Integrated Nanoplasmonic Sensing for Cellular Functional Immunoanalysis Using Human Blood

Localized surface plasmon resonance (LSPR) nanoplasmonic effects allow for label-free, real-time detection of biomolecule binding events on a nanostructured metallic surface with simple optics and sensing tunability. Despite numerous reports on LSPR bionanosensing in the past, no study thus far has applied the technique for a cytokine secretion assay using clinically relevant immune cells from human blood. Cytokine secretion assays, a technique to quantify intercellular-signaling proteins secreted by blood immune cells, allow determination of the functional response of the donor’s immune cells, thus providing valuable information about the immune status of the donor. However, implementation of LSPR bionanosensing in cellular functional immunoanalysis based on a cytokine secretion assay poses major challenges primarily owing to its limited sensitivity and a lack of sufficient sample handling capability. In this paper, we have developed a label-free LSPR biosensing technique to detect cell-secreted tumor necrosis factor (TNF)-α cytokines in clinical blood samples. Our approach integrates LSPR bionanosensors in an optofluidic platform that permits trapping and stimulation of target immune cells in a microfluidic chamber with optical access for subsequent cytokine detection. The on-chip spatial confinement of the cells is the key to rapidly increasing a cytokine concentration high enough for detection by the LSPR setup, thereby allowing the assay time and sample volume to be significantly reduced. We have successfully applied this approach first to THP-1 cells and then later to CD45 cells isolated directly from human blood. Our LSPR optofluidics device allows for detection of TNF-α secreted from cells as few as 1000, which translates into a nearly 100 times decrease in sample volume than conventional cytokine secretion assay techniques require. We achieved cellular functional immunoanalysis with a minimal blood sample volume (3 μL) and a total assay time 3 times shorter than that of the conventional enzyme-linked immunosorbent assay (ELISA).

[1]  Katsuo Kurabayashi,et al.  Emerging Microfluidic Tools for Functional Cellular Immunophenotyping: A New Potential Paradigm for Immune Status Characterization , 2013, Front. Oncol..

[2]  R. Ohye,et al.  Clinical implications and molecular mechanisms of immunoparalysis after cardiopulmonary bypass. , 2012, The Journal of thoracic and cardiovascular surgery.

[3]  Prakash D Nallathamby,et al.  Photostable single-molecule nanoparticle optical biosensors for real-time sensing of single cytokine molecules and their binding reactions. , 2008, Journal of the American Chemical Society.

[4]  Guohui Xiao,et al.  Plasmonic gold mushroom arrays with refractive index sensing figures of merit approaching the theoretical limit , 2013, Nature Communications.

[5]  Josef Lazar,et al.  Suppression of Air Refractive Index Variations in High-Resolution Interferometry , 2011, Sensors.

[6]  John Mitchell,et al.  Small Molecule Immunosensing Using Surface Plasmon Resonance , 2010, Sensors.

[7]  Richard P Van Duyne,et al.  LSPR Biosensor Signal Enhancement Using Nanoparticle-Antibody Conjugates. , 2011, The journal of physical chemistry. C, Nanomaterials and interfaces.

[8]  Y. Liu,et al.  Cytokine biosensors: the future of infectious disease diagnosis? , 2012, Expert review of anti-infective therapy.

[9]  J. Hafner,et al.  Localized surface plasmon resonance sensors. , 2011, Chemical reviews.

[10]  Peter H Seeberger,et al.  Optimization of localized surface plasmon resonance transducers for studying carbohydrate-protein interactions. , 2012, Analytical chemistry.

[11]  D. A. Stuart,et al.  Biological applications of localised surface plasmonic phenomenae. , 2005, IEE proceedings. Nanobiotechnology.

[12]  Tatsuro Endo,et al.  Localized surface plasmon resonance based optical biosensor using surface modified nanoparticle layer for label-free monitoring of antigen–antibody reaction , 2005 .

[13]  Longhua Guo,et al.  LSPR biomolecular assay with high sensitivity induced by aptamer-antigen-antibody sandwich complex. , 2012, Biosensors & bioelectronics.

[14]  R. Hotchkiss,et al.  Immunosuppression in Patients Who Die of Sepsis and Multiple Organ Failure , 2012 .

[15]  R. V. Van Duyne,et al.  Localized surface plasmon resonance spectroscopy and sensing. , 2007, Annual review of physical chemistry.

[16]  G. Whitesides,et al.  Self-assembled organic monolayers: model systems for studying adsorption of proteins at surfaces , 1991, Science.

[17]  H. Wong,et al.  CONTRIBUTION OF MKP-1 REGULATION OF p38 TO ENDOTOXIN TOLERANCE , 2005, Shock.

[18]  Katsuo Kurabayashi,et al.  An integrated microfluidic platform for in situ cellular cytokine secretion immunophenotyping. , 2012, Lab on a chip.

[19]  J. Hafner,et al.  A label-free immunoassay based upon localized surface plasmon resonance of gold nanorods. , 2008, ACS nano.

[20]  Jong-Tae Lim,et al.  Fair TCP congestion control in heterogeneous networks with explicit congestion notification , 2005 .

[21]  Katsuo Kurabayashi,et al.  Surface‐Micromachined Microfiltration Membranes for Efficient Isolation and Functional Immunophenotyping of Subpopulations of Immune Cells , 2013, Advanced healthcare materials.

[22]  H. P. Benton Cytokines and their receptors. , 1991, Current opinion in cell biology.

[23]  M. Neil,et al.  Scaling advantages and constraints in miniaturized capture assays for single cell protein analysis. , 2013, Lab on a chip.

[24]  Stanley He,et al.  MYCN and the epigenome , 2013, Front. Oncol..

[25]  Masato Saito,et al.  A Microfluidic Chip Based on Localized Surface Plasmon Resonance for Real-Time Monitoring of Antigen-Antibody Reactions , 2008 .

[26]  Tatsuro Endo,et al.  Label-free cell-based assay using localized surface plasmon resonance biosensor. , 2008, Analytica chimica acta.