Laboratories have traditionally relied on volumetric methods for preparing samples, standards and solutions. This manual process has changed very little over the years, and has considerable risk of variability and errors. New approaches and accessories, including state-of-the-art gravimetric methods, can address these errors and make sample preparation much more efficient and accurate.

In a typical analytical laboratory, sample and solution preparation is a crucial part of many processes, lying at the heart of accurate, precise data generation. Errors in sample prep steps have various consequences, particularly in regulated environments, where any non-compliance may require time-consuming and labour-intensive correction. If repeat analyses are necessary, consuming additional precious – often expensive – materials, confidence in laboratory data can fall.

Generally, samples for analysis need to be in solution, and this requires accurate, precise preparation of samples, standards and reagents. Standards of known concentrations must be accurately prepared for instrument calibration, as well as any other solutions or reagents, such as buffers, that are required for the analytical protocol.

All laboratories − regardless of industry or field − must generate reliable, accurate data. This may or may not be regulation driven, and the impact of an OOS result will vary accordingly. In research laboratories, for example, the key driver is the need for method reproducibility and accurate results, whilst production, testing and QC laboratories are likely to be strictly regulated, in compliance with stringent GMP/GLP regulations. However, in striving to ensure highly accurate experimental data, the general principles applying to out-of-specification results are equally relevant to both regulated and non-regulated laboratories.

It is widely accepted that sample processing is the most time-consuming aspect of an analytical workflow (61%), from research published more than a decade ago. If you also consider that sample processing is the largest single source of OOS errors (30%) in an analytical workflow, followed by operator error (19%), then you quickly realise that addressing (improving) the manual sample processing steps can have a significant positive impact on both resources and reducing OOS errors (see Fig. 1).

Whilst enhanced analytical instrumentation and software have provided dramatic improvements and considerable time savings in sample analysis and data processing over the last decade, surprisingly sample processing techniques have changed very little during the last century, so it seems fair to assume that the percentage of time spent on sample processing is even higher now.

Typically the sample is weighed directly into a volumetric flask−or alternatively onto a weighing paper and subsequently transferred into the flask−and then the flask is filled with solvent. Frequently, results are handwritten in a laboratory journal, with a risk of transcription errors, making any errors hard to identify and correct. The problem with errors at the sample preparation stage is that they will simply be perpetuated, or even magnified, in downstream processing.

Even for experienced professionals, the steps involved in volumetric sample preparation can take a lot of manual time and effort and have a high risk of human error, as well as being prone to day-to-day and operator-to-operator variability.

Sources of variability and error in a typical volumetric workflow include: