Non-Faradaic Electrochemical Detection of Exocytosis from Mast and Chromaffin Cells Using Floating-Gate MOS Transistors

Autor: David Holowka, Amit Singhai, Manfred Lindau, Yingqiu Cao, Krishna Jayant, Edwin C. Kan, Barbara Baird, Joshua B. Phelps
Rok vydání: 2015
Předmět:
Zdroj: Scientific Reports
ISSN: 2045-2322
Popis: Synaptic transmission and cell to cell communication in the human body are frequently characterized by the release of charged transmitters and other chemical mediators from secretory vesicles or granules which then impinge on specific receptor molecules expressed on target cells1,2,3. Depending on the excitable nature, the initiating cells respond to chemical inputs by releasing vesicular granules containing specific compounds or by inducing an electrical wave such as an action potential (AP). The process of vesicle fusion with the cell plasma membrane upon stimulation and subsequent release of the granular contents (i.e. in the form of quanta) into the extracellular environment is termed exocytosis4. When measured electrochemically such release events reveal a distinctive temporal response5,6. Exocytosis recordings are also often employed to characterize the mechanism of drug action on cells. For example, amperometric recordings have shown that the Parkinson’s drug L-Dopa increases the quantal size7, i.e. the total released charge increases, a consequence of increase vesicle size. There is thus a need to develop high throughput, scalable and multi-functional electronic instrumentation in order to characterize the action of various pharmacological inhibitors, toxins and stimulants on vesicle release. Transmitter and granular release can be specifically stimulated or inhibited depending on the cell type under study. In neurons, electrical excitations in the form of action potentials (AP) propagate along the axon and stimulate neurotransmitter release in the region between the axon terminus of the pre-synaptic neuron and the dendritic spine of the post-synaptic neuron [Fig. 1(a)] called the synapse. The released transmitters impinge on specific receptors on the post-synaptic neuron exciting or inhibiting action potential generation. In immune cells such as mast cells on the contrary, exocytosis can be induced through a receptor effector function where a specific antigen-receptor interaction causes a signal cascade within the cell, culminating in the release of chemical mediators which causes an allergic response. The released compounds from mast cells impinge on cells expressing specific receptors (such as the histamine receptor on smooth muscle cells) [Fig. 1(c)] and elicit a downstream response. In this study we seek to create a CMOS bio-sensor capable of detecting granule release from mast cells as a function of transmitter-receptor induced signaling. We then extend the approach to measuring depolarization induced activity from chromaffin cells where it can function as an electronic post-synaptic sensor [Fig. 1(d)]. Such a system not only provides a test bench for fundamental exocytotic analysis by monitoring release from vesicles and action potential’s with high temporal resolution, which is paramount in understanding cellular kinetics and establishing rapid screening procedures but also sets a promising route towards future artificial synapse systems and ionic-electronic interfacing circuitry. Figure 1 The cell-transistor synapse. The rat basophilic leukemia cell (RBL-2H3) is a tumor cell line used frequently as an experimental model for mucosal mast cells8. The release of inflammatory mediators from mast cells is the primary event in an allergic response9. These cells serve as a robust model for understanding the underlying biophysical and biochemical mechanism which couples signals originating at the membrane receptor with a biological effector function. Immunoglobulins of the IgE class serve as antigenic receptors which are anchored to cells via the membrane protein complex FceRI. Upon stimulation with multivalent antigen, the receptors crosslink causing a signal cascade within the cell, which eventually culminates in the secretion of preformed mediators stored in the cellular granules. Mast cells form a specialized niche of the immune system, because the triggered cellular activity is immediate. Depending on the particular type of mast cells or basophil’s, secretion occurs within seconds to minutes following the IgE cross linking step. Mast cells also provide a meaningful model for cell activation by an immunological stimulus, i.e., by an antibody-antigen reaction. We further demonstrate the device detection capability using chromaffin cells of the bovine adrenal medulla to detect neurotransmitter release and related electrical activity. The chromaffin cell is an excitable cell and allows us to study stimulus secretion coupling as mediated by both calcium entry and voltage gated channels, i.e., exocytosis induced by depolarization. Current methods of monitoring exocytosis include fluorescent techniques1,8,10,11, carbon-fiber amperometry12 and membrane capacitance measurements13. Fluorescence techniques often require labels and sophisticated optics, which increases the complexity of the experiment. On the other hand, amperometry may be prone to noise due to low current levels involved, relies on faradaic chemistry for detection, and is challenging to miniaturize in terms of pixel density, although recent efforts have resulted in significant improvements14,15,16. Non-faradaic transistor-based measurements on the contrary extend the detection capability to electrochemically inactive molecules, are extremely sensitive to surface adsorption, record cellular signals with a high degree of temporal sensitivity, present a naturally occurring high impedance node due to the gate oxide and can render sub-cellular spatial resolution17,18,19,20 with very low input referred noise characteristics21. Previous work on transistor-based cellular sensing has primarily focused on recording electrical activity from excitable cells such cardiac myocytes22,23 and nerve cells21,24. Recently Stern and co-workers25 extended transistor based sensing to detect antigen-stimulated T-cell activation detection by CMOS-compatible semiconducting nanowire sensors, however the exact signal generating mechanism was not investigated. In another report, transistor recording of vesicle release from chromaffin cells26 was demonstrated using open-gate ISFET’s. The recorded signal was attributed solely to the change in the local pH across the double-layer interface which leads to protonation of the surface and hence a change in surface potential. In this work, we extend this understanding and demonstrate the use of CMOS compatible floating gate transistors as cell based biosensors. Specifically we demonstrate that transistors can detect degranulation from electrically non-excitable cells such as the RBL-2H3 cell line and exocytosis from chromaffin cells. In addition to extracellular pH variation, we provide preliminary evidence suggesting direct molecular binding to the sensor surface as a signal generating mechanism. Since the nature of the FET interface allows one to record both electrochemical and ionic activities simultaneously we demonstrate the detection of AP’s and vesicle release simultaneously. Furthermore, we demonstrate simultaneous quasi-static and impedimetric based signal detection suggesting that FET’s could be used to readout passive membrane properties in addition to secreted charge.
Databáze: OpenAIRE
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