key: cord-0940771-tw6d0vg0 authors: Amouzadeh Tabrizi, Mahmoud; Acedo, Pablo title: Highly Sensitive RNA-Based Electrochemical Aptasensor for the Determination of C-Reactive Protein Using Carbon Nanofiber-Chitosan Modified Screen-Printed Electrode date: 2022-01-27 journal: Nanomaterials (Basel) DOI: 10.3390/nano12030415 sha: 0c8d1119d630a00601dee67971dbce11a214b5e8 doc_id: 940771 cord_uid: tw6d0vg0 C-reactive protein (CRP) is one of the biomarkers related to coronavirus disease 2019 (COVID-19). Therefore, it is crucial to develop a highly sensitive, selective, and cost-effective biosensor for the determination of CRP. In this study, we designed an electrochemical aptasensor. For this purpose, the surface of a carbon screen-printed electrode was first modified with a carbon nanofiber-chitosan (CNFs-CHIT) nanocomposite. After that, the amino-terminal RNA aptamer probes were linked to the amino groups of CHIT via glutaraldehyde as the cross-linker. Finally, methylene blue (MB) as a redox probe was self-assembled on the surface of the aptasensor. The obtained results indicated that the CNFs-CHIT nanocomposite increased the surface coverage of the aptamer up to 5.9 times. The square-wave voltammetry was used for the measurement of CRP concentration in the linear range of 1.0–150.0 pM. The obtained results indicated that the signal had a logarithmic relationship with the concentration of CRP. The limit of detection (LOD) was obtained to be 0.37 pM. The dissociation constant (K(d)) that demonstrates the affinity of the aptamer probe to its target was found to be 0.93 pM. The analytical performances of the proposed RNA aptasensor were better than the previously reported aptasensors for CRP. The proposed aptasensor was also applied for the determination of CRP in the human plasma samples. The obtained results indicated that there were no statistically significant differences between the responses of the proposed RNA aptasensor and an enzyme-linked immunosorbent assay kit (ELISA). The analytical performances of the proposed RNA aptasensor described in this paper are better than previously reported aptasensors for CRP determination. Sepsisis a potentially fatal response of the body to an infection that can lead to death in the framework of many diseases like coronavirus disease 2019 (COVID-19) [1] . The common method for recognizing sepsis is the measurement of the concentration of inflammation biomarkers in the human blood sample. C-reactive protein (CRP) is one of the common inflammation biomarkers. CRP levels higher than 10 ppm (86.8 nM) are considered a sign of serious infection [2] . Therefore, it is crucial to design highly sensitive, selective, and cost-effective sensors. Aptasensors are made with a nucleic acid chain as bioreceptors [3] have been used for CRP measurement [4] [5] [6] . The aptasensors have several advantages compared to antibody-based biosensors (immunosensors) including: (1) They are smaller than antibodies (10-fold) [7] that help immobilize more of them on the surface of a transducer; (2) they can interact with redox indicators and self-assemble them on the surface of the transducer (like methylene blue, hexaammine ruthenium [8, 9] ); (3) they are modifiable with different functional groups like amine and thiol [3] ; and (4) they are a low-cost bioreceptor. In the fabrication of an aptasensor, the aptamer is immobilized on the surface of a transducer. The MB, CHIT, potassium chloride (KCl), calcium chloride (CaCl 2 ), sodium chloride (NaCl), sodium dihydrogen phosphate (NaH 2 PO 4 ), Tris(hydroxymethyl)aminomethane (Tris), sodium acetate (NaAc), and GLU were purchased from Cymit Química (Barcelona, Spain). CNFs, bovine serum albumin (BSA), human serum albumin (HSA), human immunoglobulin G (HIgG), and CRP (~115 kDa) were purchased from Sigma Aldrich (Madrid, Spain). CRP-Human Enzyme-Linked Immunosorbent Assay (CRP-ELISA) was obtained from Thermo Fisher Scientific (Waltham, MA, USA). Carbon screen-printed electrodes (CSPE) were purchased from Metrohm-Drop Sens (Llanera, Spain). The amine terminal RNA aptamer probe (purified by HPLC) was purchased from Nzytech (Lisboa, Portugal). The RNA aptamer sequence was: 5'-NH 2 -(CH 2 ) 6 -GCC-UGU-AAG-GUG-GUC-GGU-GUG-GCG-AGU-GUG-UUA-GGA-GAG-AUU-GC-3' [8] . Double deionized (DI) water (18.6 MΩ) was used throughout. The cyclic voltammetry (CV) and square wave voltammetry (SWV) studies were performed using a µStat 300 Bipotentiostat (Metrohm-Drop Sens, Llanera, Spain). The electrochemical impedance spectroscopy (EIS) studies were performed using ISX-3 impedance analyzer (Sciospec, Bennewitz, Germany). Typical EIS experiments were presented in the form of the Nyquist plot and recorded in a 16.0 mM Fe(CN) 6 4−/3− solution as the redox probe. An alternating current (AC) voltage of 10 mV and a direct current (DC) voltage of 0.17 Vwereapplied over a frequency range of 100 kHz to 0.1 Hz. The EIS data were analyzed using EIS spectrum analyzer (EISSA) software. The surface morphologies of the electrodes were characterized using a scanning electron microscopy (SEM) (Field Electron and Ion (FEI, Hillsboro, OR, USA)). The elemental analysis was obtained using an energy dispersive analysis of X-rays (EDS) (EDAX, Mahwah, NJ, USA).The attenuated total reflectance spectrum (ATR) study was performed by using a Nicolet iS50 Fourier transform infrared spectrometer (Thermo Fisher Scientific, Waltham, MA, USA). A 0.01 g amount of CNF was added to 4 mL of CHIT solution (0.5%) and the mixture was then dispersed for 1 h. After that, 5 µL CNFs-CHIT solution was dropped onto the surface of the CSPE and allowed to dry at ambient temperature. After rinsing the CSPE/CNFs-CHIT with DI water, it was immersed in a 2.5% GLU solution (phosphatebuffered saline (PBS), 10X, pH 7.4) for 6 h. During that process, the primary amine groups of the CHIT interacted with the aldehyde groups of GLU via the Shiff base interaction [26] . The CSPE/CNFs-CHIT-GLU electrode was then rinsed with DI water to wash away any non-bonded GLU. Subsequently, 100 µL amino-terminal of RNA aptamer solution (100 µM, 1 mM Mg 2+ , 0.1 M NaAc, pH 7.4) was dropped onto the surface of the CSPE/CNFs-CHIT-GLU to interact with the amino-terminal of RNA aptamers overnight. GLU acts as a cross-linker agent to attach the amino-terminal aptamer probes to the amino groups of the CHIT. After washing the electrode, 100 µL BSA solution (0.1 mg mL −1 , pH 7.4) was dropped onto the electrode surface to block the non-reacted aldehyde group of GLU and avoid any non-specific binding interaction during the measurement of the CRP concentration. After that, the electrode was washed and immersed in 0.1 mM MB (10X PBS) for 1 h at ambient temperature to interact with the positively charged MB with negatively charged phosphate groups of the aptamer [21] . The CSPE/CNFs-CHIT-GLU-RNA aptamer-MB was then washed several times with PBS to wash away any loosely attached MB. The fabricated aptasensor was finally dried and stored at 4 • C when not in use. To measure the CRP concentration, the CSPE/CNFs-CHIT-GLU-RNA aptamer-MB was immersed in different concentrations of CRP solution (0.1 M Tris buffer, pH 7.4, 2 mM CaCl 2 ) to incubate the CRP with the immobilized aptamer probes. During this process, the complex of the MB-phosphate group of nucleotides will break due to the high affinity of the CRP to the RNA aptamer. In the absence of the CRP, the amount of adsorbed MB is high. Therefore, the electrochemical signal of the adsorbed MB is high. As the CSPE/CNFs-CHIT-GLU-RNA aptamer-MB is immersed in a CRP solution, the MB will release on the surface of the aptasensor to the solution and consequently, the electrochemical signal of the aptasensor will decrease. Since the amount of adsorbed MB on the aptasensor will decrease by increasing the CRP concentration, the proposed biosensor is a signal-off electrochemical aptasensor. The experimental protocol for the fabrication of the CSPE/CNFs-CHIT-GLU-RNA aptamer-MB is illustrated in Figure 1 . Figure S1A ,B show the results of the CVs of the CSPE (A) and the CSPE/CNFs-CHIT (B) in a PBS containing Fe(CN) 6 3−/4− (16.0 mM (16.0 × 10 −6 mol cm −3 )) at different scan rates (0.01-0.15 V s −1 ). As can be seen, both the oxidation (I pa ) and reduction peak (I pc ) of Fe(CN) 6 3−/4− increased versus the square root of the scan rate (υ 1/2 ), indicating that the electrochemical kinetics are controlled by the diffusion of Fe(CN) 6 3−/4− to the surface of the CSPE ( Figure S1C ) and the CSPE/CNFs-CHIT ( Figure S1D ). The electro-active area of the CSPE and the CSPE/CNFs-CHIT were also obtained by using the Randles-Ševčík equation (Equation (1)) for quasi-reversible electrochemical processes by drawing the I p quasi versus the square root of scan rate (υ 1/2 ) [27] . This can use the following equation: where I p quasi is the peak current, n is the number of electrons (n = 1), F is the Faraday constant (96,485 C mol −1 ), A eas is the electroactive surface area of the electrode, C is the concentration of Fe(CN) 6 3−/4− (16.0 × 10 −6 mol cm −3 ), D is the diffusion coefficient (7.6 × 10 −6 cm 2 s −1 ), υ is the scan rate (V s −1 ), R is the gas constant (8.314 J K −1 mol −1 ), and T is the temperature (298 Kelvin). The A eas values for the CSPE and the CSPE/CNF-CHIT were found to be 0.14 cm −2 and 0.25 cm −2 , respectively. Moreover, the roughness factor (RF) of the CSPE and the CSPE/CNFs-CHIT were found to be 1.12 and 2.0, respectively [28] . This can use the following equation: where the geometric surface area (A gsa ) of the CSPE is 0.125 cm −2 . These results indicate that the CNFs-CHIT nanocomposite improved the electrochemical performances of the electrode. Moreover, the slopes of the log I pa versus log v curves for the CSPE ( Figure S1E ) and the CSPE/CNFs-CHIT ( Figure S1F ) were found to be 0.489 and 0.56 µA (Vs −1 ) −1 , respectively, which are very close to the theoretical value of 0.5, which is specified for an ideal reaction fora diffusion-controlled process [29] . The SEM images of the CSPE (A, B) and the CSPE/CNFs-CHIT (C, D) are shown in Figure 2 . As shown in Figure 2A ,B, the CSPE has a porous structure when compared to a glassy carbon electrode that has a smooth structure ( Figure S2A ,B). Moreover, Figure 2C ,D show the SEM images of the CSPE/CNFs-CHIT. As can be seen, the surface of the electrode was modified with the CNFs uniformly and increased the RF of the electrode. The average diameter size of the CNFs was 102 ± 24 nm. Since CNFs have a high surface area and low electron transfer resistance, the electrochemical performance of the CSPE/CNFs-CHIT should be improved compared to the CSPE. The elemental analysis of the CSPE (A), the CSEP/CNFs (B), the CSPE/CNFs-CHIT (C), and the CSPE/CNFs-CHIT-GLU-RNA aptamer (D) are shown in Figure S3 . It can be seen that the EDS of the CSPE/CNFs-CHIT-GLU-RNA aptamer had two new peaks related to the phosphate element and nitrogen element of the RNA aptamer (D). This proved the RNA aptamer was immobilized on the surface of the electrode. The ATR spectrum of the CSPE/CNFs-CHIT-GLU-RNA aptamer is also shown in Figure S4 . As can be seen, a broad absorption band around 3200 cm −1 attributed to vibrations of the -OH group in CHIT, small peaks around 2850 cm −1 attributed to vibrations of the-C-H group in CLU and aptamer, a peak around 1650 cm −1 attributed to vibrations of the -C=N in the RNA aptamer, a peak around 1550 cm −1 attributed to in plan vibrations of bases in the RNA aptamer, a peak around 1240 cm −1 attributed to the asymmetric stretching of PO 2− in the phosphodiester groups of the RNA aptamer, and a peak around 1080 cm −1 attributed to the symmetrical stretching of -PO 2− in the phosphodiester groups of the RNA aptamer [30, 31] . Figure S3 . It can be seen that the EDS of the CSPE/CNFs-CHIT-GLU-RNA aptamer had two new peaks related to the phosphate element and nitrogen element of the RNA aptamer (D). This proved the RNA aptamer was immobilized on the surface of the electrode. The ATR spectrum of the CSPE/CNFs-CHIT-GLU-RNA aptamer is also shown in Figure S4 . As can be seen, a broad absorption band around 3200 cm −1 attributed to vibrations of the -OH group in CHIT, small peaks around 2850 cm −1 attributed to vibrations of the-C-H group in CLU and aptamer, a peak around 1650 cm −1 attributed to vibrations of the -C=N in the RNA aptamer, a peak around 1550 cm −1 attributed to in plan vibrations of bases in the RNA aptamer, a peak around 1240 cm −1 attributed to the asymmetric stretching of PO 2-in the phosphodiester groups of the RNA aptamer, and a peak around 1080 cm −1 attributed to the symmetrical stretching of -PO 2-in the phosphodiester groups of the RNA aptamer [30, 31] . CV ( Figure 3A ) and EIS ( Figure 3B ) were also used as efficient methods for studying the interface properties of the CSPE (a), the CSPE/CNFs-CHIT (b), and the CSPE/CNFs-CHIT-GLU-RNA aptamer (c) in the presence of the Fe(CN) 6 3−/4− redox couple. As shown in Figure 3A , after the modification of the CSPE (a) with CNFs-CHIT (b), the intensity of the peak currents not only increased but also the difference between the potential of the anodic peak and the potential of the cathodic peak (∆E = E pa − E pc ) decreased from 0.25 V for the CSPE (a) to 0.18 V for the CSPE/CNFs-CHIT (b). This indicated that the CNFs-CHIT nanocomposite facilitated the electron transfer rate of the Fe(CN) 6 3−/4− redox couple. After the immobilization of the aptamer on the surface of the CSPE/CNFs-CHIT, the intensity of the peak current decreased (c). Moreover, the ∆E of the CV increased from 0.18 V for the CSPE/CNFs-CHIT to 0.22 V for the CSPE/CNFs-CHIT-GLU-RNA aptamer. The reasonable explanation for this is that the electrostatic repulsion interaction between the immobilized aptamer on the surface of the electrode and Fe(CN) 6 3−/4− limited the accessibility of Fe(CN) 6 3−/4− to the surface of the electrode. As CRP (20.0 pM) was incubated with the RNA aptamer on the surface of the CSPE/CNFs-CHIT-GLU-RNA aptamer, the intensity of the peaks decreased and ∆E increased (0.41 V). The reasonable explanation for this is that the incubated CRP on the surface of the RNA-based aptasensor limited the mass-transfer diffusion of Fe(CN) 6 3−/4− to the surface of the RNA-based aptasensor. surface of the RNA-based aptasensor limited the mass-transfer diffusion of Fe(CN)6 3−/4− to the surface of the RNA-based aptasensor. The stepwise change in the electrochemical behavior of the electrodes was also studied using the EIS method ( Figure 3B ). As can be seen, after the modification of the CSPE with CNFs-CHIT, the electron transfer resistance (Ret) decreased from 3047 Ω for the CSPE (a) to 490 Ω for the CSPE/CNFs-CHIT (b). The Ret increased to 1253 Ω as the RNA aptamers were attached to the surface of the electrode by GLU (c). Finally, the Ret increased to 3674 Ω after the incubation of CRP with the attached RNA aptamer on the surface of the electrode (d). The results were consistent with the CV results. This change in the CV and EIS response of the aptasensor before (c) and after the incubation with CRP (d) indicated that the proposed RNA aptasensor is sensitive to this biomarker. Figure 3C shows the CVs for the CSPE/CNFs-CHIT-GLU-RNA aptamer (a) and the CSPE/CNFs-CHIT-GLU-RNA aptamer-MB (b) at PBS. As can be seen, no redox peak was observed for the CSPE/CNFs-CHIT-GLU-RNA aptamer. However, a couple of well-defined and reversible redox peaks were observed for the adsorbed MB on the aptasensor, indicating that the MB was incubated with the aptamer. Figure 3B is the equivalent electric circuit compatible with the Nyquist dia resistance; Ret: Electron transfer resistance; Cdl: Double-layer capacitance; Zw: W AC amplitude was 10 mV, DC potential was 0.17 V, and frequency range was 0 CVs of a CSPE/CNFs-CHIT-GLU-RNA aptamer-MB were recor scan rates (ʋ) at PBS. ( Figure S5A ). As shown, the log Ipa of MB has a with logʋ ( Figure S5B ). The slope of the log Ipa versus log CSPE/CNFs-CHIT-GLU-RNA aptamer-MB was found to be 1.08 µA V the theoretical value of 1.0, which is specified for an ideal adsorption- [29] . The surface coverage of MB (ΓMB) was estimated from the integra The stepwise change in the electrochemical behavior of the electrodes was also studied using the EIS method ( Figure 3B ). As can be seen, after the modification of the CSPE with CNFs-CHIT, the electron transfer resistance (R et ) decreased from 3047 Ω for the CSPE (a) to 490 Ω for the CSPE/CNFs-CHIT (b). The R et increased to 1253 Ω as the RNA aptamers were attached to the surface of the electrode by GLU (c). Finally, the R et increased to 3674 Ω after the incubation of CRP with the attached RNA aptamer on the surface of the electrode (d). The results were consistent with the CV results. This change in the CV and EIS response of the aptasensor before (c) and after the incubation with CRP (d) indicated that the proposed RNA aptasensor is sensitive to this biomarker. Figure 3C shows the CVs for the CSPE/CNFs-CHIT-GLU-RNA aptamer (a) and the CSPE/CNFs-CHIT-GLU-RNA aptamer-MB (b) at PBS. As can be seen, no redox peak was observed for the CSPE/CNFs-CHIT-GLU-RNA aptamer. However, a couple of welldefined and reversible redox peaks were observed for the adsorbed MB on the aptasensor, indicating that the MB was incubated with the aptamer. CVs of a CSPE/CNFs-CHIT-GLU-RNA aptamer-MB were recorded for different scan rates (V) at PBS. ( Figure S5A ). As shown, the log I pa of MB has a linear relationship with logV ( Figure S5B ). The slope of the log I pa versus logV curve for the CSPE/CNFs-CHIT-GLU-RNA aptamer-MB was found to be 1.08 µA V −1 s −1 , very close to the theoretical value of 1.0, which is specified for an ideal adsorption-controlled process [29] . The surface coverage of MB (Γ MB ) was estimated from the integration of the anodic peak in the cyclic voltammogram of the CSPE/CNFs-CHIT-GLU-RNA aptamer-MB ( Figure S6 ) [32] . This is according to Equation (3): where Q Faradic is the integrated area of the oxidation peak (peak area/scan rate; the scan rate was 0.05) (Coulomb), n is the number of electrons (n = 2), F is the Faraday constant (9648 C mol −1 ), and A is the electroactive surface area of the electrode (0.25 cm −2 ). The value of Γ MB was calculated to be 0.99 nmol cm −2 . The theoretical surface coverage (Γ Theory ) of the monolayer absorbance of MB at the surface of the electrode was0.22 (nmol cm −2 ) [33] . Therefore, the ratio of Γ MB to Γ Theory (η = Γ/Γ Theory ) was calculated to be 4.5 for the proposed aptasensor. This value is much larger than the theoretical value. The reasonable explanation for this is that the CNFs-CHIT nanocomposite increased the surface roughness of the electrode. Figure S6A shows how the Faradic charge (Q Faradic ) was obtained for the anodic peak current of the CSPE/CNFs-CHIT-GLU-RNA aptamer-MB. As shown, the total charge Q Total includes the non-Faradic and Faradic charge: After the subtraction of non-Faradic charge (Q Non-Faradic ) from Q Total (the charge below the red area), the Q Faradic can be obtained ( Figure S6B ). The value of Q Faradic for the CSPE/CNFs-CHIT-GLU-RNA aptamer-MB was 47.7 × 10 −6 coulomb. The aptamer surface coverage (T Aptamer ) on the modified electrode was also investigated. Since every CRP aptamer probe sequence contains 44 phosphodiester groups and a phosphodiester group interacts with an MB, the Γ MB can be converted to Γ Aptamer [34] . This is done by using Tarlov Equations (5) and (6): where z is the charge of the adsorbed molecule (z = 1 for MB), m is the number of phosphate groups of aptamer (m = 44), and N A is Avogadro's number (6.022 × 10 23 molecules mol −1 ). The value of Γ Aptamer was calculated to be 22.5 pmol cm −2 (by using Equation (5)) or 1.35 × 10 13 molecules cm −2 (by using Equation (6)),which was greater than previously reported for the CRP aptamer probe [8] . The value of Γ Aptamer on the CSPE/CHIT-GLU-RNA aptamer-MB was also obtained with the same method used for the CSPE/CNFs-CHIT-GLU-RNA aptamer-MB ( Figure S7A-C) . The values of Q Faradic , T MB , and Γ Aptamer for the CSPE/CHIT-GLU-RNA aptamer-MB were obtained to be 4.8 × 10 −6 coulomb, 0.17 nmol cm −2 , and 3.8 pmol cm −2 (2.32 × 10 +12 molecules cm −2 ), respectively. Figure S8A ,B show the CVs and the anodic peak current related to the Faradic charge of MB on the CSPE/CNFs-CHIT-GLU-RNA aptamer-MB (a), and the CSPE/CHIT-GLU-RNA aptamer-MB (b). As can be seen, the Faradic charge of MB on the CSPE/CNFs-CHIT-GLU-RNA aptamer-MB was much bigger than on the CSPE/CHIT-GLU-RNA aptamer-MB. The obtained result indicated that the CNFs-CHIT nanocomposite increased the Γ Aptamer value up to 5.9 times. The heterogeneous electron transfer rate constant (K s ) for MB was also calculated for the CSPE/CNFs-CHIT-GLU-RNA aptamer-MB using Laviron's formula for the surface controlled electrochemical system (∆Ep < 200 mV, α = 0.5) [35] . This is shown in Equation (7): where m is the parameter related to the peak potential separation, n the number of electrons involved in the reaction, ν is the scan rate (V s −1 ), F is the Faraday constant (96,485 C mol −1 ), R is the universal gas constant (8.31 J K −1 mol −1 ), and T is the temperature (298 Kelvin). The average value of K s for MB was found to be 1.83 s −1 , suggesting that the electron transfer of the self-assembled MB on the proposed aptasensor has good reversibility. The influence of the volume of the CNFs-CHIT (A), the concentration of the immobilized RNA aptamer on the amount of the self-assembled MB (B), and the incubation time on the response of the CSPE/CNFs-CHIT-GLU-RNA aptamer-MB to 20.0 pM CRP (C) were investigated ( Figure 4 ) by using the one-factor-at-a-time method. As can be seen in Figure 4A , the signal of the assembled MB on the surface of the RNA aptasensor increased by increasing the volume of the CNFs-CHIT from 2 to 5 µL and then decreased. The effect of the RNA aptamer probe on the signal of the aptasensor was also investigated ( Figure 4B ). As shown, the signal increased by increasing the concentration of the RNA aptamer solution from 25.0 nmol to 100.0 nmol and then decreased as the concentration of the RNA aptamer solution increased to 150.0 nmol. This is due to the electrostatic repulsion between the negatively charged aptamer strands' increase in the high concentration of RNA aptamer, hindering them in their interaction with GLU. Therefore, the amount of the immobilized RNA aptamer and consequently the amount of the immobilized MB decreased [36] . The effect of the incubation time was also studied ( Figure 4C ). As can be seen, the signal of the self-assembled MB on the aptasensor in the presence of 20.0 pM CRP decreased from 20 min to 60 min, and after that remained unchanged, suggesting that the bond between MB and the phosphate groups of the aptamer broke and a new bond between CRP and the aptamer (CRP/RNA aptamer) was generated. The results indicated that the interaction of the RNA aptamer with the CRP reached a saturation level after 60 min. Therefore, we chose 5 µL CNFs-CHIT, 100 nmol RNA aptamer to fabricate the RNA aptasensor, and 60 min as the incubation time between the CRP and RNA aptamer as the optimized conditions throughout this work. The SWV method was applied for the measurement of the various concentrations of CRP ( Figure 5A ). As shown, the signal of the proposed aptasensor to the different concentrations of CRP (C CRP ) decreased logarithmically as the C CRP increased from 1.0 to 150.0 pM ( Figure 5B ). The corresponding logarithmic regression equation was: I p (µA) = −2.26 Log C CRP (pM) + 27.77 (8) Nanomaterials 2022, 12, x FOR PEER REVIEW 10 of 15 creased from 20 min to 60 min, and after that remained unchanged, suggesting that the bond between MB and the phosphate groups of the aptamer broke and a new bond between CRP and the aptamer (CRP/RNA aptamer) was generated. The results indicated that the interaction of the RNA aptamer with the CRP reached a saturation level after 60 min. Therefore, we chose 5 µL CNFs-CHIT, 100 nmol RNA aptamer to fabricate the RNA aptasensor, and 60 min as the incubation time between the CRP and RNA aptamer as the optimized conditions throughout this work. The SWV method was applied for the measurement of the various concentrations of CRP ( Figure 5A ). As shown, the signal of the proposed aptasensor to the different concentrations of CRP (CCRP) decreased logarithmically as the CCRP increased from 1.0 to 150.0 pM ( Figure 5B ). The corresponding logarithmic regression equation was: Ip (µA) = −2.26 Log CCRP (pM) + 27.77 (8) The sensitivity was 9.0 µA pM −1 cm −2 . The limit of detection (LOD) was found to be 0.37 pM (3σ/S), where σ is the standard deviation of the blank measurements for four different aptasensors (signal of the aptasensor in the absence of CRP) and S the slope of Figure 5B . The error bars represent the calculated standard deviation for the four different aptasensors. As can be seen, the intensity of the SWV signals is not only decreased but also the position of the signal was shifted. To explain this change in the peak position, the CVs of the CSPE/CNF-CHIT-GLU-RNA aptamer-MB in the absence and presence of 50.0 The sensitivity was 9.0 µA pM −1 cm −2 . The limit of detection (LOD) was found to be 0.37 pM (3σ/S), where σ is the standard deviation of the blank measurements for four different aptasensors (signal of the aptasensor in the absence of CRP) and S the slope of Figure 5B . The error bars represent the calculated standard deviation for the four different aptasensors. As can be seen, the intensity of the SWV signals is not only decreased but also the position of the signal was shifted. To explain this change in the peak position, the CVs of the CSPE/CNF-CHIT-GLU-RNA aptamer-MB in the absence and presence of 50.0 pM CRP were recorded ( Figure S9 ). As shown, the intensity of the signal not only decreased but also the ∆E in the CV of MB increased from 0.052 V (in the absence of CRP) to 0.163 V. The reasonable explanation is that as a big molecule like CRP is incubated with the RNA aptamer, the electron transfer to the surface of the electrode for the rest of the assembled MB would be difficult, and consequently, the ∆E in the CV of MB increased. The value of the Langmuir isotherm constant (K L ), the dissociation constant (K d ), and the maximum number of binding sites (I max ) for the CRP-RNA aptamer were also obtained using the Langmuir adsorption systems equation [37] . Equation (9) is as follows: where I is the steady-state current after the addition of the biomarker. where I is the steady-state current after the addition of the biomarker. The values of 1/Imax and 1/KL × Imax can be obtained from the slope (0.043) and intercept point (−0.04) in Figure 5C , respectively. The values of Imax, KL, and Kd (1/KL) were found to be 23.25 µA, 1.07 pM −1 , and 0.93 pM, respectively. The value of Kd is lower than the previously reported RNA aptasensor for CRP [8] , indicating the high affinity of the proposed aptasensor. This indicates that the high surface area of the modifier (CNFs-CHIT) prepared the better position and orientation conditions for the bio-recognizer (RNA aptamer) to interact with its target (CRP). Moreover, the Gibbs free energy for the desorption band of the CRP-RNA aptamer was found to be −179.6 kJ mol −1 [38] . This is done by using the equation below: where R is the universal gas constant of 8.31 J K −1 mol −1 , and T is the temperature (298.15 Kelvin). Nanomaterials 2022, 12, x FOR PEER REVIEW The analytical performance of the CSPE/CNFs-CHIT-GLU-RNA compared with other aptasensors for CRP measurement (Table 1) . It i CSPE/CNFs-CHIT-GLU-RNA aptamer-MB has good analytical perfor ison with other aptasensors for CRP due to using the CNFs-CHIT nano Table 1 . Comparison of the analytical performance of the CSPE/CNFs-C tamer-MB with other reported aptasensors for CRP. The values of 1/I max and 1/K L × I max can be obtained from the slope (0.043) and intercept point (−0.04) in Figure 5C , respectively. The values of I max , K L , and K d (1/K L ) were found to be 23.25 µA, 1.07 pM −1 , and 0.93 pM, respectively. The value of K d is lower than the previously reported RNA aptasensor for CRP [8] , indicating the high affinity of the proposed aptasensor. This indicates that the high surface area of the modifier (CNFs-CHIT) prepared the better position and orientation conditions for the bio-recognizer (RNA aptamer) to interact with its target (CRP). Moreover, the Gibbs free energy for the desorption band of the CRP-RNA aptamer was found to be −179.6 kJ mol −1 [38] . This is done by using the equation below: where R is the universal gas constant of 8.31 J K −1 mol −1 , and T is the temperature (298.15 Kelvin). The analytical performance of the CSPE/CNFs-CHIT-GLU-RNA aptamer-MB was compared with other aptasensors for CRP measurement (Table 1 ). It is obvious that the CSPE/CNFs-CHIT-GLU-RNA aptamer-MB has good analytical performance in comparison with other aptasensors for CRP due to using the CNFs-CHIT nanocomposite. 3.6. Stability, Reproducibility, and Selectivity of the CSPE/CNFs-CHIT-GLU-RNA Aptamer-MB The selectivity of the CSPE/CNFs-CHIT-GLU-RNA aptamer-MB was also studied ( Figure S10 ). As can be seen, no interference was detected for 10-fold quantities of HSA and HIgG in the determination of 10.0 pM CRP, indicating the proposed aptasensor has good selectivity. Figure S11 shows the stability of the CSPE/CNFs-CHIT-GLU-RNA aptamer-MB after two weeks. As shown, no significant change in the signal is observed (~2.4%), indicating the high stability of the proposed RNA aptasensor. The high stability of the CSPE/CNFs-CHIT-GLU-RNA aptamer-MB can be attributed to the biocompatible microenvironment provided by the CNFs-CHIT. The reproducibility of the CSPE/CNFs-CHIT-GLU-RNA aptamer-MB was evaluated by three newly fabricated aptasensors ( Figure S12 ). The relative standard deviation (RSD) was 3.1 % for 10.0 pM CRP. Human serum samples were prepared based on the previous report. Details are included in the supplementary data section. Serum samples 40.0 µL in amount were added to 156.0 µL PBS and mixed for 15 min. Then the solution was divided into two samples. After that, 2 µL CRP solution with different concentrations (100 pM, and 500 pM) was added to each of the two solutions and mixed for 15 min. The CRP concentration was 2.0 pM for the first diluted serum sample and 10.0 pM for the second one. The CRP concentration in the real sample was calculated by using the calibration curve ( Figure 5B ). Figure S13 shows the responses of the aptasensor to sample 1 (2.0 pM) and sample 2 (10.0 pM). The obtained results were compared with a CRP-ELISA kit (Table S1 ). As can be seen, the P-values were greater than 0.05. Therefore, there were no statistically significant differences between the responses of the proposed RNA aptasensor and a CRP-ELISA kit. While the CSPE/CNFs-CHIT-GLU-RNA aptamer-MB demonstrated excellent analytical performance in terms of sensitivity, stability, and selectivity, its response time is slower than the immunosensors. Therefore, our future plans include designing a new aptamer probe to decrease the response time of the sensor. In this study, an electrochemical RNA aptasensor was introduced with a strategy based on the association of the CNFs, CHIT, and MB to measure CRP concentration. The investigations indicated that the CNFs-CHIT nanocomposite increased the aptamer surface coverage dramatically. The proposed RNA aptasensor for the CRP measurement had a wider linear-response range and a lower LOD, and an affinity. The obtained results also demonstrated that the proposed RNA aptasensor has good stability, reproducibility, and selectivity. Moreover, there were not any significant differences between the responses of the proposed RNA aptasensor and a CRP-ELISA kit in human serum samples. The analytical performances of the proposed RNA aptasensor were not only better than the aptasensors previously reported for CRP, but also better than the immunosensors previously reported for CRP (Table S2 ). This is because of the low electron transfer resistance, the high surface area, and the high number of the primary amine functional groups of the CNFs-CHIT nanocomposite. We hope that the proposed aptasensor paves the way for a new opportunity to fabricate a cost-effective, selective, and sensitive device to measure the CRP biomarker as one of the key biomarkers in sepsis diseases. Figure S6 : The anodic peak current obtained from CVof the CSPE/CNFs-CHIT-GLU-RNA aptamer-MB includes non-Faradic current (a area) and Faradic current (b area) (A) at a scan rate of 0.05 Vs−1. The anodic peak current (Faradic current) was obtained from the CV of the CSPE/CNF-CHIT-GLU-RNA aptamer-MB after the subtraction of non-Faradic current from the total current (B). Figure S7 : CV of the CSPE/CHIT-GLU-RNA aptamer-MB (A) in a PBS at a scan rate of 0.05 V.s−1. The anodic peak current obtained from CVof CSPE/CNFs-CHIT-GLU-RNA aptamer-MB includes non-Faradic current and Faradic current (B). The anodic peak current (faradic current) obtained from CVof the CSPE/CNFs-CHIT-GLU-RNA aptamer-MB after the subtraction of non-Faradic current from the total current (C). Figure S8 : CVs (A) and Faradic anodic current (B) of the CSPE/CNFs-CHIT-GLU-RNA aptamer-MB (a) and the CSPE/CHIT-GLU-RNA aptamer-MB (b) in a PBS at a scan rate of 0.05 Vs-1. Figure S9 : CVs of the CSPE/CNFs-CHIT-GLU-RNA aptamer-MB in a PBS in the absence (a) and presence of 50 pM CRP (b) at a scan rate of 0.05 Vs-1. Figure S10 : SWVs of the CSPE/CNFs-CHIT-GLU-RNA aptamer-MB to 10 pM CRP in a PBS (0.1 M, pH 7.4) in the absence (a) and presence of 100 pM HSA and 100 pM HIgG (b). Figure S11 : SWVs of the CSPE/CNFs-CHIT-GLU-RNA aptamer-MB in a PBS (0.1 M, pH 7.4) in the first day (a) and 2 weeks after its fabrication (b). Figure S12 : SWVs of the three different aptasensors (a-c) to 10 pM CRP in a PBS related to the reproducibility of the aptasensor. Figure S13 : SWVs of the CSPE/CNFs-CHIT-GLU-RNA aptamer-MB in the 5-fold diluted plasma serum sample with PBS in the absence (a) and presence of 2 pM (b) and 10 pM CRP (c). Table S1 : Comparison of the obtained results between the proposed RNA aptasensor and an ELISA kit. Table S2 Biomarkers associated with COVID-19 disease progression Diagnostic strategies for c-reactive protein The electrochemical aptasensors for the determination of tumor markers Zeptomole detection of c-reactive protein in serum by a nanoparticle amplified surface plasmon resonance imaging aptasensor An aptasensor based on the microscopic enumeration of encoding gold nanoparticles for the detection of c-reactive protein Detection of c reactive protein (crp) in serum by an electrochemical aptamer-based sandwich assay Aptamers: An emerging class of molecules that rival antibodies in diagnostics Application of rna aptamers as recognition layers for the electrochemical analysis of c-reactive protein A label-free and sensitive electrochemical aptasensor for thrombin based on the direct electron transfer of hemin and hemin@rgo nanosheets as the signal probe Plug-and-play metabolic transducers expand the chemical detection space of cell-free biosensors Real-time measurement of small molecules directly in awake, ambulatory animals Characterization of electrochemical transducers for biosensor applications Voltammetric aptasensors for protein disease biomarkers detection: A review Development of an optical rna-based aptasensor for c-reactive protein Electrochemical aptasensors for cancer diagnosis in biological fluids-A review Fabrication of screen-printed electrodes: Opportunities and challenges Flexible and high-performance electrochromic devices enabled by self-assembled 2d tio2/mxene heterostructures Regenerative field effect transistor biosensor for in vivo monitoring of dopamine in fish brains A photoelectrochemical sandwich immunoassay for protein s100β, a biomarker for alzheimer's disease, using an ito electrode modified with a reduced graphene oxide-gold conjugate and cds-labeled secondary antibody Carbon nanofiber based electrochemical biosensors: A review Biocompatible conductive architecture of carbon nanofiber-doped chitosan prepared with controllable electrodeposition for cytosensing A carbon nanofiber-based label free immunosensor for high sensitive detection of recombinant bovine somatotropin Glypican-3 electrochemical aptasensor based on reduced graphene oxide-chitosan-ferrocene deposition of platinum-palladium bimetallic nanoparticles Methylene blue as an electrochemical discriminator of single-and double-stranded oligonucleotides immobilised on gold substrates Development of DNA aptamer-based sensor for electrochemical detection of C-reactive protein Behavior in aqueous solution, reaction with proteins, and application to enzyme crosslinking Determination of the electrochemical area of screen-printed electrochemical sensing platforms Comparative electroanalytical studies of graphite flake and multilayer graphene paste electrodes Cyclic Voltammetry-Simulation and Analysis of Reaction Mechanisms Morphological, molecular and ftir spectroscopic analysis during the differentiation of kidney cells from pluripotent stem cells Changes in the infrared microspectroscopic characteristics of DNA caused by cationic elements, different base richness and single-stranded form Green-synthesized gold nanoparticles decorated graphene sheets for label-free electrochemical impedance DNA hybridization biosensing The electrochemical behavior of methylene blue at a microcylinder carbon fiber electrode Electrochemical quantitation of DNA immobilized on gold General expression of the linear potential sweep voltammogram in the case of diffusionless electrochemical systems Electrochemical aptasensor based on aptamer-complimentary strand conjugate and thionine for sensitive detection of tetracycline with multi-walled carbon nanotubes and gold nanoparticles amplification Porous sio2 interferometric biosensor for quantitative determination of protein interactions: Binding of protein a to immunoglobulins derived from different species Receptor binding thermodynamics as a tool for linking drug efficacy and affinity1presented at the first italian-swiss meeting on medicinal chemistry Rna aptamer-based electrochemical aptasensor for c-reactive protein detection using functionalized silica microspheres as immunoprobes Informed Consent Statement: Not applicable. The authors declare no conflict of interest.