The spin coated PMMA film on a clean silicon wafer (Fig. developed method and bonded permanently with R2R sizzling embossed PMMA microchannels by solvent bonding lamination. The functionality of the immobilized antibody inside the microfluidic channel was evaluated by fluorescence-based sandwich immunoassay for detection of C-reactive protein (CRP). The antibody-antigen assay exhibited a good level of linearity over the range of 10 ng/ml to 500 ng/ml (R2?=?0.991) having a calculated detection limit of 5.2 ng/ml. The designed patterning method is straightforward, rapid and provides a versatile approach for creating multiple protein patterns in one microfluidic channel for multiplexed immunoassays. Intro The analysis of biomarkers TCF10 directly at the side of a patient, which is known as point-of-care screening (POCT), is definitely a continually expanding pattern in the practice of medical analysis [1]C[3]. Many of the available POCT products on the market are based on immunoassays. Among the various immunoassay types, enzyme-linked immunosorbent assay (ELISA) is definitely a long standing-standard for the quantitative analysis of several diseases biomarker because of its level of sensitivity and specificity [4]. However, the conventional ELISA technique is definitely often subjected to long incubation occasions and multiple washing methods, which limit its throughput and applicability for quick biomarker screening. Miniaturization of standard assays into POCT products provides several advantages, such as simplification of the assay methods, portability, reduced assay time, and lower usage of samples and reagents. Several types of immunoassay products have been developed and commercialized for POCT applications [5], [6]. Among these devices, the lateral flow-based pregnancy test, in which an antigen is definitely detected to be above a certain threshold, is the simplest and most commercialized POCT device. Although this type of test is simple to do, the result is not reproducible, quantitative and sensitive [2], [7]. Microfluidic products are better options for testing target analytes that require quantification with less sample volume and increased level of sensitivity and accuracy [2], [6]-[9]. In parallel with the analytical need of microfluidic immunoassay systems for POCT applications, there is a large demand for fabrication of future products utilized for POCT as inexpensive and disposable platform [10]. Silicon and glass are the popular substrates for fabrication of microfluidic products. However, the expensive and time-consuming fabrication process limits the practical applicability of those materials for commercial immunoassays. Recently, there has been an increasing interest in the use of polymer and plastic materials for fabrication of microfluidics because of their mechanical, optical and chemical stability, low production cost and superb processing properties. Poly (dimethylsiloxane) (PDMS) is definitely a widely used elastomeric polymer in academic research for quick prototyping of microfluidics via smooth lithographic techniques because of its desired optical properties, BETP flexibility, BETP and cost-effectiveness. However, the inherent limitations of PDMS for POCT applications include its hydrophobicity, propensity for BETP protein adsorption and troubles in scaling up for mass production [11]. Currently, thermoplastic materials, such as polymethyl methacrylate (PMMA), cyclic olefin copolymer (COC), polycarbonate (Personal computer), polypropylene (PP), and polystyrene (PS), are progressively used for extremely high-volume production of microfluidics using R2R sizzling embossing and injection molding [12]. Compared to injection molding, R2R sizzling embossing is a fast production BETP method for microfluidic products in which a revolving embossing cylinder transfers its stamp features onto a heated polymer web [12], [13]. Several approaches have been implemented to immobilize and pattern biomolecules on the surface of microchannels, including microcontact printing [14], [15], microfluidic patterning [16], photolithography [17], physical entrapment [18], deposition through stencil [19] and inkjet printing [20]. Among these methods, inkjet printing offers multiple advantages such as simplicity, flexibility, low-cost of process, minimum usage of materials and the capability to pattern multiple analytes simultaneously using self-employed cartridges. Piezoelectric inkjet BETP printing has been applied to deposit antibodies on streptavidin-coated glass slides [20], EDC/NHS triggered nanofibrillar cellulose films [21], nylon membranes [22], aldehyde functionalized silicon substrates [23] and streptavidin-coated platinum surfaces [24]. The major methods utilized for the.
The spin coated PMMA film on a clean silicon wafer (Fig
- Post author:aftaka
- Post published:January 22, 2025
- Post category:Angiotensin Receptors, Non-Selective