Introduction

Hormones are natural substances formed in the body, with the role of chemical messengers released by endocrine glands, which can act on target cells from a distance. Besides cell communication, hormones are indispensable for complete and harmonious human growth. Three of the most important sex steroid hormones are 17β-estradiol (E2), testosterone (T2) and 5α-dihydrotestosterone (DHT). These derivates of cholesterol are responsible for the proper development of sexual characteristics and numerous essential processes in human development and reproduction. Clegg et al found a correlation between the steroid hormones and obesity1,2,3,4.

The accurate measurement of the sex hormones in biological samples is important in evaluating ovarian, prostate and testicular function5,6. E2 is checked in clinical laboratories for female infertility and ovarian tumor diagnosis, therefore E2 is a clinically important analyte7. DHT is a biomarker for benign prostatic hyperplasia (BPH) and for prostatic cancer (PCa). DHT formation is inhibited by the 5α-reductase inhibitors, so it is essential to measure the T2 levels in the body.

In children, measurement of serum E2 and T2 is used in the clinical diagnosis of precocious or delayed puberty in girls and boys, respectively8,9. In recent years, the use of saliva as a non-invasive alternative matrix to measure steroid hormones has gained attention10, though there are concerns about specificity and sensitivity of classical immunological (including ELISA) or liquid chromatography tandem mass spectrometry based methods for measuring the low androgen and estrogen levels in children's saliva11. Therefore it is a real need to develop high sensitive and selective methods that can be used for reliable assay of steroid hormones in children's saliva.

Stochastic microsensors represent a modern tool for qualitative and quantitative analysis of targeted analytes, with a better sensitivity and selectivity than classical electrochemical sensors. Their utilization in biomedical analysis represents a good alternative to chromatographic methods12,13,14,15,16,17,18,19,20,21,22. Stochastic response is based on channel conductivity, according to the mechanism described previously by Stefan-van Staden and Moldoveanu21. The stochastic sensors are highly selective for the assay of biological substances, because the value of toff (known as signature of the analyte) depends on many parameters of the analyte such as: geometry and size of molecule, capacity of unfolding, velocity related to the speed of passing through the channel; accordingly, there will be difficult to find two molecules that will have the same signature21,23,24.

In this paper we propose three tools based on stochastic microsensors designed using diamond paste and three different electroactive materials: maltodextrin (MD), α-cyclodextrin (α-CD) and 5,10,15,20-tetraphenyl-21H,23H porphyrin (P), for the assay of steroid hormones in saliva samples from children. Diamond powder is used as a matrix in the design of stochastic microsensors, due to its particular electrochemical proprieties, such as wide potential range, low background current and the ability of reaching low detection limits13,22. The monocrystalline form of diamond was preferred due to the diamond monocrystal properties proprieties, such as enhanced holes and electron mobilities25,26. Monocrystallin diamond paste sensors have been used in differential potentiometric voltammetry mode for the assay of biological compounds such as: L-fucose and D-fucose15, sildenafil citrate13,14 and neurotransmitters16,17,18,19. To our knowledge, the approach has not been used previously to assay steroid hormones in biological matrices such as saliva. Here we show that the proposed method and tools can be reliable used for the assay of the three hormones in children's saliva and can be employed in clinics for early detection and prevention of problems related to children such as early puberty, endocrin disorders and obesity.

Experimental

Materials and reagents

All chemicals were of analytical grade. 17β-estradiol (E2), testosterone (T2) and 5α-dihydrotestosterone (DHT), maltodextrin (MD), α-cyclodextrin (α-CD) and 5,10,15,20-tetraphenyl-21H,23H porphyrin (P), natural monocrystalline diamond powder were purchased from Sigma Aldrich (Milwaukee, USA) and paraffin oil (d420, 0,86 gxcm−1) from Fluka (Buchs, Switzerland).

The hormones solutions were firstly dissolved in dimethylsulfoxide (DMSO), with a concentration of 10 mmol L−1 T2 and DHT and 6.59 mmol L−1 E2. For the preparation of solutions with different concentrations (10−16 mol L−1–10−4 mol L−1), we used deionized water and the serial dillution technique.

Apparatus and methods

All measurements were performed with an AUTOLAB/PGSTAT 12 (Utrecht, The Netherlands) connected to a personal computer with a GPES software, used to record the measurements. A three electrode system electrochemical cell was employed. Ag/AgCl (0.1 mol L−1 KCl) electrode serves as a reference electrode in the cell and a platinum wire as a counter electrode in the cell, respectively.

Design of stochastic microsensors

Natural monocrystalline diamond powder was mixed with paraffin oil until a homogenous paste was formed. 25 µL of 10−3 mol/L electroactive material solution (maltodextrin (MD), α-cyclodextrin (α-CD) and 5,10,15,20-tetraphenyl-21H,23H porphyrin (P)) were added to 100 mg of the paste to give the modified diamond pastes. Three plastic tubes (100 µm inner diameter) were filled with the three modified pastes and the electric contact was obtained by inserting a silver (0.5 mm in diameter) wire into the paste. Schematic representation of the microsensors is presented in Figure 1. Before each measurement, the microsensors were cleaned with deionized water. When not in use, they were kept at room temperature, in a dry place.

Figure 1
figure 1

Schematic representation of the stochastic microsensor.

Samples

Saliva samples were obtained from children aged 4–10 years (6 boys, 6 girls) collected at the Universitary Hospital in Bucharest (ethics committee approval nr. 11/2013). Saliva collection was done in the morning around 8 am before eating or drinking for all subjects included in the study. Saliva sampling was performed following a mouth rinse with 5 ml of water to wash out any debris or exfoliated cells. From each subject around 1 ml of unstimulated whole saliva was collected. The sample was divided in two: one part was used for the assay of hormones using stochastic sensing and the other one was centrifuged at 2000 rpm for 10 min and the three hormones were analysed using a standard method (see below).

Standard method

5α-dihydrotestosterone, testosterone and estradiol were analysed using an enzyme immunoassay quantitative (ELISA) kit for DHT, E2 and T2 (IBL International GMBH, Hamburg, Germany) following manufacturer instructions. Briefly, 0.2 mL saliva samples and manufacturer provided standards were pipetted into wells precoated with an antibody specific for the tested hormone. After enzyme conjugate addition the wells were incubated at room temperature for one hour. Following a washing step with the provided buffer a substrate solution was added to wells. The color developed in proportion to the amount of the hormone bound in the first step. When color development was stopped, the optical density was determined using a microplate reader set to 450 nm. The limits of determination using ELISA where: 25 pg/mL for 5α-dihydrotestosterone, 6.4 pg/mL for testosterone and and 1 pg/mL for estradiol.

Results and discussion

Response characteristics of stochastic microsensors

The diagrams obtained when a potential of 125 mV was applied were specific for stochastic sensors. The response of the proposed microsensors was based on channel conductivity: the current flowing through a channel under an applied potential of 125 mV is altered when DHT, E2 and T2 are binding on the channel wall. The molecular recognition of the hormones is taking part in two stages21: stage 1 (molecular recognition stage) on which the hormone (DHT, E2 and T2) extracted from the solution into the membrane-solution interface is blocking the channel and the intensity of the current is 0 for a certain period of time named signature of the analyte (toff). The value of toff is used for the qualitative assay of DHT, E2 and T2 in the diagrams obtained for children's saliva analysis. When DHT, E2 and T2 are interacting with the wall of the channel (Stage 2, bounding stage), the following equilibrium equations (equations (1), (2), (3)) are taking place:

where Ch is the channel and i is the interface. The time of equilibrium for interaction with the channel process is defined as ton and is used for the quantitative assay of DHT, E2 and T2.

Signatures of DHT, E2 and T2 (toff values) are shown in Table 1. Standard solutions of each hormone, in the concentration range 0.1 fmol L−1 – 0.1 mmol L−1, were analysed to obtain the calibration equations for all three diamond paste based microsensors. The equations of calibration with the correlation coefficients, the linear concentration ranges, the sensitivities and the limits of determination for DHT, E2 and T2 are shown in Table 1.

Table 1 Response characteristics of stochastic microsensors used for the assay of DHT, T2 and E2

The microsensor based on MD showed the highest sensitivity for the assay of DHT (2.65 × 1011 s mol−1 L) and T2 (1.95 × 108 s mol−1 L), while for the assay of E2 the highest sensitivity was obtained using the microsensor based on porphyrin (2.51 × 109 s mol−1 L). The lowest determination limits were obtained using MD based microsensor for the assay of DHT (1 fmol/L) and T2 (1 pmol/L), while for the assay of E2 the lower limit of determination was achieved by using the porphyrin and the α-CD based microsensors (66 fmol/L).

A high reproducibility of all miscrosensors was recorded, RSD (%) values of the slopes obtained for the equations of calibration (Table 1), when the microsensors were used for 6 months dayly, were less than 1%. Also, the design was highly reproducible: three pastes of each microsensors were made and tested each for a period of three months and in each case, the RSD (%) values were less than 0.01%.

Analytical applications

Pattern recognition of the three hormones in saliva samples from 6 boys and 6 girls (age 4–10) was done using stochastic microsensors, based on their signatures shown in Table 1. Patterns were recorded for each saliva sample, followed by the identification of signature (toff values) of each hormone and its quantification (based on ton values) using the equation of calibration of the stochastic sensors. Examples of pattern recorded using stochastic sensors are given in Figure 2. There is a good correlation between the results obtained using the stochastic sensors, for each sample analysed (Table 2). The standard method (ELISA) was not able to determined accurately the hormones, all amounts being under its limit of determination. Therefore, the problem that the pattern recognition with stochastic microsensors solved is: the assay at very low concentration of DHT, T2 and E2 from childen's saliva samples. The proposed method is more accurate and reliable (RSD, % values are far lower in the case of the proposed method than those obtained for standard method) when used for very low concentrations compared with ELISA and can be reliable used for the assay of the hormones in saliva samples.

Table 2 Determination of T2, DHT and E2 in children's saliva using stochastic microsensors. All results are in pg/mL
Figure 2
figure 2

Pattern recognition of the hormones in saliva sample using the stochastic microsensors based on (a) porphyrin and diamond paste; (b) maltodextrin and diamond paste; and (c) α-cyclodextrin and diamond paste.

Conclusions

The paper proposed three stochastic microsensors based on modified diamond paste with porphyrin, maltodextrin and α-cyclodextrin for the assay of estradiol (E2), testosterone (T2) and dihydrotestosterone (DHT) in saliva. The limits of quantification of the hormones are far lower than those recorded for the ELISA – standard method, which made them available for the assay of the hormones in the children saliva (the amounts of these hormones in children saliva are far lower than in the adults saliva and frequently under the limit of quantification of the ELISA standard method). The pattern recognition of the three hormones in saliva samples was performed by identification of the signatures of the hormones in the patterns recorded using stochastic sensors. The quantification was reliable; very good correlations between the results were obtained by utilization of the three stochastic microsensors. The proposed pattern recognition method performed using stochastic microsensors has great future for analysis of such compounds in children saliva, making possible early detection of hormone levels and related disorders such as early onset or delayed puberty, obesity and endocrine diseases.