and further metabolism and pharmacological studies in the preclinical development phase. Both in vivo and in vitro tests are conducted, and various animal species are used to prove the pharmacokinetic profile of the candidate. The detailed information about the candidate forms the basis for further pharmaceutical research on the synthesis of raw materials, the development of dosage forms, quality control, and stability testing.

The clinical development phase can begin when a regulatory body has judged a drug candidate to be effective and to appear safe in healthy volunteers. In phase I, the goal is to establish a safe and efficient dosage regimen and to assess pharmacokinetics. Blood samples are collected and analyzed from a small group of healthy volunteers (20–80 persons). The data obtained form the basis for developing controlled phase II studies. The goal of phase II studies is to demonstrate a positive benefit–risk balance in a larger group of patients (200–800) and to further study pharmacokinetics. Monitoring of efficacy and monitoring of possible side effects are essential. Phase II studies can take up to two years to fulfill. At the end of phase II, a report is submitted to the regulatory body, and conditions for phase III studies are discussed. Additional information supporting the claims for a new drug is provided. Phase III begins when evidence for the efficacy of the drug candidate and supporting data have demonstrated a favorable outcome to the regulatory body. The phase III studies are large-scale efficacy studies with focus on the effectiveness and safety of the drug candidate in a large group of patients. In most cases, the drug candidate is compared with another drug already in use for treatment of the same condition. Phase III studies can last two to three years or more, and 3000–5000 patients can be involved. Carcinogenetic tests, toxicology tests, and metabolic studies in laboratory animals are conducted in parallel. The cumulative data form the basis for filing a new drug application to the regulatory body and for future plans for manufacturing and marketing. The regulatory body thoroughly evaluates the documentation that is provided before a market approval can be authorized and the drug product can be legally marketed. The time required from drug discovery to product launch is up t...