Skip to Content
MilliporeSigma
HomeClinical & Forensic TestingSimultaneous Determination of Free T3 and Free T4 in Serum

Simultaneous Determination of Free Triiodothyronine (T3) and Free Thyroxine (T4) from Serum using the Supel™ BioSPME for Sample Preparation

Abstract

This study presents a novel method for the simultaneous determination of free T3 and T4 serum hormone levels by LC-MS using Supel™ BioSPME for sample preparation, significantly reducing preparation time to under one hour. The method is compared to traditional equilibrium dialysis, demonstrating improved efficiency for monitoring of thyroid hormones.

Section overview:

Introduction

The thyroid hormones triiodothyronine, T3 or 3, 5, 3’-triiodo-l-thyronine, and thyroxine, T4 or 3, 5, 3’, 5’-tetraiodo-l-thyroxinine, are biomarkers used to monitor thyroid activity (Figure 1). Approximately 0.04% of the total T3 and 0.02% of the total T4 is available as the free form in circulation, with the remainder bound primarily to thyroxine-binding globulin and, to a lesser extent, albumin and transthyretin.1 Direct analogue immunoassays, the most common tests performed at most clinical laboratories, suffer from interferences and lack of specificity leading to criticism for poor quality.2 The most accepted sample preparation for determining the free concentration of these hormones involves the lengthy process of equilibrium dialysis prior to quantification by LC-MS/MS. This application note presents a novel approach to accurately monitor and determine the free T3 and T4 in under an hour of sample preparation using a technique called BioSPME, bioanalytical solid phase microextraction, prior to analysis by LC-MS/MS. Figure 2 shows the Supel™ BioSPME C18 device utilized for sample preparation.

Chemical structures of three thyroid hormones: L-Thyroxine (T4), 3, 5, 3'-triiodo-L-thyronine (T3), and 3, 3', 5'-triiodo-L-thyronine (rT3). Each structure features two aromatic rings connected by an oxygen atom. The left ring includes variable substituents labeled as R1 and R2, and an iodine atom at the third position. The right ring has an iodine atom at the fourth position, along with a side chain containing an amino group (NH2) and a carboxyl group (COOH). Specifically, L-Thyroxine (T4) has iodine atoms at both R1 and R2 positions, 3, 5, 3'-triiodo-L-thyronine (T3) has a hydrogen at R1 and an iodine at R2, and 3, 3', 5'-triiodo-L-thyronine (rT3) has an iodine at R1 and a hydrogen at R2.

Figure 1.Structure of T4, T3, and rT3.

The BioSPME device is a 96-pin array with a 2 mm C18 sorbent and biocompatible coating that is on the outside of each pin. This device operates by direct immersion into the sample solution and requires no active pipetting as there is no liquid transfer in or out of pin. It provides a quick and efficient means to deliver a clean sample with minimal matrix effects for analysis from human serum or plasma.

A rectangular plastic construction that holds 96 thin, white, needle-like pins extending from the bottom. The device has a label on the side, featuring the brand name Supelco and the product name BioSPME. There is also a barcode on one side of the tray. The overall appearance is clean and white, designed for use in scientific or laboratory settings.
A close-up view of two slender, transparent pins positioned vertically against a black background. Each pin has a slightly rounded tip and features a visible 2 mm coating near the tip, indicative of a C18 coating. The coating appears as a faint, slightly darker band on the otherwise smooth and uniform surface of the pins. The pins are evenly spaced and parallel to each other, showcasing their fine and precise construction.

Figure 2. (left) Supel™ BioSPME device. (right) close-up of two pins to show the C18 coating of 2 mm on the outside of the pin.

Experimental

Handling and storage of serum samples

Bulk serum, 50 mL, arrived frozen and were thawed and separated into 4 mL aliquots in 5 mL polypropylene cryotubes. A 4 mL aliquot of each serum was submitted to an external clinical laboratory for independent determination of free T3 and free T4 by equilibrium dialysis, ED, prior to quantification by LC-MS/MS. The remainder 4 mL aliquots of the serums were stored in a -80 °C freezer until utilization.

Preparation of working stock solutions and internal standards

Stock solutions of T3 and T4 started with 100 µg/mL ampules of the corresponding Cerilliant® solutions (T-074, T-073). Dilution of the stock solutions to 100 ng/mL were prepared in methanol containing 0.2% ammonia and aliquoted into 1 mL glass vials and stored in the -20 °C freezer. A new aliquot of these frozen diluted standards was used daily.

Three internal standards (Figure 3), 13C6-T4 (T-076),13C6-T3 (T-077), and 13C6-rT3 (T-078)started as individual 100 µg/mL ampules of the corresponding Cerilliant® solution. A diluted mixture with a final concentration of 100 ng/mL

13C6-T4, 50 ng/mL 13C6-T3, and 50 ng/mL 13C6-rT3 was prepared in methanol containing 0.2% ammonia and aliquoted into 1 mL glass vials and stored in -20 °C freezer. A new aliquot of the frozen diluted internal standard mixture was used daily.

Chemical structures of three internal standards, each with a 13C6 substitution on the internal phenyl ring. These structures consist of two aromatic rings connected by an oxygen atom. The left ring includes variable substituents labeled as R1 and R2, and an iodine atom at the third position. The right ring, containing the 13C6 substitution, has an iodine atom at the fourth position, a side chain with an amino group (NH2), and a carboxyl group (COOH). The internal standards are identified as 13C6-T4 when R1 = I and R2 = I, 13C6-T3 when R1 = H and R2 = I, and 13C6-rT3 when R1 = I and R2 = H.

Figure 3.Structure of three internal standards used. All three internal standards have the 13C6 substitution in the same location, the internal phenyl ring.

LC-MS/MS Method

Samples prepared in a final solution of methanol were diluted to 50:50 with water using a needle command sequence of the Agilent 1290 Autosampler. Separation of the analytes and internal standard mixture utilized an Ascentis® Express Biphenyl column (10 cm x 2.1 mm I.D., 2.7 µm) on an Agilent 1290 (Table 1 & 2). The transitions monitored, along with the source parameters of the Sciex Triple Quad™ 6500+ are listed in Table 3 & 4.

Table 1.LC Condition
Table 2.Injection sequence
Table 3.Mass Spectrometry Parameters
Table 4.MS Transitions for the analytes

External calibration

Using a previously unused frozen aliquot of 100 ng/mL T4 and T3, a daily working solution of 4 ng/mL in methanol was prepared. Similarly, an unused frozen aliquot of the internal standard (100 ng/mL 13C6-T4, 50 ng/mL 13C6-T3, and 50 ng/mL 13C6-rT3) was used to prepare a 400/200/200 pg/mL internal standard solution. Separate calibrator solutions of T3 and T4 (concentration range of 2 to 80 pg/mL) with an IS concentration of 40/20/20 pg/mL were prepared using volumetric glassware. Calibrators were loaded in duplicate and processed as described under the LC-MS/ MS section.

Extracted calibration curve and preparation of sample plate

Using the 4 ng/mL of T3 and T4 in methanol as described in the previous section, calibrators in the range of 2 to 80 pg/mL were prepared in a 7.5 mM HEPES aqueous solution adjusted to pH 7.5. The calibrator solutions were loaded in duplicate at a volume of 200 µL in the sample plate.

Serum samples were pH adjusted by diluting 5% (v/v) with a 1.15 M HEPES solution. pH of serum solutions prior to extraction at room temperature were in the range of 7.3 – 7.4. The sample plate was prepared by first loading 10 µL of 1.15 M HEPES solution prior to 190 µL of the respective serum. The sample plate was agitated for 3 minutes at 300 rpm prior to starting the BioSPME sample preparation.

BioSPME Sample Preparation

An overview of the BioSPME process is shown in Table 5. A Hamilton® Microlab® STARlet liquid handler was programmed to perform the method (an overview of the steps is shown in Table 6 and deck and consumable view shown in Figure 4). Briefly, the Supel™ BioSPME device was conditioned for 20 min in acetonitrile, followed by a 10 second wash in water. The analytes were extracted into the C18 phase of the BioSPME device over the course of a predetermined time at 1200 rpm at 37 °C using a 3 mm orbital radius Hamilton Heated Shaker. The BioSPME device then underwent a wash in the same water plate as wash one for 60 seconds before being returned to the home position. The desorption plate is then filled with 40 µL of methanol containing internal standards described earlier. The analytes are then desorbed from the BioSPME device under static conditions in 5 min. The desorption plate is covered with seal tape and loaded onto the LC-MS/MS instrument for analysis.

Table 5.Overview of the BioSPME sample preparation steps.
Table 6.BioSPME extraction method utilizing a Hamilton® STARlet liquid handler
A representation of a Hamilton® Microlab® STARlet deck layout with consumables arranged on a dark gray background. The layout includes multiple sections, each labeled with numbers and containing consumable items in distinct configurations. On the left, there is a column with smaller illustrations of consumable trays, including a "Standard" tray at the bottom in blue with rectangular wells. To the right, a grid layout is shown, with positions numbered from 1 to 11. Positions 2, 6, and 9 feature blue trays labeled "DW 96" with a grid of light blue wells. Positions 3, 4, 5, and 7 contain orange well configurations within similarly labeled "DW 96" trays, with varying orientations and arrangements of the orange wells. Position 8 shows empty slots with no wells, while positions 10 and 11 feature tall, vertical blue racks with cylindrical containers or tubes.

Figure 4. Hamilton® Microlab® STARlet deck layout with consumables (position descriptions see Table 7).

Table 7.Hamilton® Microlab® STARlet deck layout – Position descriptions

Method Development

Time Curve Study

A sample plate containing serum sample L-680F, pH adjusted, and a T4 calibrator prepared at 30 pg/mL were prepared and extracted as described earlier. Four different extraction time points (5, 10, 20, 30 min) were utilized. At each time point, there were n=5 serum and n=3 of the 30 pg/mL calibrator. Concentration extracted were compared to a 5-point external calibration curve as described earlier.

Reproducibility Study

Four independent calibrators were prepared in a 7.5 mM HEPES solution, pH 7.5. Six bulk sera that had externally determined free T3 and free T4 values by ED-LC-MS/MS were extracted a total of five times over multiple weeks and multiple freeze-thaw cycles. The sera pH was adjusted to 7.3 prior to extraction using a 1.15 M HEPES (5% by v/v) solution. Serum samples were loaded in quadruplets. Sample preparation was executed as described earlier.

Results and Discussion

Method Development

Method development focused on two keys parameters, extraction time and reproducibility. While much work was conducted in changing solvents and organic modifiers in the BioSPME process, the factor that had the largest impact was pH. The pH adjustment was influenced by CLSI-C45-A3, Katleen Van Uytfanghe4, and Bingfang Yue5. Previously published work has also stated the impact of chloride ions and phosphate ions.6 As a direct result, phosphate buffered saline was removed from consideration and replaced with HEPES (4-(2-hydroxyethyl)-1-piperazineethanesulfonic acid); as previous reports listed that it had no impact on free thyroxine levels.

Time Curve

Using the external calibration curve, the extracted T4 values for the serum and extracted calibrator solution were determined at each time point as shown in Figure 5 and data in Table 8. After 20 minutes, it is seen that the calibrator in HEPES and serum sample level off.

A representation of a Hamilton® Microlab® STARlet deck layout with consumables arranged on a dark gray background. The layout includes multiple sections, each labeled with numbers and containing consumable items in distinct configurations. On the left, there is a column with smaller illustrations of consumable trays, including a "Standard" tray at the bottom in blue with rectangular wells. To the right, a grid layout is shown, with positions numbered from 1 to 11. Positions 2, 6, and 9 feature blue trays labeled "DW 96" with a grid of light blue wells. Positions 3, 4, 5, and 7 contain orange well configurations within similarly labeled "DW 96" trays, with varying orientations and arrangements of the orange wells. Position 8 shows empty slots with no wells, while positions 10 and 11 feature tall, vertical blue racks with cylindrical containers or tubes.

Figure 5.Time curve showing the amount of T4 extracted from serum sample L-680F (triangles) or 30 pg/mL calibrator (circles) prepared in HEPES solution.

Table 8.Concentration of T4, pg/mL, extracted against external calibration curve.

Reproducibility and Multiple Freeze Thaws

As highlighted earlier, a multiday freeze/thaw reproducibility study was conducted for six different sera that were previously tested externally by a validated equilibrium-dialysis LC-MS/MS method.

Figure 6 shows an example chromatogram after sample preparation by the Supel™ BioSPME device. The use of the 10 cm biphenyl column allowed separation of the isobars T3 and rT3 in addition to T4.

A chromatogram displaying the extraction results of a sample, plotted with "Retention Time (min)" on the x-axis ranging from 0.0 to 4.0 minutes and "Peak Area Counts" on the y-axis spanning from 0.0 to 8.0 × 104. Three primary peaks are visible, labeled as 1, 2, and 3, along with their corresponding internal standards (IS): 1-IS, 2-IS, and 3-IS. The peak labeled "1" is in cyan, and its internal standard "1-IS" is marked in yellow, both located at around 1.5 minutes. The peak "2-IS" in yellow appears at about 2 minutes. The peak labeled "3" in green and its internal standard "3-IS" in blue are observed near 2.5 minutes, with "3" being the tallest peak in the graph.

Figure 6.Representative chromatogram after extraction of L-676M. 1 is T3, 1-IS is 13C6-T3, 2-IS is 13C6-rT3, 3 is T4 and 3-IS is 13C6-T4.

In Table 9, the effect of dilution or no dilution with 5% 1.15 M HEPES solution can be seen. Over the three-day individual testing period, the pH of the sera was consistently between 7.3 and 7.4 prior to extraction.

Table 9.pH of bulk serum samples of unadjusted and adjusted with 5% 1.15 M HEPES solution.

Another important feature is the consistency in the extraction and sample preparation of the calibrators between days. As shown in Table 10, the reproducibility of the slopes over the course of the days for both quantitative and qualifier transitions are below 5%.

Table 10.Slopes of individual and average extracted calibration curves for monitored transitions during the reproducibility and multiple freeze thaw studies.

With showing the consistency of the sample preparation and extraction of the calibrators and LC-MS/MS studies, the results and reproducibility for the six sera tested in quadruplets over the course of five days is shown in Tables 11 and 12, as well as a correlation graph in Figure 7. For the free T3 (range of 1.57 – 7.62 pg/mL), the interday RSD (%) was < 10%, while for free T4 (range of 4.4 – 60.3 pg/mL), the interday RSD (%) was less than 11%.

Table 11.Comparison of free T3 values, pg/mL, and reproducibility after multiple-day extraction (n=5) and freeze-thaws.
Table 12.Comparison of free T4 values, pg/mL, and reproducibility after multiple-day extraction (n=5) and freeze-thaws.

Using the data for the externally determined equilibrium dialysis prepared and internally prepared Supel™ BioSPME results, Figure 7 highlights the correlation between the two methods for the two analytes. For the two analytes, an R2 of >0.977 for both analytes show the strong correlation between the two methods. The slopes between the two methods (0.809 – 1.05) show the two methods further provide comparable results as well.

A scatter plot for free T3 with a green dotted trendline. The x-axis is labeled "fT3, pg/mL, ED-LC-MS/MS" and ranges from 0 to 9. The y-axis is labeled "fT3, pg/mL, BioSPME-LC-MS/MS" and also ranges from 0 to 9. Multiple green circular data points are scattered along the diagonal trendline, which has the equation y = 1.054x - 0.087 and an R² value of 0.981, displayed near the upper-right corner of the plot. The data points follow the trendline closely, indicating a strong linear correlation. The plot is displayed on a white background with clear gridlines for better visibility.
A scatter plot for free T4with a light blue dotted trendline. The x-axis is labeled "fT4, pg/mL, ED-LC-MS/MS" and spans from 0 to 70. The y-axis is labeled "fT4, pg/mL, BioSPME-LC-MS/MS" and ranges from 0 to 70. Several light pink circular data points are scattered along the trendline, which is positioned diagonally across the plot. The equation of the trendline, "y = 0.809x + 2.016," and the R² value of 0.977 are displayed near the top-right area of the plot. The data points generally align closely with the trendline, indicating a strong positive linear correlation.

Figure 7. Correlation of free T3 (top) and free T4 (bottom) against two different sample preparation techniques. The ED-LC-MS/MS were determined externally by a validated method and laboratory.

Conclusion

In the past, free thyroid hormones levels, specifically free T3 and free T4, have been tested individually. However, there is now a method of sample preparation that allows for a single test to be conducted, offering a more efficient and convenient process for obtaining results. This technique, known as Supel™ BioSPME, also significantly reduces the sample preparation time from hours (as with equilibrium dialysis) to less than an hour. Consequently, this method has the potential to improve patient care by enabling quicker return of test results.

See also our webinar recording:

BioSPME: A Novel Sample Preparation of Clinically Relevant Analytes

Related Products
Loading

REFERENCES

1.
Welsh KJ, Soldin SJ. 2016. DIAGNOSIS OF ENDOCRINE DISEASE: How reliable are free thyroid and total T3 hormone assays?. European Journal of Endocrinology. 175(6):R255-R263. https://doi.org/10.1530/eje-16-0193
2.
Soldin OP, Soldin SJ. 2011. Thyroid hormone testing by tandem mass spectrometry. Clinical Biochemistry. 44(1):89-94. https://doi.org/10.1016/j.clinbiochem.2010.07.020
3.
CLSI Measurement of Free Thyroid Hormones: Approved Guidline. CLSI document C45-A, Wayne, PA: Clinical and Laboratory Standards Institute, 2004.. [Internet]. Available from: https://clsi.org/standards/products/clinical-chemistry-and-toxicology/documents/c45/
4.
Van Uytfanghe K, Stöckl D, Ross HA, Thienpont LM. 2006. Use of Frozen Sera for FT4 Standardization: Investigation by Equilibrium Dialysis Combined with Isotope Dilution-Mass Spectrometry and Immunoassay. Clinical Chemistry. 52(9):1817-1821. https://doi.org/10.1373/clinchem.2006.070425
5.
Yue B, Rockwood AL, Sandrock T, La’ulu SL, Kushnir MM, Meikle AW. 2008. Free Thyroid Hormones in Serum by Direct Equilibrium Dialysis and Online Solid-Phase Extraction–Liquid Chromatography/Tandem Mass Spectrometry. Clinical Chemistry. 54(4):642-651. https://doi.org/10.1373/clinchem.2007.098293
6.
SPAULDING SW, GREGERMAN RI. 1972. Free Thyroxine in Serum by Equilibrium Dialysis: Effects of Dilution, Specific Ions and Inhibitors of Binding. J. Clin. Endocrinol. Metab. 34(6):974-982. https://doi.org/10.1210/jcem-34-6-974
Sign In To Continue

To continue reading please sign in or create an account.

Don't Have An Account?