Blood biochemical indicators are an important basis for the diagnosis and treatment by doctors. The performance of related instruments, the qualification of operators, the storage method and time of blood samples and other factors will affect the accuracy of test results. However, it is difficult to meet the clinical needs of rapid detection and early screening of diseases with currently available methods. Point-of-care testing (POCT) is a new diagnostic technology with the characteristics of instant, portability, accuracy and efficiency. Microfluidic chips can provide an ideal experimental reaction platform for POCT. This paper summarizes the existing detection methods for common biochemical indicators such as blood glucose, lactic acid, uric acid, dopamine and cholesterol, and focuses on the application status of POCT based on microfluidic technology in blood biochemistry. It also summarizes the advantages and challenges of existing methods and prospects for development. The purpose of this paper is to provide relevant basis for breaking through the technical barriers of microfluidic and POCT product development in China.
Humans ; Point-of-Care Testing ; Lactic Acid/blood* ; Microfluidic Analytical Techniques/methods* ; Blood Glucose/analysis* ; Point-of-Care Systems ; Blood Chemical Analysis/instrumentation* ; Uric Acid/blood* ; Cholesterol/blood* ; Dopamine/blood* ; Microfluidics/methods*

Point-of-care testing (POCT) is a test method performed on the sampling site or patient bedside. Accurate results can be achieved rapidly by the application of portable analytical instruments and compatible reagents. It has been widely used in the field of in vitro diagnosis (IVD). Paper-based microfluidics technology has great potential in developing POCT due to its advantages in low cost, simple operation, rapid detection, portable equipment, and unrestricted application conditions. In recent years, the development of paper-based microfluidic technology and its integration with various new technologies and methods have promoted the substantial development of POCT technology and methods. The classification and characteristic of the paper are summarized in this review. Paper-based microfluidic sample pretreatment methods, the flow control in the process of reaction and the signal detecting and analyzing methods for the testing results are introduced. The research progress of various kinds of microfluidic paper-based analytical devices (μPADs) toward POCT in recent years is reviewed. Finally, remaining problems and the future prospects in POCT application of paper-based microfluidics are discussed.
Diagnostic Tests, Routine ; methods ; Humans ; Microfluidic Analytical Techniques ; instrumentation ; Paper ; Point-of-Care Testing

Deficiency Diseases ; blood ; diagnosis ; genetics ; Genotyping Techniques ; Humans ; Microfluidic Analytical Techniques ; Micronutrients ; deficiency ; Polymorphism, Single Nucleotide ; Precision Medicine ; methods ; Risk Assessment

We developed phase-switch microfluidic devices for molecular profiling of a large number of single cells. Whole genome microarrays and RNA-sequencing are commonly used to determine the expression levels of genes in cell lysates (a physical mix of millions of cells) for inferring gene functions. However, cellular heterogeneity becomes an inherent noise in the measurement of gene expression. The unique molecular characteristics of individual cells, as well as the temporal and quantitative information of gene expression in cells, are lost when averaged among all cells in cell lysates. Our single-cell technology overcomes this limitation and enables us to obtain a large number of single-cell transcriptomes from a population of cells. A collection of single-cell molecular profiles allows us to study carcinogenesis from an evolutionary perspective by treating cancer as a diverse population of cells with abnormal molecular characteristics. Because a cancer cell population contains cells at various stages of development toward drug resistance, clustering similar single-cell molecular profiles could reveal how drug-resistant sub-clones evolve during cancer treatment. Here, we discuss how single-cell transcriptome analysis technology could enable the study of carcinogenesis from an evolutionary perspective and the development of drug-resistance in leukemia. The single-cell transcriptome analysis reported here could have a direct and significant impact on current cancer treatments and future personalized cancer therapies.
Carcinogenesis ; genetics ; Drug Resistance, Neoplasm ; Gene Expression Profiling ; Hematopoietic Stem Cells ; metabolism ; Humans ; Leukemia, Myelogenous, Chronic, BCR-ABL Positive ; drug therapy ; pathology ; Microfluidic Analytical Techniques ; Single-Cell Analysis ; methods ; Transcriptome

Microbe is extremely abundant in nature, and its size has a very wide coverage from nano- to micro-scale making it suitable to be processed at multi-scale level as natural "building blocks" and "chassis cells". Biofabrication based on microbes is an artificial manipulation on microbes to assemble functional materials and devices by using the specific structures and various biological functions of microbes. In the meantime, the novel strategies of biofarication enables us to study the behavioral details of microbes, which will provide new platforms for uncovering the unsolved basic scientific problems of microbes. In this paper, we reviewed the frontier and progress in biofabrication from nano- and micro-scale in microbes that were manipulated as structured "building blocks" or functional "micro/nano robots".
Bacteria ; metabolism ; Biomimetics ; methods ; Biotechnology ; Microfluidic Analytical Techniques ; methods ; Nanotechnology ; Viruses ; metabolism

Flexible print circuit (FPC) technology has been widely applied in variety of electric circuits with high precision due to its advantages, such as low-cost, high specific fabrication ability, and good flexibility, etc. Recently, this technology has also been used in biomedical engineering, especially in the development of microfluidic chip and microelectrode array. The high specific fabrication can help making microelectrode and other micro-structure equipment. And good flexibility allows the micro devices based on FPC technique to be easily packaged with other parts. In addition, it also reduces the damage of microelectrodes to the tissue. In this paper, the application of FPC technology in biomedical engineering is introduced. Moreover, the important parameters of FPC technique and the development trend of prosperous applications is also discussed.
Biomedical Engineering ; instrumentation ; methods ; Electricity ; Equipment Design ; Lab-On-A-Chip Devices ; trends ; Microelectrodes ; Microfluidic Analytical Techniques ; instrumentation ; Microfluidics ; instrumentation

With the constant development of the drug screening technology, new screening methods and techniques have came to the fore, driving drug screening to grow rapidly and efficiently with a high throughput. Characterized by micro-scale analysis, high throughput, inheritability and good biocompatibility, the micro-fluidic analytical technology provides a new method and technical platform for screening active ingredients from natural products. This essay introduces multiple methods used for screening active ingredients from natural products and focuses on the micro-fluidic chip screening technology combined with cell culture and its characteristics, the composition of the platform of the micro-fluidic chip screening technology and its application in screening active ingredients from natural products.
Animals ; Biological Products ; chemistry ; Drug Evaluation, Preclinical ; methods ; Humans ; Microfluidic Analytical Techniques ; methods

OBJECTIVETo establish a new method for sperm sorting by imitating the physiological process of sperm-cervical mucus interaction on the microfluidic chip.

METHODSWe designed a microfluidic chip to imitate the physiological process of natural sperm sorting in the microchannel based on the interaction between sperm and cervical mucus, and obtained motile sperm after the interaction. Meanwhile, we established an integrated real-time sperm detection reservoir on this chip to determine sperm parameters using the computer-assisted sperm analysis system. We analyzed 30 samples using both microfluidic and swim-up methods, and compared the results with those obtained before sorting.

RESULTSThe rate of grade a + b sperm, the rate of morphologically normal sperm, straight-line velocity (VSL), average path velocity (VAP) and straightness (STR) were (29.78 +/- 11.24)%, (8.00 +/- 5.19)%, (18.89 +/- 4.90) microm/s, (26.84 +/- 5.13) microm/s and (70.15 +/- 7.61)%, respectively, before sorting, (71.65 +/- 11.18)%, (14.95 +/- 6.79)%, (24.14 +/- 5.95) microm/s, (32.61 +/- 6.36) microm/s and (73.87 +/- 9.34)%, respectively, after swim-up sorting, and (92.37 +/- 6.33)%, (23.33 +/- 7.67)%, (34.03 +/- 16.78) microm/s, (38.73 +/- 16.40) microm/s and (84.91 +/- 12.56)%, respectively, after sorting on the microfluidic chip. The sperm parameters obtained before sorting showed statistically significant differences from those obtained on the chip (P < 0.01) and by the swim-up method (P < 0.05).

CONCLUSIONImitation of the physiological interaction between sperm and cervical mucus on the microfluidic chip helped the realization of both the natural sorting and real-time analysis of sperm. The quality of the sperm sorted on the microfluidic chip is significantly better than that of the sperm before sorting and sorted by the swim-up method. This has prepared the ground for imitating the fertilization process under the physiological condition on the microfluidic chip.

Cell Movement ; Cell Separation ; Cervix Mucus ; Humans ; Male ; Microfluidic Analytical Techniques ; instrumentation ; Microfluidics ; methods ; Oligonucleotide Array Sequence Analysis ; Semen Analysis ; Sperm Motility ; physiology ; Spermatozoa ; physiology

After years of development, biosensors based on imaging ellipsometry and biosensors based on total internal reflection imaging ellipsometry have been successfully implemented in various engineering systems. Their experimental setups, detection principles, and biological and clinical applications are briefly reviewed.
Antibodies ; analysis ; immunology ; Antigens, CD ; analysis ; immunology ; Bacteria ; chemistry ; isolation & purification ; Biomarkers ; analysis ; Biosensing Techniques ; instrumentation ; methods ; Humans ; Ligands ; Microfluidic Analytical Techniques ; instrumentation ; methods ; Microfluidics ; instrumentation ; methods ; Molecular Imaging ; instrumentation ; methods ; Protein Array Analysis ; instrumentation ; methods ; Viruses ; chemistry ; isolation & purification

Microfluidic chip is a novel technology platform, in which microchannels are fabricated in different materials. The ability to precisely control the microflows makes it possible to mimic the microenvironment of cells in physiological or pathological states, which provides many distinct advantages for cell research. In this paper are reviewed the design and fabrication of microfluidic chip, the application of microfluidic chip in cell culture and cell researches; the enormous advantages of microfluidic chips in precise experimental control of the cellular microenvironment are introduced.
Cell Adhesion ; Cell Culture Techniques ; Cell Movement ; Cells, Cultured ; Cellular Microenvironment ; Humans ; Microfluidic Analytical Techniques ; methods