Optimisation of incubation and shaking protocols

Optimising incubation and agitation protocols is one of the fundamental pillars for ensuring reproducibility and sensitivity in cell-based assays. Often, small variations in time, temperature or movement can significantly alter signal intensity, reagent binding affinity or even cell viability.
Understanding how these factors interact allows us to design robust procedures that maximise the signal-to-noise ratio, reduce inter-experimental variability, and preserve cellular physiology.

Incubation time: finding the balance between efficiency and cell stability

Incubation time defines the window in which key molecular processes occur, such as antigen-antibody binding, probe internalisation, or enzyme activation.

• Insufficient incubation times can lead to incomplete binding and a reduction in signal intensity.
• Prolonged incubations, on the other hand, can trigger cellular stress responses, loss of surface markers, or apoptosis, especially in sensitive populations.

Each assay requires empirical calibration of the optimal time, considering the cell type, antigen expression density, and nature of the reagent. In our assays with the INTRACELL line, we have observed that carefully adjusted incubation can increase fluorescence intensity by up to 30% without compromising viability.

Incubation temperature: modulating kinetics and cell integrity

Temperature is a determining factor in the speed of molecular interactions and the stability of cell structures.

• Incubations at 4°C are ideal for surface labelling assays, as they minimise endocytosis and preserve the distribution of membrane receptors.
• Incubations at 37°C, on the other hand, are used when it is necessary to maintain metabolic activity or study energy-dependent processes, such as intracellular signalling or antigen internalisation.

However, even slight deviations (±2 °C) can alter the binding affinity of antibodies or modify the protein expression profile. Therefore, it is recommended to periodically validate the calibration of thermal systems and ensure thermal uniformity throughout the incubation process.

Movement and agitation: promoting homogeneity without compromising integrity

Movement during incubation plays an essential role in promoting better diffusion of reagents and preventing cell sedimentation, which contributes to a more uniform signal. However, excessive agitation can induce mechanical stress and micro-shearing that damage the cell membrane or alter morphology.
Recommendations:

• Use gentle and constant agitation (e.g., 100-150 rpm in orbital incubators).
• Avoid sudden movements or prolonged vortexing.
• Validate the compatibility of the container (tubes, microplates, incubation chambers) with the type of agitation applied.

Proper optimisation of movement can improve the reproducibility of assays, especially in intracellular expression or cytokine detection studies, where the homogeneity of contact between reagents and cells is crucial.

Interaction between parameters: the multifactorial approach

The parameters of time, temperature, and agitation do not act in isolation. Their interdependence defines the overall performance of the assay. For example:

• A reduction in temperature can be compensated for with longer incubation times to maintain affinity.
• Moderate agitation can accelerate binding kinetics, allowing the total time to be reduced without signal loss.

The most effective approach is multifactorial design of experiments (DoE), which allows the combined effects of these variables to be modelled and predicted, identifying the optimal conditions with a minimum number of trials.

Conclusion: control and standardisation for a consistent signal

In advanced biotechnology, reproducibility is as important as sensitivity. Optimising incubation and agitation parameters not only improves signal quality, but also ensures consistency between experiments and comparability between laboratories.
At Immunostep, we develop reagents and kits—such as the INTRACELL range—designed to offer maximum signal intensity and preservation of cell viability, even under demanding experimental conditions. Our commitment to optimising experimental protocols translates into more robust, sensitive and reproducible results for researchers seeking precision and reliability in every assay.