The procedure of pharmaceutical deformulation involves using chemical reverse engineering methods to deconstruct a pharmaceutical product’s formulation to determine and measure its active pharmaceutical ingredients and excipients. Experienced chemists execute this process to maintain consistent physical properties throughout the analytical procedure. The process of deformulation can be utilized for a range of pharmaceutical products such as oral solid dosage forms and injectables among others.
The pharmaceutical industry greatly depends on the process of pharmaceutical deformulation. Pharmaceutical deformulation helps replicate existing products to gather detailed drug information while allowing identification of formulation differences and development of generic drugs and drug improvements. Deformulation assists in verifying product composition against label statements and detecting counterfeit drugs.
What are the Objectives of Deformulation?
Development of Generic Drugs
In generic drug development pharmaceutical deformulation stands as one of the essential processes. Analyzing the formulation of the original drug allows researchers to gather essential ingredient details for creating a generic drug that matches the brand-name drug’s effectiveness.
Improvement of Product Performance
Pharmaceutical companies can expedite their product development through deformulation analysis by gaining swift insights into competitor formulations which helps them enhance their own product design. Product quality enhancement becomes possible through formulation improvements developed from existing product deficiencies analysis.
Regulatory Compliance and Quality Assurance
Demonstrating bioequivalence between a generic drug and its reference-listed counterpart in Abbreviated New Drug Applications requires deformulation analysis as an essential step. Analyzing both APIs and excipients allows for verification that the generic drug remains consistent across dosage form, administration route, and quality attributes.
Intellectual Property and Patent Analysis
The process of deformulation serves as a tool to evaluate potential patent infringement risks. New product development gains legal justification through competitor product analysis which identifies patent infringement situations.
Pharmaceutical deformulation serves as a crucial analytical process that is widely utilized in generic drug development along with product quality improvement and intellectual property protection. The primary objective of this technique is to ensure superior development quality and adherence to regulatory standards by performing detailed reverse engineering techniques on drug compositions.
The Process of Deformulation Testing
1. Sample Preparation and Preliminary Analysis
The API and excipients in pharmaceutical formulations (e.g., tablets, capsules, or solutions) undergo a series of physical and chemical treatments to achieve separation. The process can include grinding the sample followed by dissolution and filtration among other necessary procedures.
The primary identification of sample components utilizes spectroscopy methods like FT-IR and NMR along with chromatography techniques such as HPLC and GC.
2. Component Separation and Quantification
To analyze separated components further and determine their identities and concentrations analytical instruments like LC-MS and GC-MS are applied.
Separation techniques such as solvent extraction or electrophoresis become necessary when particular components present separation challenges.
3. Identification and Quantification of Excipients
Deformulation processes require accurate identification and quantification of excipients due to their influence on drug release properties alongside stability and bioavailability.
The functional roles of excipients in a formulation become clearer when their physicochemical properties such as solubility and melting point are studied.
4. Formulation Reconstruction and Validation
The analytical data enables chemists to either replicate the original formulation or create a new formulation.
In vitro bioequivalence tests including dissolution profile comparisons are required to confirm the reconstructed formulation matches the original drug.
5. Quality Control and Compliance Evaluation
The deformulation testing process requires that all analytical methods and instruments demonstrate both accuracy and reliability.
The final analytical results must adhere to specific regulatory standards including ANDA (Abbreviated New Drug Application) and Q3/4/5Q bioequivalence requirements.
Deformulation Analysis: Tools and Techniques
The process of pharmaceutical deformulation requires the use of multiple sophisticated analytical instruments and procedures.
Nanoscale Instrumentation
- Scanning Electron Microscopy (SEM): The SEM system equipped with Energy Dispersive Spectroscopy allows measurement of drug particles’ morphology and size distribution and identifies the elemental composition of APIs and excipients.
- Transmission Electron Microscopy (TEM): Transmission Electron Microscopy enables researchers to examine drug particles’ microscopic structure while helping identify components.
Spectroscopic Techniques
- Fourier Transform Infrared Spectroscopy (FT-IR): Fourier Transform Infrared Spectroscopy (FT-IR) performs analysis on the chemical structure of drugs alongside excipients.
Fig. 1 FTIR for direct quantification of paracetamol content in solid pharmaceutical formulations
- Raman Spectroscopy: Raman Spectroscopy enables quick identification of APIs and excipients through morphology-guided analysis.
Chromatographic Techniques
- Gas Chromatography (GC): Gas Chromatography enables both separation and identification of volatile substances.
- High-Performance Liquid Chromatography (HPLC): This technique facilitates separation and measurement of non-volatile chemical substances.
Physical Characterization Techniques
- X-ray Diffraction (XRD): Analyzes the crystalline structure of drugs.
- X-ray Fluorescence (XRF): Detects the elemental composition of components.
- Thermogravimetric Analysis (TGA): Studies the thermal stability of components.
Other Advanced Techniques
- Synchrotron Radiation X-ray Microtomography (SR-CT): Provides high-resolution imaging of drug particles.
- Nanoindentation Technology: Evaluates the mechanical properties of drug particles.
