In pharmaceutical manufacturing, the color of a drug product is crucial as it can influence consumer perception and compliance. Specifically, variations from the anticipated color could indicate impurities are present in the product or that the material has degraded. This is particularly important for materials which are easily decomposed, including light, moisture, and oxygen/air-sensitive substances.
Human eyes are sensitive to variations in color and brightness, making even small changes noticeable. However, person-to-person variations, environmental effects such as light sources, and shadows can influence perceived color, necessitating a more rigorous and quantitative method for assessing color. UV-Visible spectrophotometry is a technique that offers an objective way to measure and analyze color in pharmaceutical products.
What is the Real Color?
Color perception results from the collection of reflected light in the visible range (~400 nm – 700 nm) by our eyes. To mitigate subjective variations in color assessment, UV-Visible spectrophotometry — a well-established analytical technique used in pharmaceutical research and quality control in drug development — can quantitatively measure the color of materials. These spectrometers can analyze the absorption and reflection of light across the UV-visible spectrum, providing precise and reproducible color data.
Getting the Right Color, Day or Night
As we noted, in pharmaceutical manufacturing, color analysis is often required to ensure that products meet specific color standards. Some products may need to be achromatic (having no discernable color), while others must meet a minimum color value. The United States Pharmacopeia (USP) has developed criteria to set acceptable limits for color differences from a standard, facilitating consistent quality control.
The Study
In order to demonstrate how UV-Visible spectrophotometers can accurately analyze the color of pharmaceutical products, we conducted several experiments involving day and night-time liquid cough syrups and 4 different colored antacid samples. A select set of color-matching standards prepared according to a USP monograph were also analyzed for color.
Qualitatively, a comparison of the color of a finished drug product by eye with an accepted standard can be used to ensure the material’s color matches. However, inherently this methodology will introduce person-to-person variations and does not account for environmental effects (e.g., light source) thereby influencing the perceived color. As the color of a material comes from the reflected visible light, spectroscopic measurements of a material in the visible spectral range can be used to provide a more rigorous and quantitative method for assessing color.
Consequently, a UV-Visible spectrophotometer can be used to measure either the percent of light transmitted (%T) or reflected (%R) across the visible spectrum for this purpose. As %R is only used for solid samples, the ability to use either of these beam geometries ensures the color of both liquids and solids can assessed.
The American Society for Testing and Materials (ASTM) as well as various pharmacopeia (USP and EP) have detailed descriptions of the mathematics that can be used to assign the sample a coordinate in a graphical representation of color, also referred to as a color space.
We have published the details and results of the study in our application note Color analysis for pharmaceutical products using UV-Visible absorption techniques. Read it to learn more about the use of UV-Visible spectrophotometry and the underlying mathematics that can be used for color analysis of various sample types.
Summary
The study concluded that color analysis using UV-Visible spectrophotometry is an effective and rapid method for quality assurance and quality control (QA/QC) in pharmaceutical manufacturing. This technique eliminates person-to-person variations and provides a quantitative analysis of a product’s color.
The described methods demonstrate the ability to analyze both liquid and solid samples following USP color analysis procedures, helping to ensure consistent and reliable color measurements. This technique provides a reliable, objective, and reproducible method for assessing the color of pharmaceutical products, critical for maintaining consumer trust and meeting regulatory requirements.
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