Microchip for sustained drug delivery by diffusion through microchannels

To enable sustained drug delivery, we prepared microchips of simple structure for drug release based on diffusion through microchannels. The microchips were fabricated with poly(methyl methacrylate), embedded with one or more microwells and microchannels of controlled length. The channels were filled with biocompatible polymer, poly(ethylene glycol), to serve as a drug diffusion barrier. The wells served as drug reservoirs and were filled with a fine powder of a model compound, fluorescein. Three different drug delivery microchip designs were prepared, each equipped with a channel of 1, 4, or 8 mm length. Drug release from these devices all exhibited a delay followed by sustained release over time. As the channel length increased from 1 to 8 mm, the onset time and duration of drug release also increased from 0.5 to 7 day and from 11 days to 28, respectively. We also prepared microchips equipped with multiple microwells, each connected to a channel of different length. In this way, a chip with channels of 1, 4, and 8 mm length exhibited a continuous drug release from 0.5 to 35 days. A future study is in progress to develop the microchips made of biodegradable materials. Therefore, we conclude that a microchip embedded with multiple sets of microwells and microchannels of different length can be designed to enable sustained drug release for controlled and prolonged periods of time.     

A novel method for transuterine identification of piglets

Implantable microchips provide a secure, permanent and unique identification of individual animals. When performing fetal intervention studies in experimental animal models easy and secure identification of fetuses is desirable, as having test and control groups within the same uterus reduces the total number of animals used in a study. The aims of this study were: (1) to establish a protocol to identify porcine fetuses in utero by microchip implantation and (2) to assess postnatally whether clinical or pathological reactions to the implant occurred. Two Danish Landrace/Danish Large White crossbred sows at day 100 of gestation were used. The sows were sedated with azaperone and induced with propofol intravenously. Anaesthesia was maintained with isoflurane and oxygen. Antibiotics were administered intramuscularly (i.m.) at induction and analgesia was given pre-, intra- and postoperatively. A laparotomy was performed and the uterus exteriorized. The rump of the first fetus was recognized through the uterine wall and the thigh muscle of the fetus was fixed between the thumb and the forefinger. The microchip was then implanted into the fetus at an angle of 45 degrees i.m. in the lateral hindleg using an insertion device with a 12G needle. The same procedure was done in every fetus. The uterus was returned to the abdomen and the abdominal wall closed. The sows gave birth to 24 liveborn piglets and one stillborn. None of the liveborn piglets were limping at the time of birth and no visible cutaneous or palpable reactions on the hindlegs were observed. Following euthanasia, the microchip was easily localized and no macroscopic reactions at the implantation site were seen. None of the piglets had more than one microchip implanted. Histology showed a chronic mild foreign body granulomatous inflammatory response with peripheral eosinophils surrounding the microchip. No inflammation was evident in the adjacent muscles. It is concluded that transuterine identification of piglets two weeks before delivery is feasible using a microchip implant as an effective, easy and reliable method for identification of individuals after birth.     

Near-Infrared Metal-Enhanced Fluorescence Using a Liquid–Liquid Droplet Micromixer in a Disposable Poly(Methyl Methacrylate) Microchip

Solution-based metal-enhanced fluorescence of near-infrared fluorophores in a poly(methyl methacrylate) microchip is studied. A liquid–liquid droplet micromixer is used for rapid mixing of fluorophores with silver nanoparticles while maintaining discrete packets of known analytes for reproducible quantitative analysis. Nanoparticle aggregation within the microchip is controlled by individually adjusting salt concentration, colloid concentration, and mixing efficiency. Results identify an optimal salt concentration for aggregate formation and enhanced fluorescence, while the impacts of colloid concentration and mixing efficiency increase linearly, suggesting the possibility of further enhancement. Fluorescence enhancements of 35-fold were achieved on a microfluidics device using metal-enhanced fluorescence in a discrete solution-based system with exposure times of only 50 ms.     

Fabrication of amino silane-coated microchip for DNA extraction from whole blood

A simple microchip device for DNA extraction was constructed based on electrostatic interactions between surface amine groups and DNA. Microchannel was fabricated on silicon wafer by photolithography and coated with 3-aminopropyltriethoxysilane (APTES) or 3-[2-(2-aminoethylamino)-ethylamino]-propyltrimethoxysilane (AEEA) to introduce amine groups on the surface. Determination of the number of surface amine groups and optimization of DNA capture condition were demonstrated to characterize the microchip. Capacities of capturing DNA were approximately 97 ng/cm2 in APTES and 194 ng/cm2 in AEEA modified microchips, respectively. The amount of DNA captured in the microchip increased depending on surface amine density. Furthermore, DNA extraction using amine-coated microchip from whole blood was examined. Quantification of DNA and proteins in washing or eluting fraction indicates that proteins were removed at washing steps and only DNA was effectively eluted by changing alkalinity of buffer from pH 7.5 to 10.6. The amount of DNA extracted from whole blood was approximately 10 ng and its recovery ratio was 27-40%. Performance of PCR for the eluted fraction indicates that DNA extracted from whole blood was well purified using amine-coated microchip.     

A dielectrophoretic microchip for controlled cell targeting with functionalized microspheres

Individual cell manipulation and targeting is of major interest in the field of diagnosis, phenotypic characterization and drug delivery. Lab-on-a-chip technologies open the possibility to work easily at the single cell level. We developed a dielectrophoretic microchip capable to trap and manipulate individual cells and microspheres. We targeted single cells with functionalized microspheres in a software-controlled way proving the efficiency and reliability of our chip. As an example, we demonstrate guided targeting and binding of cell lines expressing or not specific antigens with microspheres coated or not with the corresponding monoclonal antibodies.     

Gold nanoparticle assembly microfluidic reactor for efficient on-line proteolysis

A microchip reactor coated with a gold nanoparticle network entrapping trypsin was designed for the efficient on-line proteolysis of low level proteins and complex extracts originating from mouse macrophages. The nanostructured surface coating was assembled via a layer-by-layer electrostatic binding of poly(diallyldimethylammonium chloride) and gold nanoparticles. The assembly process was monitored by UV-visible spectroscopy, atomic force microscopy, and quartz crystal microbalance. The controlled adsorption of trypsin was theoretically studied on the basis of the Langmuir isotherm model, and the fitted Gamma(max) and K values were estimated to be 1.2 x 10(-7) mol/m(2) and 4.1 x 10(5) M(-1), respectively. An enzymatic kinetics assay confirmed that trypsin, which was entrapped in the biocompatible gold nanoparticle network with a high loading capacity, preserved its bioactivity. The maximum proteolytic rate of the adsorbed trypsin was 400 mM/(min.microg). Trace amounts of proteins down to femtomole per analysis were digested using the microchip reactor, and the resulting tryptic products were identified by MALDI-TOF MS/MS. The protein mixtures extracted from the mouse macrophages were efficiently identified by on-line digestion and LC-ESI-MS/MS analysis.     

Dye with low specificity to nucleotide sequences of DNA: use for assessing the quantity of oligonucleotides, immobilized in cells of biological microchips

To assess the DNA amount in samples (e.g., in biological microchip gel pads) by means of fluorescent dyes, one should use the dyes whose fluorescence weakly depends on DNA composition and structure. With the ImD-310 dye created for this purpose, we have analyzed the staining of single- and double-stranded oligo- and polynucleotides of different nucleotide composition, length, and concentration both in solution and being immobilized in biological microchip gel pads. It turned out that ImD-310 has no pronounced specificity to the single- and double-stranded nucleotide sequences, while the intensity of fluorescence for the dye complexes with d(A)8, d(T)8, d(C)8, and d(G)8 at high temperatures (50 degrees C) differs by less than 25%. A linear correlation has been established between the intensity of fluorescence and the amount of oligonucleotides immobilized on a biological microchip. The plots of the intensity of fluorescence against the concentration of NaCl and the temperature were obtained. By using a generic microchip containing all 4096 hexamer oligonucleotides, it has been determined that the dye has no distinct specificity to any certain motifs of the nucleotide sequence. Thus, ImD-310 may serve as an efficient fluorescent probe to quickly estimate the amount of oligonucleotides immobilized in a microchip, in an electrophoretic gel, etc.     

糖芯片研究进展

糖芯片是生物芯片的一种,是继基因芯片、蛋白质芯片、组织芯片等之后发展起来的一种很有前景的生物检测技术。随着糖生物学和糖组学的研究进展,糖芯片正逐步发展为该领域的新型研究手段。介绍了糖芯片技术及其制作方法,高通量分析平台以及糖芯片在生物学研究和医学领域的具体应用,同时也对糖芯片技术的发展进行了展望。     

Parallel thermodynamic analysis of duplexes on oligodeoxyribonucleotide microchips.

A microchip method has been developed for massive and parallel thermodynamic analyses of DNA duplexes. Fluorescently labeled oligonucleotides were hybridized with oligonucleotides immobilized in the 100 x 100 x 20 mum gel pads of the microchips. The equilibrium melting curves for all microchip duplexes were measured in real time in parallel for all microchip duplexes. Thermodynamic data for perfect and mismatched duplexes that were obtained using the microchip method directly correlated with data obtained in solution. Fluorescent labels or longer linkers between the gel and the oligonucleotides appeared to have no significant effect on duplex stability. Extending the immobilized oligonucleotides with a four-base mixture from the 3'-end or one or two universal bases (5-nitroindole) from the 3'- and/or 5'-end increased the stabilities of their duplexes. These extensions were applied to increase the stabilities of the duplexes formed with short oligonucleotides in microchips, to significantly lessen the differences in melting curves of the AT- and GC-rich duplexes, and to improve discrimination of perfect duplexes from those containing poorly recognized terminal mismatches. This study explored a way to increase the efficiency of sequencing by hybridization on oligonucleotide microchips.     

Microfluidic based immunoassay

This paper describes the different aspects of the design of rapid and sensitive immunoassays in a microchip platform, with accurate control of the fluidics inside the microchannels. In order to get the required sensitivity and reproducibility, it is notably necessary to monitor and actively control the fluidic events at each step of the assay. Particularly, it is important to know at what linear velocity the liquid is transported through the microfluidic reactor, and we will show here how individual flow sensors inserted in each channel of the disposable chip can be used to precisely monitor the fluid flows within microchannels, and this with various fluid delivery means.     

Urinary metabolic network analysis in trauma, hemorrhagic shock, and resuscitation

Hemorrhagic shock, often a result of traumatic injury, is a condition of reduced perfusion that results in diminished delivery of oxygen to tissues. The disruption in oxygen delivery induced by both ischemia (diminished oxygen delivery) and reperfusion (restoration of oxygen delivery) has profound consequences for cellular metabolism and the maintenance of homeostasis. The pathophysiologic state associated with traumatic injury and hemorrhagic shock was studied with a scale-invariant metabolic network. Urinary metabolic profiles were constructed from NMR spectra of urine samples collected at set timepoints in a porcine model of hemorrhagic shock that included a pulmonary contusion, a liver crush injury, and a 35 % controlled bleed. The network was constructed from these metabolic profiles. A partial least squares discriminant analysis (PLS-DA) model that discriminates by experimental timepoint was also constructed. Comparisons of the network (functional relationships among metabolites) and PLS-DA model (observable relationships to experimental time course) revealed complementary information. First, ischemia/reperfusion injury and evidence of cell death due to hemorrhage was associated with early resuscitation timepoints. Second, evidence of increased protein catabolism and traumatic injury was associated with late resuscitation timepoints. These results are concordant with generally accepted views of the metabolic progression of shock.     

Alginate gel microchip for real-time monitoring of intracellular processes in bacterial and yeast cells

A method of alginate-based hydrogel cell microchip manufacturing is proposed. The development of mild conditions for cell immobilization in microvolumes of non-toxic alginate gel allows extending the range of microorganisms used. Different approaches to cell analysis using microchip have been approved in pilot studies. By the example of Escherichia coli, Bordetella bronchiseptica and Saccharomyces cerevisiae it is shown that cell microchip can be successfully applied for monitoring of nucleic acid and protein synthesis in growing cells simultaneously using two fluorescent dyes. The influence of chloramphenicol on the nucleic acids and protein synthesis in five bacterial strains has been studied on the microchip. The microchip was also applied for the analysis of inducible fluorescent protein EGFP synthesis in E. coli cells, the correlation between the level of EGFP synthesis and concentration of the inductor in the medium has been established.     

Biological Microchips with Hydrogel-Immobilized Nucleic Acids,Proteins, and Other Compounds: Properties and Applications in Genomics

The MAGIChip (MicroArrays of Gel-Immobilized Compounds on a chip) consists of an array of hydrophilic gel pads fixed on a hydrophobic glass surface. These pads of several picoliters to several nanoliters in volume contain gel-immobilized nucleic acids, proteins, and other compounds, as well as live cells. They are used to conduct chemical and enzymatic reactions with the immobilized compounds or samples bound to them. In the latter case, nucleic acid fragments can be hybridized, modified, and fractionated within the gel pads. The main procedures required to analyze nucleic acid sequences (PCR, detachment of primers and PCR-amplified products from a substrate, hybridization, ligation, and others) can be also performed within the microchip pads. A flexible, multipurpose, and inexpensive system has been developed to register the processes on a microchip. The system provides unique possibilities for research and biomedical applications, allowing one to register both equilibrium states and the course of reaction in real time. The system is applied to analyze both kinetic and thermodynamic characteristics of molecular interaction in the duplexes formed between nucleic acids and the probes immobilized within the microchip gel pads. Owing to the effect of stacking interaction of nucleic acids, the use of short oligonucleotides extends the possibilities of microchips for analysis of nucleic acid sequences, allowing one to employ the MALDI-TOF mass spectrometry to analyze the hybridization data. The specialized MAGIChips has been successfully applied to reveal single-nucleotide polymorphism of many biologically significant genes, to identify bacteria and viruses, to detect toxins and characterize the genes of pathogenic bacteria responsible for drug resistance, and to study translocations in the human genome. On the basis of the MAGIChip, protein microchips have been created, containing immobilized antibodies, antigens, enzymes, and many other substances, as well as microchips with gel-immobilized live cells.     

Biological microchips with hydrogel-immobilized nucleic acids,proteins, and other compounds: properties and applications in genomics

The MAGIChip (MicroArrays of Gel-Immobilized Compounds on a chip) consists of an array of hydrophilic gel pads fixed on a hydrophobic glass surface. These pads of several picoliters to several nanoliters in volume contain the gel-immobilized nucleic acids, proteins, and other compounds, as well as live cells. They are used to conduct chemical and enzymatic reactions with the immobilized compounds or samples bound to them. In the latter case, nucleic acid fragments can be hybridized, modified, and fractionated within the gel pads. The main procedures required to analyze nucleic acid sequences (PCR, detachment of primers and PCR-amplified products from a substrate, hybridization, ligation, and others) can be also performed within the microchip pads. A flexible, multipurpose, and inexpensive system has been developed to register the processes proceeding on a microchip. The system provides unique possibilities for research and biomedical applications, allowing one to register both equilibrium states and the course of reaction in real time. The system is applied to analyze both kinetic and thermodynamic characteristics of molecular interaction in the duplexes formed between nucleic acids and the probes immobilized within the microchip gel pads. Owing to the effect of stacking interaction of nucleic acids, the use of short oligonucleotides extends the possibilities of microchips for analysis of nucleic acid sequences, allowing one to employ the MALDI-TOF mass spectrometry to analyze the hybridization data. The specialized MAGIChips has been successfully applied to reveal single nucleotide polymorphism of many biologically significant genes, to identify bacteria and viruses, to detect toxins and characterize the genes of pathogenic bacteria responsible for drug resistance, and to study translocations in the human genome. On the basis of the MAGIChip, the protein microchips have been created, containing the immobilized antibodies, antigens, enzymes, and many other substances, as well as the microchips with the gel-immobilized live cells.     

A system for the application of general anaesthetics and other volatile agents to superfused, isolated tissue preparations

1. A delivery system for the application of general anaesthetics or other gaseous and volatile agents to superfused, isolated preparations is described in detail. 2. This system delivers known concentrations of anaesthetic and controls for evaporation and absorption of volatile agents, whilst allowing intracellular electrophysiological recordings to be made from the tissue with minimal disturbance. 3. In particular, this delivery system permits accurate, controlled experiments to be carried out on the neuronal actions of general anaesthetics.     

Determination of endogenous extracellular signal-regulated protein kinase by microchip capillary electrophoresis

The application of microchip capillary electrophoresis (CE) to the assay of extracellular signal-regulated protein kinase (ERK) is presented. In this assay, ERK catalyzes the transfer of gamma-phosphate from adenosine 5(')-triphosphate to the threonine residue of a fluorescently labeled nonapeptide (APRTPGGRR), and the phosphorylated and nonphosphorylated peptides were detected by fluorescence. The phosphorylated and nonphosphorylated peptides and the internal standard were separated within 20s, and the increase in magnitude of the phosphorylated peptide peak was monitored to assess ERK activity. ERK reactions were prepared off-chip and analyzed on a single-lane glass microchip fabricated by standard methods. It was demonstrated that microchip CE could be used to measure endogenous amounts of ERK by spiking known concentrations of recombinant ERK2 into the lysates of serum-starved human umbilical vein endothelial cells (HUVEC) and recovering between 90 and 100% for all samples. Endogenous ERK activity was determined by microchip where HUVEC were stimulated with 500pM vascular endothelial growth factor (VEGF) at different times before cell lysis. The results showed a transient VEGF-mediated ERK activation that peaked at 10min, which was consistent with previous reports using conventional techniques. The microchip assay provided a rapid, accurate, and precise alternative to conventional methods of determining endogenous ERK activity.     

一种细胞培养微芯片的制作及应用

细胞培养是细胞研究的基础, 微系统技术的发展给细胞培养提供了新的方法。在微系统平台上进行细胞研究,能够充分利用微流体和微结构的性质, 对细胞进行操控, 在细胞生物学、组织工程学、药物筛选等领域有广泛应用。介绍了一种利用SU-8负性光刻胶模具制作双层细胞培养微芯片的方法, 该芯片通过狭缝将细胞培养区和微通道区隔离, 既保证细胞培养区域的相对独立, 又可以利用微流体的特性调节细胞外基质的性质, 给基于微芯片进行细胞研究提供了一种新的平台。     

Stimuli-responsive controlled-release system using quadruplex DNA-capped silica nanocontainers

A novel proton-fueled molecular gate-like delivery system has been constructed for controlled cargo release using i-motif quadruplex DNA as caps onto pore outlets of mesoporous silica nanoparticles. Start from simple conformation changes, the i-motif DNA cap can open and close the pore system in smart response to pH stimulus. Importantly, the opening/closing and delivery protocol is highly reversible and a partial cargo delivery can be easily controlled at will. A pH-switchable nanoreactor has also been developed to validate the potential of our system for on-demand molecular transport. This proof of concept might open the door to a new generation of carrier materials and could also provide a general route to use other functional nucleic acids/peptide nucleic acids as capping agents in the fields of versatile controlled delivery nanodevices.     

Analysis of perfect and mismatched DNA duplexes by a generic hexanucleotide microchip

The thermodynamic analysis was done for the duplexes formed by fluorescently labeled oligonucleotide targets on a genetic hexanucleotide microchip. All 4096 different hexanucleotide chains were immobilized as probes in individual gel pads of the microchip. To strengthen the hybridization, each hexamer was extended at both ends by one nucleotide from the equimolar mixture of all four nucleotides to serve as nonselective linkers. It has been shown that the melting curves for oligonucleotide duplexes formed on the microchip and in a solution are quite similar. The influence of ionic surrounding has been studied in terms of the hybridization efficiency and discrimination between the mismatched and perfect duplexes. Different approaches have been tested to compensate the dependence of duplex stability on the GC content. It has been demonstrated that the use of chaotropic agents, addition of nonlabeled GC-rich competitor oligonucleotides, as well as creation of a temperature gradient along the microchip reproducing the distribution of melting temperatures, efficiently level out the AT/GC differences. The use of tetramethylammonium chloride for the same purpose was accompanied by weakening to some extent the discrimination between the mismatched duplexes and the perfect ones.