微电极阵列细胞传感器芯片技术的研究进展

综述了目前国际上基于微电极阵列技术的细胞传感器芯片的研究状况。介绍了微电极阵列的工艺设计、界面模型以及在细胞电生理研究中的应用,同时分析了细胞胞外记录技术在实现组织-细胞以及细胞间信号传导过程的实时动态检测的特点和目前存在的问题。在此基础上,介绍了单细胞以及细胞传感器网络芯片技术的发展。最后,提出微电极阵列细胞传感器研究的发展方向。     

High efficient electrical stimulation of hippocampal slices with vertically aligned carbon nanofiber microbrush array

Long-term neuroprostheses for functional electrical stimulation must efficiently stimulate tissue without electrolyzing water and raising the extracellular pH to toxic levels. Comparison of the stimulation efficiency of tungsten wire electrodes (W wires), platinum microelectrode arrays (PtMEA), as-grown vertically aligned carbon nanofiber microbrush arrays (VACNF MBAs), and polypyrrole coated (PPy-coated) VACNF MBAs in eliciting field potentials in the hippocampus slice indicates that, at low stimulating voltages that preclude the electrolysis of water, only the PPy-coated VACNF MBA is able to stimulate the CA3 to CA1 pathway. Unlike the W wires, PtMEA, as-grown VACNF MBA, and the PPy-coated VACNF MBA elicit only excitatory postsynaptic potentials (EPSPs). Furthermore, the PPy-coated VACNF MBA evokes somatic action potentials in addition to EPSPs. These results highlight the PPy-coated VACNF’s advantages in lower electrode impedance, ability to stimulate tissue through a biocompatible chloride flux, and stable vertical alignment in liquid that enables access to spatially confined regions of neuronal cells.     

Modification of risk for cancer as a coincidental finding in DNA array investigation

Rostasy K, Fauth C, Gautsch K, Laimer I, Krabichler B, Wimmer K, Frühmesser A, Kotzot D, Moshir S. Modification of risk for cancer as a coincidental finding in DNA array investigation. The high resolution of modern DNA arrays has the implification of unintended coincidental detection of gene deletions predisposing to late‐onset neurological and oncological disorders. Here, we report the case of an 18‐year‐old girl with mild intellectual disability, facial dysmorphisms, and a microdeletion of approximately 6.3 Mb on 22q12.1q12.3 including NF2, the gene for neurofibromatosis type 2, and CHEK2, a modifier gene for breast cancer. Subsequent magnetic resonance imaging of the brain showed she had already developed bilateral vestibular schwannomas. The challenge of DNA arrays and the consequences for genetic counselling and informed consent will be discussed in the light of this unique case with a microdeletion including both a high risk and a moderate risk cancer predisposition gene.     

Clear-cell papillary renal cell carcinoma: 24 cases of a distinct low-grade renal tumour and a comparative genomic hybridization array study of seven cases

Adam J, Couturier J, Molinié V, Vieillefond A & Sibony M
(2011) Histopathology 58, 1064–1071
Clear‐cell papillary renal cell carcinoma: 24 cases of a distinct low‐grade renal tumour and a comparative genomic hybridization array study of seven cases Aims: To report clinicopathological and genomic characteristics of (ccpRCC), a rare, recently characterized renal tumour entity. Methods and results: Twenty‐four renal tumours identified as ccpRCC were collected. Data from comparative genomic hybridization on microarrays (array‐CGH) were obtained for seven of these. Most tumours (58%) occurred in the absence of renal disease. Mean patient age was 58.1 years. Tumours were small (mean size: 2.4 cm) and classified as pT1. Histological characteristics consisted of tubules and papillae lined by a single layer of small clear cells harbouring low‐grade nuclei (Fuhrman grades 1 or 2). Architectural variations, with compact areas (41% of cases) and a micro‐ or macrocystic pattern (67% of cases) were observed frequently. Immunostaining demonstrated diffuse, strong expression of cytokeratin 7 and vimentin, whereas CD10, racemase, RCC antigen, translocation factor E3, TFE3 and translocation factor EB were consistently negative. In seven tumours, array‐CGH detected no chromosomal imbalances. Conclusions: Clear‐cell papillary renal cell carcinoma (ccpRCC) were differentiated from other renal neoplasms by a specific constellation of histopathological and immunohistochemical features, without characteristic genomic imbalances. Clinical, histopathological and genomic data suggested that these tumours have a low potential for malignancy.     

Application of a comprehensive subtelomere array in clinical diagnosis of mental retardation

In 2-8% of patients with mental retardation, small copy number changes in the subtelomeric region are thought to be the underlying cause. As detection of these genomic rearrangements is labour intensive using FISH, we constructed and validated a high-density BAC/PAC array covering the first 5 Mb of all subtelomeric regions and applied it in our routine screening of patients with idiopathic mental retardation for submicroscopic telomeric rearrangements. The present study shows the efficiency of this comprehensive subtelomere array in detecting terminal deletions and duplications but also small interstitial subtelomeric rearrangements, starting from small amounts of DNA. With our array, the size of the affected segments, at least those smaller than 5 Mb, can be determined simultaneously in the same experiment. In the first 100 patient samples analysed in our diagnostic practice by the use of this comprehensive telomere array, we found three patients with deletions in 3p, 10q and 15q, respectively, four patients with duplications in 9p, 12p, 21q and Xp, respectively, and one patient with a del 6q/dup 16q. The patients with del 3p and 10q and dup 12p had interstitial rearrangements that would have been missed with techniques using one probe per subtelomeric region chosen close to the telomere.     

Analysis method of cellular stress caused by intermediate dose-rate irradiation using a cell lysate array technique

Ionizing radiation damages DNA and may lead to the development of cancer. Irradiation also generates reactive oxygen species (ROS) which cause damage to various biological molecules. Relatively low dose-rate irradiation causes less damage. However, the damage and its effects on cell fate are difficult to evaluate. To develop a method to analyze the damage and accompanying changes in physiology in cells irradiated by γ-rays at a relatively low dose-rate, we used the protein array technique to quantify marker proteins involved in the stress response and the regulation of cell growth and death. This method enabled efficient analyses of many replicates of experimental data on cell lysate samples. We detected relatively small changes in the levels of these proteins in the irradiated cells. Changes in protein levels suggested ROS production and DNA damage as well as cell cycle retardation and the progression of cellular senescence. Thus, our approach shows promise for analyzing the biological effects of relatively low dose-rate irradiation.     

Application of CD27 as a marker for distinguishing human NK cell subsets

It has long been recognized that human NK cells can be dividedinto two phenotypically and functionally distinct subsets, basedon their levels of expression of CD56. We recently found thatCD27 distinguishes subsets of mature mouse NK cells. Here wereport that CD27 can be used as a marker to discriminate humanNK cell subsets. The majority of peripheral blood human NK cellswere CD27^lo/CD56^dim NK cells, whereas the minor CD27^hi NK cellpopulation correspondingly displayed a CD56^bright phenotype.Distinctions between CD27^lo and CD27^hi NK cells in their receptorexpression and typical NK cell functions such as cytotoxicityand cytokine production can be easily delineated. Therefore,we propose the dual use of CD27 and CD56 as maturation/subsetmarkers for human NK cells. The identification of CD27 subsetsin both mice and humans will allow more accurate projectionsof the role of NK cell subsets in murine models of human pathologieswhere NK cells are involved.     

Nanopillar sheets as a new type of cell culture dish: detailed study of HeLa cells cultured on nanopillar sheets

Nanopillar sheets were fabricated with high-aspect ratio structures with a diameter of 160–1000 nm and a height of 1 μm by nanoimprinting. The suitability of nanopillar sheets as a new type of cell culture dish was examined by studying the behavior of HeLa cells cultured on the sheets using light microscopy, scanning electron microscopy, and fluorescence microscopy observing actin and vinculin molecules. The nanopillar structure enabled easy subculture of the cells from the sheets without conventional trypsinization. Moreover, the HeLa cells divided and proliferated on the sheets in a different way to that found on petri dish because of the manner in which the cells adhered to the materials.     

Rapid Fabrication and Chemical Patterning of Polymer Microstructures and their Applications as a Platform for Cell Cultures

Much of the current knowledge regarding biological processes has been obtained through in-vitro studies in bulk aqueous solutions or in conventional Petri-dishes, with neither methodology accurately duplicating the actual in-vivo biological processes. Recently, a number of innovative approaches have attempted to address these shortcomings by providing substrates with controlled features. In particular, tunable surface chemistries and topographical micro and nanostructures have been used as model systems to study the complex biological processes. We herein report a versatile and rapid fabrication method to produce a variety of microstructured polymer substrates with precise control and tailoring of their surface chemistries. A poly(dimethylsiloxane) (PDMS) substrate, produced by replication over a master mold with specific microstructures, is modified by a fluoro siloxane derivative to enhance its anti-adhesion characteristics and used as a secondary replication mold. A curable material, deposited by spin coating on various substrates, is stamped with the secondary mold and crosslinked. The removal of the secondary mold produces a microstructured surface with the same topographical features as the initial master mold. The facile chemical patterning of the microstructured substrates is demonstrated through the use of microcontact printing methods and these materials are tested as a platform to guide cell attachment, growth and proliferation. The master mold and flexible fluorinated PDMS stamps can be used in a repeated manner without any degradation of the anti-adhesion characteristics opening the way to the development of high-throughput fabrication methods that can yield reliable and inexpensive microstructured and chemically patterned substrates.     

Expression of interferon-gamma receptors and interferon-gamma-induced up-regulation of intercellular adhesion molecule-1 in basal cell carcinoma; decreased expression of IFN-γR and shedding of ICAM-1 as a means to escape immune surveillance

The peritumoural inflammatory infiltrate in basal cell carcinoma (BCC) of the skin consists mainly of T lymphocytes which hardly invade the tumour nests. The absence of intercellular adhesion molecule-1 (ICAM-1) on BCC cells may explain the lack of tumour-infiltrating cells and the lack of an active cell-mediated immune response in this tumour. In this study, the induction of ICAM-1 was investigated in BCC biopsies using recombinant human interferon-gamma (rHuIFN-γ). The expression of interferon-gamma receptors (IFN-γR) in the biopsies was also investigated. The results showed that BCC cells expressed ICAM-1 after incubation with rHuIFN-γ, but to a lesser degree than normal epidermal cells. The levels of shed ICAM-1 were significantly increased in the culture supernatants of tumour biopsies compared with those from normal skin biopsies, after culturing in the presence of rHuIFN-γ. The expression of IFN-γR was significantly decreased on the tumour cells compared with the overlying epidermis. The decreased expression of IFN-γR on the tumour cells and the shedding of ICAM-1 into the peritumoural stroma may be a plausible mechanism by which the tumour cells are protected against an active cell-mediated immune response. © 1998 John Wiley & Sons, Ltd.     

Longevity of human allospecific TLCs: Mycoplasma infection as a cause of in vitro “suppression” of MLC

It has been suggested that allospecific T-cell clones lose specific reactivity after approximately 30 cell doublings and subsequently acquire suppressor and NK-like characteristics. We have tested this hypothesis by assaying paired functional and nonfunctional TLCs for suppressor activity in PLT and MLC cocultures. Two sets of clones were initially studied: the first pair consisted of clone S5.2B, a functional TLC, and S5.14A, a nonfunctional TLC; the second pair of clones tested was comprised of two different expansions of the same clone S5.5A (nnfunctional) and S5.5B (functional). These experiments yielded no evidence for suppressive activity by nonfunctional clones toward functional clones, furthermore, the addition of nonfunctional clones to primary MLC assays had no effect on the level of responsiveness. Eight clones were subcloned and 89 subclones were retested for function after approximately 50 cell doublings. Generally, the subclones failed to suppress MLC proliferation. A minority of TLCs could suppress MLC responses, but this “suppression” was reversible with the addition of 2% exogenous TCGF. However, eight subclones and two parental TLC lines did suppress MLC responses in the presence or absence of TCGF, but the suppressive effects in such cocultures were reversible in the presence of tylocine, an anti-mycoplasma antibiotic. Therefore, human T -cells, cultured for extended periods, do not inexorably and universally lose specific alloreactivity and gain suppressive characteristics due to some presumed differentiative event.     

Matrigel-embedded 3D culture of Huh-7 cells as a hepatocyte-like polarized system to study hepatitis C virus cycle

Hepatocytes are highly polarized cells where intercellular junctions, including tight junctions (TJs), determine the polarity. Recently, the TJ-associated proteins claudin-1 and occludin have been implicated in hepatitis C virus (HCV) entry and spread. Nevertheless, cell line-based experimental systems that exhibit hepatocyte-like polarity and permit robust infection and virion production are not currently available. Thus, we sought to determine whether cell line-based, Matrigel-embedded cultures could be used to study hepatitis C virus (HCV) infection and virion production in a context of hepatocyte-like polarized cells. In contrast to standard bidimensional cultures, Matrigel-cultured Huh-7 cells adopted hepatocyte polarization features forming a continuous network of functional proto-bile canaliculi structures. These 3D cultures supported HCV infection by JFH-1 virus and produced infective viral particles which shifted towards lower densities with higher associated specific infectivity. In conclusion, our findings describe a novel use of Matrigel to study the entire HCV cycle in a more relevant context.