TRANSIL HSA Binding Kit

Most literature values were obtained by dialysis experiments. Usually, dialysis experiments use pooled plasma that is not controlled for its exact protein composition. However, even minor changes in both HSA and AGP concentration can have major effects on the fraction unbound of some drug candidates. Also, most literature values date back to times when there was no awareness of the influence of pH shifts during the dialysis experiment on the results. And only recently has it been recognized that plasticizers in plasma collection bags can have an equally dramatic effect on plasma protein folding and thus binding of drugs. Thus, differences between results from TRANSIL and dialysis experiments are to be expected due to artefacts that can arise and uncontrolled variables in dialysis.

The table below lists dissociation constants for some marketed drugs.

When a compound is unstable in plasma equilibrium dialysis fails to report adequate results. However, the TRANSIL HSA binding assay performs well under these conditions, because incubation time is 15 minutes or less and there are no enzymes present in the assay system that would degrade the compound.

When a compound is unstable and degrades within hours during equilibrium dialysis results will not be useful. However, the TRANSIL HSA binding assay performs well under these conditions, because incubation time can be reduced to only 2 minutes.

No, there are two reason why this is not needed. Remember, the CO2 atmosphere is needed for dialysis because there is only a low buffer capacity in the system which makes it susceptible to pH changes by diffusion of CO2. That pH change then results in biased plasma protein binding estimates.

This doesn’t happen in the TRANSIL HSA Binding Kit as comes with a strong phosphate buffer, thus diffusion of CO2 will not alter the pH. Also, the kit is only incubated for 12 minutes instead of several hours which minimizes the potential impact of CO2-concentration changes.

The extent of binding to plasma influences the way in which a drug distributes into tissues in the body. If a compound is highly bound, then it is retained in the plasma, which results in a low volume of distribution. This may impact on the therapeutic effects of the compound by limiting the amount of free compound which is available to act at the target molecule. Extensive plasma protein binding also limits the amount of free compound available to be metabolized which can, in turn, reduce the clearance of the compound.

Healthy humans have a plasma composition that breaks down into 60% albumin and 40% globulins. The latter break down into 4% α₁ globulins, of which α₁ acid glycoprotein is only a small part, 8% α₂ globulins (e.g. haptoglobulin, macrogobulin etc), 12% β globulins, and 16% γ globulins (i.e. our antibodies). However, these are textbook number referring to healthy humans. The plasma composition changes with age, race, sex, and disease condition and the unbound fraction of a drug can change accordingly (Figure 3). In fact, it has been shown that, for example, a 2-fold change in the AGP (AAG) concentration can lead to a 3-fold reduction in survival time of NSCLC patients treated with docetaxel. Thus, measuring the dissociation constant KD of your discovery compound to the major plasma proteins HSA and AGP can be critical in many indication areas.

For instance, as a positive control you can use warfarin (KD=6.4 µM), and as a negative control compound you can use propranolol (KD=430 µM).

The TRANSIL Quality Index (TQI) is based on independent measures derived from the data analysis.

• Overall fit of the data to the standard protein binding model
• Recovery: does the model derived compound concentration equal the true concentration?
• Data consistency: does membrane binding increase proportionally with the increasing TRANSIL bead content in each well?
• Data consistency: are the estimated reference concentrations in alignment with the compound concentration used?
• Missing data and outliers.

One assay plate can be used for 12 compounds. Thus, you’ll need to pipette 15 µl of test item to each of 8 wells and repeat this for all 12 compounds. This takes less than 10 minutes even with manual pipetting. After compound addition, the plate is ready for incubation. You can do this with an electronic 8 or 12 channel pipette by aspirating and dispensing a volume of 120 µl for 15 times. That takes just over a minute for each column or row. In total, that makes 8 to 15 minutes depending on your pipette. When using a pipetting robot with a 96 well head this time decreases to 2 minutes. After incubation, the plate needs to be spun in a plate centrifuge for 10 minutes. The supernatants are then ready for quantification by LC/MS/MS, UV, fluorescence or any other method of your choice.

Thus, the total time the start and end of the experiment varies between 7 and 25 minutes depending upon your equipment.

One assay plate can be used for 12 compounds. A special feature of the 96 well plates used for these kits is that each of the 12 columns can be separated from the plate. Thus, it is possible to use the plate for one compound at a time.

The TRANSIL assay kits utilize Micronic 96 well plates with ultra-low-binding tubes. Standard polypropylene tubes have 41x higher non-specific binding and low-binding tubes from other vendors have 2.6x higher non-specific binding.