Magnetobiosensors Based on Viral Protein p19 for MicroRNA Determination in Cancer Cells and Tissues

MicroRNAs (miRs) have emerged as important clinical biomarkers with both diagnostic and prognostic value for relevant diseases, such as cancer. MiRs pose unique challenges for detection and are currently detected by northern blotting, real‐time PCR, and microarray techniques. These expensive, complicated, and time‐consuming techniques are not feasible for on‐site miR determination. In this study, amperometric magnetobiosensors involving RNA‐binding viral protein p19 as a selective biorecognition element were developed for miR quantification. The p19‐based magnetosensors were able to detect 0.4 fmol of a synthetic target and endogenous miR‐21 (selected as a model for its role in a wide variety of cancers) in only 2 h in total RNA extracted from cancer cells and human breast‐tumor specimens without PCR amplification and sample preprocessing. These results open up formidable perspectives for the diagnosis and prognosis of human cancers and for drug‐discovery programs.     

Multiplexed Immunosensing Platform Coupled to Hybridization Chain Reaction for Electrochemical Determination of MicroRNAs in Clinical Samples

There is an urgent need for development of rapid and inexpensive techniques for detection of microRNAs (miRNAs), which are potential biomarkers of various types of cancer. In this paper, we describe a multiplexed electrochemical platform for determination of three cancer‐relevant miRNAs: miR‐21, let‐7a and miR‐31. The strategy combines the use of magnetic beads (MBs) modified with a commercial antibody for the efficient capture of the heteroduplexes formed by hybridization of the target miRNA with DNA probe. Free non‐hybridized region of the DNA probe was thereafter hybridized with two biotin‐labeled auxiliary DNA probes in a process of hybridization chain reaction (HCR), resulting in a long hybrid bearing a large number of biotin molecules. Labeling of these multiple biotin units with streptavidin‐peroxidase conjugates allowed an amplification of the amperometric signal measured after capturing the modified MBs at a screen‐printed carbon electrode array of eight electrodes. The combined strategy demonstrated in a similar assay time significantly higher sensitivity than those previously described using modified MBs with the same capture antibody (without amplification by HCR) or a HCR strategy implemented on the surface of MBs, respectively. The methodology exhibits a good selectivity for discriminating single mismatches and was applied to the determination of the three target miRNAs in total RNA (RNA_t) extracted from various cancer cell lines and from cervical precancerous lesions.     

Polymersome‐assisted delivery of curcumin: A suitable approach to decrease cancer stemness markers and regulate miRNAs expression in HT29 colorectal cancer cells

Curcumin as a safe traditional compound has various benefits such as anticancer activities. However, low solubility in water is a problem. Herein, curcumin encapsulated in polymersome nanoparticles (CPNs) have been developed, the physicochemical properties have been evaluated, and cytotoxicity effects on HT29 cells were evaluated by MTT assay and annexin V/PI staining. The expression of stemness markers including CD44, CD133, and CD24, as well as miRNAs (miR‐126, miR‐34a, miR‐21, miR‐155, miR‐221, and miR‐222) and some potential targets, was evaluated in CPNs‐treated and untreated cells. Physicochemical analysis confirmed the encapsulation of curcumin in polymersomes and showed a spherical shape, an appropriate mean size of 259.5±1.5 nm, the acceptable polydispersity index of ~ 0.465, and the zeta potential of (‐8.74±0.2), as well as long‐term storage of CPNs at 4°C. According to the result, CPNs with the IC50 of 14 μg/ml increased apoptosis and induced S arrest in treated cells. Flow cytometry analysis showed the decrease in cancer stemness markers. RT‐qPCR analysis identified the downregulation of miR‐21, miR‐155, and miR‐221/222, as well as upregulation of miR‐34a, miR‐126, and deregulation of some apoptotic targets such as P53, CASP9, CASP8, CASP3, BAX, and BCl‐2 in CPNs‐treated cells. As a result, CPNs can be a safe and effective complementary agent to diminish cancer stem cells and tumor recurrence in colorectal cancer therapy.     

Chitosan/Nitrogen Doped Reduced Graphene Oxide Modified Biosensor for Impedimetric Detection of microRNA

The development of a low‐cost and disposable biosensor platform for the sensitive and rapid detection of microRNAs (miRNAs) is of great interest for healthcare, pharmaceuticals, and medical science. We designed an impedimetric biosensing platform using Chitosan (CHIT)/nitrogen doped reduced graphene oxide (NRGO) conductive composite to modify the surface of pencil graphite electrodes (PGE) for the sensitive detection of miRNAs. An initial optimisation protocol involved investigation of the effect of NRGO concentration and miR 660 DNA probe concentration on the response of the modified electrode. After the optimization protocol, the sequence‐selective hybridization between miR 660 DNA probe and its RNA target was evaluated by measuring changes on charge transfer resistance, R_ct values. Moreover, the selectivity of impedimetric biosensor was tested in the presence of non‐complementary miRNA (NC) sequences, such as miR 34a and miR 16. The hybridization process was examined both in phosphate buffer (PBS) and in PBS diluted fetal bovine serum (FBS:PBS) solutions. The biosensor demonstrated a detection limit of 1.72 μg/mL in PBS and 1.65 μg/mL in FBS:PBS diluted solution. Given the easy, quick and disposable attributes, the proposed conductive nanocomposite biosensor platform shows great promise as a low‐cost sensor kit for healthcare monitoring, clinical diagnostics, and biomedical devices.     

Monitoring H2O2 on the Surface of Single Cells with Liquid Crystal Elastomer Microspheres

Live‐imaging of signaling molecules released from living cells is a fundamental challenge in life sciences. Herein, we synthesized liquid crystal elastomer microspheres functionalized with horse‐radish peroxidase (LCEM‐HRP), which can be immobilized directly on the cell membrane to monitor real‐time release of H₂O₂ at the single‐cell level. LCEM‐HRP could report H₂O₂ through a concentric‐to‐radial (C‐R) transfiguration, which is due to the deprotonation of LCEM‐HRP and the break of inter or intra‐chain hydrogen bonding in LCEM‐HRP caused by HRP‐catalyzed reduction of H₂O₂. The level of transfiguration of LCEM‐HRP revealed the different amounts of H₂O₂ released from cells. The estimated detection sensitivity was ≈2.2×10^?7 μm for 10 min of detection time. The cell lines and cell–cell heterogeneity was explored from different configurations. LCEM‐HRP presents a new approach for in situ real‐time imaging of H₂O₂ release from living cells and can be the basis for seeking more advanced chemical probes for imaging of various signaling molecules in the cellular microenvironment.     

Thioguanosine Conversion Enables mRNA‐Lifetime Evaluation by RNA Sequencing Using Double Metabolic Labeling (TUC‐seq DUAL)

Temporal information about cellular RNA populations is essential to understand the functional roles of RNA. We have developed the hydrazine/NH₄Cl/OsO₄‐based conversion of 6‐thioguanosine (6sG) into A′, where A′ constitutes a 6‐hydrazino purine derivative. A′ retains the Watson–Crick base‐pair mode and is efficiently decoded as adenosine in primer extension assays and in RNA sequencing. Because 6sG is applicable to metabolic labeling of freshly synthesized RNA and because the conversion chemistry is fully compatible with the conversion of the frequently used metabolic label 4‐thiouridine (4sU) into C, the combination of both modified nucleosides in dual‐labeling setups enables high accuracy measurements of RNA decay. This approach, termed TUC‐seq DUAL, uses the two modified nucleosides in subsequent pulses and their simultaneous detection, enabling mRNA‐lifetime evaluation with unprecedented precision.     

MnO2‐TiO2 Nanocomposite and 2‐(3,4‐Dihydroxyphenethyl) Isoindoline‐1,3‐Dione as an Electrochemical Platform for the Concurrent Determination of Cysteine,Tryptophan and Uric Acid

A novel modified carbon paste electrode (CPE) based on an MnO₂‐TiO₂ nanocomposite and 2‐(3,4 dihydroxyphenethyl) isoindoline‐1,3‐dione (DPID) as the modifier for the simultaneous analysis of cysteine (Cys), tryptophan (Trp) and uric acid (UA), as three key biochemicals present in human body. The MnO₂/TiO₂ nanocomposite was synthesized through a chemical co‐precipitation approach and the resulting electrode (MnO₂‐TiO₂/DPID/CPE) was used for studying the electrochemical oxidation of cysteine (Cys), tryptophan (Trp) and uric acid. As opposed to conventional CPEs, the oxidation peak potential of cysteine on MnO₂‐TiO₂/DPID/CPE had a 600.0 mV decrease in overpotential and could be observed at 30.0 mV, and the signals were linear from 0.025 to 200.0 μM, and a lower detection limit of 0.013 μM was reached. The MnO₂‐TiO₂/DPID/CPE was satisfactorily used for the concurrent analysis of Cys, Trp and UA in pharmaceutical and biological samples.     

A Strategy for Dramatically Enhancing the Selectivity of Molecules Showing Aggregation‐Induced Emission towards Biomacromolecules with the Aid of Graphene Oxide

By intelligently utilizing the different interacting strengths between different moieties according to the displacement method, general biosensors with aggregation‐induced emission (AIE) characteristics for biomacromolecules without selectivity were converted to excellent, highly selective probes for one specific biomacromolecule with the aid of graphene oxide (GO) in an aqueous medium. Importantly, thanks to the different interactions between the AIE molecule and biomacromolecules, just by simply changing the AIE molecule the sensing system could detect different types of biomacromolecules, thereby providing a new approach to the development of AIE‐based sensors with high selectivity and sensitivity. More specifically, the complex of A₂HPS?HCl—a derivative of hexaphenylsilone (HPS) functionalized by two amino (A₂) groups (N(CH₂CH₃)₃)—and GO only gives an “off–on” response to DNA, with a detection limit of 2.3 μg mL^?1 toward DNA‐CT (calf thymus); interestingly, the complex of TPE‐N₂C₄ (1,2‐bis{4‐[4‐(N,N,N‐triethylammonium)butoxy]phenyl}‐1,2‐diphenylethene dibromide) and GO could only detect the presence of bovine serum albumin (BSA), whereas other biomacromolecules, including DNA, RNA, and even other proteins have very little influence.     

Novel 13C‐detected NMR Experiments for the Precise Detection of RNA Structure

Up to now, NMR spectroscopic investigations of RNA have utilized imino proton resonances as reporters for base pairing and RNA structure. The nucleobase amino groups are often neglected, since most of their resonances are broadened beyond detection due to rotational motion around the C–NH₂ bond. Here, we present ¹³C‐detected NMR experiments for the characterization of all RNA amino groups irrespective of their motional behavior. We have developed a C(N)H‐HDQC experiment that enables the observation of a complete set of sharp amino resonances through the detection of proton‐NH₂ double quantum coherences. Further, we present an “amino”‐NOESY experiment to detect NOEs to amino protons, which are undetectable by any other conventional NOESY experiment. Together, these experiments allow the exploration of additional chemical shift information and inter‐residual proton distances important for high‐resolution RNA secondary and tertiary structure determination.     

Coordination Polymers of Bipyridyldicarboxylates – a Cobalt Containing 12,3‐net with Potential Reactive Sites

The porous cobalt(II) coordination polymer [Co{2,2′‐bipy‐4,4′(CO₂)₂}(H₂O)₂] ( 1 ) was prepared via a hydrothermal synthesis approach starting from Co(NO₃)₂ · 6 H₂O and 2,2′‐bipyridine‐4,4′‐dicarboxylic acid in a one to one mixture of ethanol and water at 120 °C. The product was characterized by single crystal X‐ray diffraction, TGA and elemental analysis. Space group: P3₁21, unit cell dimensions at –73 °C: a = 11.980(2), c = 8.335(2) Å, R = 0.032, wR² (all data) = 0.048. The structure determination revealed 1 to be a network in which octahedrally coordinated cobalt atoms are arranged to form a (12,3) net.     

A Non‐Invasive NMR Method Based on Histidine Imidazoles to Analyze the pH‐Modulation of Protein–Nucleic Acid Interfaces

A useful ²J(N?H) coupling‐based NMR spectroscopic approach is proposed to unveil, at the molecular level, the contribution of the imidazole groups of histidines from RNA/DNA‐binding proteins on the modulation of binding to nucleic acids by pH. Such protonation/deprotonation events have been monitored on the single His96 located at the second RNA/DNA recognition motif (RRM2) of T‐cell intracellular antigen‐1 (TIA‐1) protein. The pK_a values of the His96 ionizable groups were substantially higher in the complexes with short U‐rich RNA and T‐rich DNA oligonucleotides than those of the isolated TIA‐1 RRM2. Herein, the methodology applied to determine changes in pK_a of histidine side chains upon DNA/RNA binding, gives valuable information to understand the pH effect on multidomain DNA/RNA‐binding proteins that shuttle among different cellular compartments.     

Crystalline Materials with Large Channels or Cavities – Synthesis and Crystal Structure of an Iron(III) tetra(4‐carboxyphenyl)‐porphine

Tetra(4‐carboxyphenyl)‐porphine iron(III) chloride · 2 CH₃COOH · 4 H₂O ( 1 ) was prepared via a hydrothermal synthesis approach starting from FeCl₂ and 5,10,15,20‐tetrakis‐(4‐carboxyphenyl)‐21 H,23 H‐porphine in glacial acetic acid in the presence of KOH as a base and ytterbium(III) acetate as a template. Compound 1 was characterized by single crystal X‐ray diffraction and elemental analysis. Space group: P 1, Z = 2, unit cell dimensions at 200 K: a = 9.282(2), b = 20.239(5), c = 22.239(5) Å, α = 92.49(3), β = 99.87(3), γ = 90.78(3)°, R₁ (observed) = 0.132, wR₂ (all data) = 0.395. The architecture of the structure is determined by interporphyrin hydrogen bonding. Four iron porphyrin units form a very wide open channel with dimensions of circa 15.7 Å × 15.7 Å. No interpenetrating is observed.     

Electrooxidation of Chlorophenols Catalyzed by Nickel Octadecylphthalocyanine Adsorbed on Single‐Walled Carbon Nanotubes

We described the synthesis of nickel octadecylphthalocyanine (NiPc(C₁₀H₂₁)₈), followed by its adsorption on single‐walled carbon nanotubes (SWCNT) to form SWCNT‐NiPc(C₁₀H₂₁)₈ conjugates. SWCNT‐NiPc(C₁₀H₂₁)₈ was used to modify a glassy carbon electrode (GCE) and for the electrooxidation of 4‐chlorophenol and 2,4‐dichlorophenol. The SWCNT and NiPc(C₁₀H₂₁)₈ have a synergistic effect on each other in terms of improving electrocatalysis for the detection of chlorophenols. The stability of the electrode improved in the presence of NiPc(C₁₀H₂₁)₈ or NiPc compared to the bare GCE. The presence of SWCNT improves the electrocatalytic behaviour of NiPc(C₁₀H₂₁)₈ but not of unsubstituted NiPc. All modified electrodes showed improved stability towards the detection of 2,4‐dichlorophenol. The best stability for 4‐CP detection was observed in the presence of SWCNT for NiPc(C₁₀H₂₁)₈.     

Differentiate RNA Single‐Stranded Region of the Branched Structures and Hairpin Loops by an Octahedral Cobalt(II) Complex

Single‐stranded RNA molecules usually include secondary structural elements such as bulges, internal loops, and hairpin loops. These RNA secondary structural elements are often essential for the biological activity and functions of the RNA molecule. Chemical probe Co^II(HAPP)(TFA)₂ in the presence of H₂O₂ is found to differentiate single‐stranded RNA from branched structures and hairpin loops. This study uses Co^II(HAPP)(TFA)2 to analyze the structures of two RNA molecules: a fragment of HIV TAR RNA (TAR‐27) and the catalytic domain 5 of group II intron (D5‐29). The electrophoretic mobility of TAR‐27 does not shift in the presence of Co^II(HAPP)(TFA)₂, suggesting that the reagent does not change the conformation of RNA substrate. Cleavage of the RNA substrates by Co^II(HAPP)(TFA)₂ unambiguously differentiated RNA internal looped structures from hairpin loops. The results show that Co^II(HAPP)(TFA)2 is a sensitive, informative and convenient tool for analysis of RNA secondary structures.     

A Sensor for Serotonin and Dopamine Detection in Cancer Cells Line Based on the Conducting Polymer−Pd Complex Composite

An electrochemical sensor based on the conducting polymer composite with a palladium complex (Pd(C₂H₄N₂S₂)₂) was developed for the detection of serotonin and dopamine simultaneously in the breast cancer cell and human plasma samples. The proposed sensor was fabricated using the Pd(C₂H₄N₂S₂)₂ complex‐anchored poly2,2 : 5,2‐terthiophene‐3‐(p‐benzoic acid) (pTBA) layer on the AuNPs decorated reduced graphene oxide (AuNPs@rGO) substrate, which revealed the enhanced anodic current of the target species. The sensor probe was characterized by electrochemical and surface analysis methods. The experimental parameters affecting the sensor performance were optimized, in terms of AuNPs@rGO concentration, the number of electropolymerization cycle for pTBA, immobilization time of Pd(C₂H₄N₂S₂)₂, and pH. The dynamic ranges for serotonin and dopamine were obtained from 0.02 to 200 μM, and from 0.1 to 200 μM with the detection limit of 2.5, and 24.0 nM, respectively. The reliability of proposed sensor was evaluated using cancer cell lines for the clinical applications.     

4‐Styrylquinolines from cyclocondensation reactions between (2‐aminophenyl)chalcones and 1,3‐diketones: crystal structures and regiochemistry

Structures are reported for two matched sets of substituted 4‐styrylquinolines which were prepared by the formation of the heterocyclic ring in cyclocondensation reactions between 1‐(2‐aminophenyl)‐3‐arylprop‐2‐en‐1‐ones with 1,3‐dicarbonyl compounds. (E)‐3‐Acetyl‐4‐[2‐(4‐methoxyphenyl)ethenyl]‐2‐methylquinoline, C₂₁H₁₉NO₂, (I), (E)‐3‐acetyl‐4‐[2‐(4‐bromophenyl)ethenyl]‐2‐methylquinoline, C₂₀H₁₆BrNO, (II), and (E)‐3‐acetyl‐2‐methyl‐4‐{2‐[4‐(trifluoromethyl)phenyl]ethenyl}quinoline, C₂₁H₁₆F₃NO, (III), are isomorphous and in each structure the molecules are linked by a single C—H…O hydrogen bond to form C(6) chains. In (I), but not in (II) or (III), this is augmented by a C—H…π(arene) hydrogen bond to form a chain of rings; hence, (I)–(III) are not strictly isostructural. By contrast with (I)–(III), no two of ethyl (E)‐4‐[2‐(4‐methoxyphenyl)ethenyl]‐2‐methylquinoline‐3‐carboxylate, C₂₂H₂₁NO₃, (IV), ethyl (E)‐4‐[2‐(4‐bromophenyl)ethenyl]‐2‐methylquinoline‐3‐carboxylate, C₂₁H₁₈BrNO₂, (V), and ethyl (E)‐2‐methyl‐4‐{2‐[4‐(trifluoromethyl)phenyl]ethenyl}quinoline‐3‐carboxylate, C₂₂H₁₈F₃NO₂, (VI), are isomorphous. The molecules of (IV) are linked by a single C—H…O hydrogen bond to form C(13) chains, but cyclic centrosymmetric dimers are formed in both (V) and (VI). The dimer in (V) contains a C—H…π(pyridyl) hydrogen bond, while that in (VI) contains two independent C—H…O hydrogen bonds. Comparisons are made with some related structures, and both the regiochemistry and the mechanism of the heterocyclic ring formation are discussed.     

Crystal packing in the structures of diethanolamine derivatives

Four distinct hydrogen‐bonding topologies were observed in the structures of six diethanolamine ligands. These compounds are (1R*,2R*)‐2‐[(2‐hydroxyethyl)(methyl)amino]‐1,2‐diphenylethanol, C₁₇H₂₁NO₂, (I), 1‐[(2S)‐2‐(hydroxydiphenylmethyl)pyrrolidin‐1‐yl]‐2‐methylpropan‐2‐ol, C₂₁H₂₇NO₂, (II), 2‐[(2‐hydroxyethyl)(methyl)amino]‐1,1‐diphenylethanol, C₁₇H₂₁NO₂, (III), 1‐{(2‐hydroxy‐2‐methylpropyl)[(1S)‐1‐phenylethyl]amino}‐2‐methylpropan‐2‐ol, C₁₆H₂₇NO₂, (IV), 1‐{[(2R)‐2‐hydroxy‐2‐phenylethyl][(1S)‐1‐phenylethyl]amino}‐2‐methylpropan‐2‐ol, C₂₀H₂₇NO₂, (V), and (1R*,2S*)‐2‐[(2‐hydroxyethyl)(methyl)amino]‐1,2‐diphenylethanol, C₁₇H₂₁NO₂, (VI). In each compound, all `active' hydroxy H atoms are engaged in hydrogen bonding, but the N atoms are not involved in intermolecular hydrogen bonding. In the structures of (I), (II) and (IV)–(VI), molecules are linked into chains by intermolecular O—H...O interactions. These chains are organized in such a way as to hide the hydrophilic groups inside, and so the outer surfaces of the chains are hydrophobic. The structure of (VI) contains two distinct non‐equivalent systems of intermolecular O—H...O hydrogen bonds formed by disordered hydroxy H atoms.     

Semisynthesis of 3′(2′)‐O‐(Aminoacyl)‐tRNA Derivatives as Ribosomal Substrate

An efficient synthesis of (3′‐terminally) 3′(2′)‐O‐aminoacylated pCpA derivatives is described, which could lead to the production of (aminoacyl)‐tRNAs following T4 RNA ligase mediated ligation. The tetrahydrofuranyl (thf) group was used as a permanent protective group for the 2′‐OH of the cytidine moiety which can be removed during the purification of the 3′(2′)‐O‐aminoacylated‐pCpA. This approach allowed for a general synthesis of (3′‐terminally) 3′(2′)‐O‐aminoacylated oligonucleotides. The fully protected pCpA 14 was synthesized by phosphoramidite chemistry and treated with NH₃ solution to remove the 2‐cyanoethyl and benzoyl groups (→ 15 ; Schemes 1 and 2). The 2′‐O‐thf‐protected‐pCpA 15 was coupled with α‐amino acid cyanomethyl esters, and the products 20a – c were deprotected and purified with AcOH buffer to afford 3′(2′)‐O‐aminoacylated pCpA 21a – c in high yields. The 3′(2′)‐O‐aminoacylated pCpA were efficiently ligated with tRNA(? CA) to yield (aminoacyl)‐tRNA which was an active substrate for the ribosome.     

Femtogram Detection of Explosive Nitroaromatics: Fluoranthene‐Based Fluorescent Chemosensors

Herein we report a novel fluoranthene‐based fluorescent fluorophore 7,10‐bis(4‐bromophenyl)‐8,9‐bis[4‐(hexyloxy)phenyl]fluoranthene ( S₃ ) and its remarkable properties in applications of explosive detection. The sensitivity towards the detection of nitroaromatics (NACs) was evaluated through fluorescence quenching in solution, vapor, and contact mode approaches. The contact mode approach using thin‐layer silica chromatograp‐ hic plates exhibited a femtogram (1.15 fg cm^?2) detection limit for trinitrotoluene (TNT) and picric acid (PA), whereas the solution‐phase quenching showed PA detection at the 2–20 ppb level. Fluorescence lifetime measurements revealed that the quenching is static in nature and the quenching process is fully reversible. Binding energies between model binding sites of the S₃ and analyte compounds reveal that analyte molecules enter into the cavity created by substituted phenyl rings of fluoranthene and are stabilized by strong intermolecular interactions with alkyl chains. It is anticipated that the sensor S₃ could be a promising material for the construction of portable optical devices for the detection of onsite explosive nitroaromatics.     

Aptamer‐based detection and quantitative analysis of human immunoglobulin E in capillary electrophoresis with chemiluminescence detection

A novel aptamer‐based CE with chemiluminescence (CL) assay was developed for highly sensitive detection of human immunoglobulin E (IgE). The IgE aptamer was conjugated with gold nanoparticles (AuNPs) to form AuNPs‐aptamer that could specifically recognize the IgE to produce an AuNPs‐aptamer‐IgE complex. The mixture of the AuNPs‐aptamer‐IgE complex and the unbounded AuNPs‐aptamer could be effectively separated by CE and sensitively detected with luminol‐H₂O₂ CL system. By taking the advantage of the excellent catalytic behavior of AuNPs on luminol‐H₂O₂ CL system, the ultrasensitive detection of IgE was achieved. The detection limit of IgE is 7.6 fM (S/N = 3) with a linear range from 0.025 to 250 pM. Successful detection of IgE in human serum samples was demonstrated and the recoveries of 94.9–103.2% were obtained. The excellent assay features of the developed approach are its specificity, sensitivity, adaptability, and very small sample consumption. Our design provides a methodology model for determination of rare proteins in biological samples.