Name: nanosensors to detect protease activity in vivo for noninvasive diagnostics
Uploaded: 2018-07-16T14:30:00
Description: Watch this Scientific Journal Video about Nanosensors to Detect Protease Activity In Vivo for Noninvasive Diagnostics at JoVE.com

This work was funded by an NIH Director&#39;s New Innovator Award (Award No. DP2HD091793). Q.D.M. is supported by the NSF Graduate Research Fellowships Program (Grant No. DGE-1650044). B.A.H is supported by the National Institutes of Health GT BioMAT Training Grant under Award Number 5T32EB006343 as well as the Georgia Tech President&#39;s Fellowship. G.A.K. holds a Career Award at the Scientific Interface from the Burroughs Welcome Fund. The content is solely the responsibility of the authors and does not necessarily represent the official views of the National Institutes of Health.

Institutional approval from Institutional Animal Care and Use Committee (IACUC) at the researcher&#39;s institution is necessary to carry out the following animal experiments. Additionally, standard animal care facilities (e.g., housing chambers, sterile animal hoods, isofluorane chambers for anesthetization, and CO2 chambers for ethical endpoint euthanization) are necessary to properly carry out these experiments. Special training and assistance with these facilities can be provided by the Physiologi...

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This method describes the development of activity-based nanosensors consisting of protease substrates conjugated to a nanoparticle core. The event of proteolytic cleavage is dubbed the &#34;pharmacokinetic switch&#34;, because cleaved peptide products are smaller than the renal size filtration limit of 5 nm23&#160;and filter into urine to produce a noninvasive signal. Therefore, it is important to use nanoparticles or carriers with a hydrodynamic radius that is larger than 5 nm, as anything smalle...

Proteases are multi-functional enzymes that specialize in the hydrolysis of peptide-bonds and have significant control over many biological processes, including homeostasis, allostasis, and disease1. An altered state of protease activity has been correlated to a variety of diseases, including cancer and cardiovascular disease, making proteases attractive candidates for development into clinical biomarkers2,3. Moreover, protease activity is functionally linked to distinct pathogeneses, patient outcomes, and prognosis of disease4. Broadly, biosensors have been developed to detect various biological phenomena and diseases, such as cancer, neurodegenerative disease, and electron transfer processes5,6,7,8,9. More specifically, substrate-based protease sensors have been developed to detect protease activity, and include fluorogenic probes for diagnostic imaging10 and isotopically labeled peptide substrates for in vitro detection by mass spectrometry11. In addition, activity-based probes have been developed, which contain substrate-like regions that bind or modify the target protease12. With this method, the target protease is irreversibly inhibited when the active site is modified, and analysis requires harvesting of tissue, which limits in vivo applications. However, it is important to sense protease activity in vivo, because regulation of protease activity is heavily dependent on the context of other biological activities such as the presence of endogenous inhibitors.
The goal of this work is to describe the formulation of activity-based nanosensors that detect protease activity in vivo by producing a measurable signal in urine. This platform is used as a noninvasive diagnostic to discriminate complex diseases such as cancer by using dysregulated protease activity as a functional biomarker. Our nanosensor platform consists of iron oxide nanoparticles (IONP) conjugated to protease substrates. These substrates are terminated by a fluorescent reporter which is released when proteases cleave the substrate. These IONPs circulate in vivo, localize to disease sites, and expose substrates to active disease-associated proteases. After cleavage, fluorescent reporters are released and, due to their small size, are filtered into urine, while uncleaved substrates on the IONP remain in the body. Therefore, an increase in protease activities in vivo will result in higher concentrations of reporter in urine (Figure 1). Since our platform is a urine test, no imaging platform is required and diagnostic signals are enriched in urine.
This platform can be engineered to detect a variety of diseases including cancer, fibrosis, and thrombosis13,14. Here we describe the design of nanosensors to detect elevations in Matrix metallopeptidase 9 (MMP9) activity as a biomarker of colorectal cancer. Colorectal cancer is the second leading cause of cancer death in the United States, with an estimated 136,800 new cases and 50,300 deaths in 2014 alone15. Colorectal tumor cells produce MMP9, which has been shown to drive malignant progression , matrix degradation, as well as metastasis16. Additionally, we identified a suitable peptide substrate (PLGVRGK) for MMP9 from the literature17. This platform may be used for early cancer detection and low-cost point-of-care diagnostics13,14,18,19,20,21.
<img alt="Figure 1" class="xfigimg" src="/files/ftp_upload/57937/57937fig1.jpg" /> 
Figure 1: Schematic of Nanosensor Activity In vivo. Nanosensors circulate through the body and localize to sites of disease. Then, disease-related proteases cleave peptide substrates presented by IONPs. The size of cleaved fragments allows for renal clearance, causing them to localize in the urine. After the animal urinates, these peptide fragments can be analyzed by their reporter molecule. <a href="https://www.jove.com/files/ftp_upload/57937/57937fig1large.jpg" target="_blank">Please click here to view a larger version of this figure.</a>

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			<td height="21" style="height:21px;width:375px;">0.2 &#181;m syringe filters</td>
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			<td height="21" style="height:21px;width:375px;">Tris-HCl</td>
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			<td height="21" style="height:21px;width:375px;">BD Insulin Syringes</td>
			<td style="width:171px;">Fisher</td>
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nanosensors to detect protease activity in vivo for noninvasive diagnostics

Proteases are multi-functional enzymes that specialize in the hydrolysis of peptide-bonds and control broad biological processes including homeostasis and allostasis. Moreover, dysregulated protease activity drives pathogenesis and is a functional biomarker of diseases such as cancer; therefore, the ability to detect protease activity in vivo may provide clinically relevant information for biomedical diagnostics. The goal of this protocol is to create nanosensors that probe for protease activity in vivo by producing a quantifiable signal in urine. These protease nanosensors consist of two components: a nanoparticle and substrate. The nanoparticle functions to increase circulation half-life and substrate delivery to target disease sites. The substrate is a short peptide sequence (6-8 AA), which is designed to be specific to a target protease or group of proteases. The substrate is conjugated to the surface of the nanoparticle and is terminated by a reporter, such as a fluorescent marker, for detection. As dysregulated proteases cleave the peptide substrate, the reporter is filtered into urine for quantification as a biomarker of protease activity. Herein we describe construction of a nanosensor for matrix metalloproteinase 9 (MMP9), which is associated with tumor progression and metastasis, for detection of colorectal cancer in a mouse model.

The majority of the population of the IONPs is around the average diameter, which ranges from 40 - 50 nm. After pegylation, this size range has a circulation half-life of approximately 6 hours13&#160;in vivo (see Figure 2a). If one wants to select for a particular size range, one can use size exclusion chromatography to isolate IONP fractions with different diameters. The nanoparticles by TEM will appear as individual spherica...

Watch this Scientific Journal Video about Nanosensors to Detect Protease Activity In Vivo for Noninvasive Diagnostics at JoVE.com

Nanosensors to Detect Protease Activity In Vivo for Noninvasive Diagnostics

Proteases are tightly regulated enzymes involved in fundamental biological processes, and dysregulated protease activity drives progression of complex diseases such as cancer. This method&#39;s goal is to create nanosensors that measure protease activity in vivo by producing a cleavage signal that is detectable from host urine and discriminates disease.

Nanosensors to Detect Protease Activity In Vivo for Noninvasive Diagnostics

Proteases are multi-functional enzymes that specialize in the hydrolysis of peptide-bonds and control broad biological processes including homeostasis and ...

This method can help answer key questions in protea mix and diagnostics, such as how to design probes that can detect the progression of diseases by measuring proteates'activity in vivo. The main advantage of this method is that the diagnositics developed will be noninvasive, and can actually amplify the detection of biological signals. This method can be applied to numerous diseases, because many proteuses are actually major drivers of pathogenesis.In the chemical fume hood, transfer one ml of 30%ammonium hydroxide to a 15 ml conical tube. Place this tube into an ice bucket and let it chill for 30 minutes. Wash a 250 ml Ehrlenmeyer flask with deionized water.Then add 10 ml of double distilled water. Submerge the flask in an ice bath resting on a heat plate. Using a plastic pipette, begin the flow of nitrogen gas into the double distilled water in the flask.Bubble for 15 minutes to deoxygenate. Next, weigh out 4.5 g of dextrine in a 15 ml conical tube. Add water such that the final volume of the mixture including the dextrine is 20 ml.Vortex vigorously to dissolve the dextrine. Weigh out 78.5 mg of iron 3 chloride hexahydrate and add this to the dextrine solution. Vortex to dissolve.Using a 0.2 um filter, filter the resulting solution. After this, transfer 9 ml of the deoxygenated water to the 15 ml conical tube containing the 1 ml of chilled ammonium hydroxide. Return the conical tube to the ice bucket to chill.Weigh out 73 mg of iron 2 chloride tetrahydrate and dissolve it in the remaining 1 ml of deoxygenated double distilled water. Use a 0.2 um filter to filter the solution. Then, transfer the dextrine iron 3 solution into the 250 ml Ehrlenmeyer flask.Deoxygenate with nitrogen gas for 15 minutes on ice, while mixing at 1, 600 rpm. Cap the flask with a rubber septum. Using an 18 gauge needle, puncture the septum to flow nitrogen gas into the flask.Insert a separate 18 gauge needle, which will be the flow outlet. Next, use a 1 ml syringe to add 467 ul of the iron 2 solution to the dextrine iron 3 solution. Stir at 1, 600 rpm.Add the chilled dilute ammonium hydroxide solution dropwise to initiate the nucleation process. Make sure each drop mixes well before adding another. Stop the flow of nitrogen gas and remove the rubber septum.Remove the ice bath and replace it with a bath of warm water. Heat the solution to 75 degrees Celsius and then incubate for 75 minutes. Remove the flask from the hot plate.Doubly filter the solution through a 0.2 um filter and then a 0.1 um filter to remove any coarse particles. Using 100 kDa molecular weight cutoff concentrators, buffer exchange the particles into double distilled water to remove excess dextrine. If the flow through remains dark after two to three spins, replace the filters as they may have broken.Next, resuspend the iron oxide nanoparticles in double distilled water at a concentration of 10 mg per ml. Add 1.6 volumes of 5 molar sodium hydroxide, then add 0.65 volumes of epichlorohydrine. Using a plate shaker, rigorously mix at room temperature for 12 hours.Use a 20 ml syringe with an 18 gauge needle to transfer the iron oxide nanoparticle solution into a dialysis membrane with a 50 kDa molecular weight cutoff. Place the dialysis membrane into 4 liters of double distilled water. Incubate at room temperature overnight.After determining the concentration, bring the iron oxide nanoparticles to a concentration of 5 mg per ml. Add ammonium hydroxide to reach 20%and shake at room temperature for at least 12 hours to amenate the surface of the iron oxide nanoparticles. Then, buffer exchange using 30 kDa molecular weight cutoff filters.Use dynamic light scattering to determine the hydrodynamic radius of the iron oxide nanoparticles as outlined in the text protocol. After synthesizing a peptide substrate, aliquot 0.5 mg of iron oxide nanoparticles into the 10 kDa molecular weight cutoff spin filter tube. Buffer exchange into coupling buffer using a 10 kDa molecular weight cutoff spin filter as outlined in the text protocol.Dissolve SIA in DMF to reach a concentration of approximately 30 mg per ml. Then, add SIA to the iron oxide nanoparticles at a mole ratio of 500 to one. After incubation and buffer exchange, bring the final product to a concentration of 1 mg per ml.Mix the peptide of interest with 20 kDa thiol terminated polyethylene glycol, and then mix this peptide glycol solution with iron oxide nanoparticles. Cover the tubes in foil to prevent photo bleaching the fluorescent molecules. And incubate overnight at room temperature on a plate shaker set the to the highest speed.Next, add L cystine at a molar ratio of 500 to one to the iron oxide nanoparticles. Incubate for one hour at room temperature on a shaker set to the highest speed. After this, make an 18 ul nanoparticle solution using PVS, and a 200 nanomolar concentration of peptide.Add 2 ul of the protease of interest. Incubate in a plate reader for one hour at 37 degrees Celsius taking flourescence measurements every one to two minutes to monitor cleavage. Immediately after injecting the prepared nanosensor solution via tail vein injection, place the mice into metabolic cages, and note the time of injection for each mouse.Combine 2 ul of urine with 5 ul of prepared magnetic beads. Using PVS, bring the final total volume to 50 ul. Incubate at room temperature for 60 minutes.Next, wash twice using 50 ul of PVS each time, while using a magnetic separator to collect the magnetic beads after each wash. Elute twice with 32.5 ul of 5%glacial acetic acid. Use 35 ul of 2 molar tris to neutralize the pool dilution and achieve a final ph around 7.After this, use a plate reader at appropriate excitation and emission wavelengths to quantify the urine flourescence. Calculate the concentration of fluorescent reporter against a ladder of known concentrations of free flourophor. In this study, activity based nanosensors are developed by conjugating protease substrates to a nanoparticle core.The average diameter of iron oxide nanoparticles is observed to be between 40 and 50 nm. After pecolation, the circulation half life for this size range is seen to be approximately 6 hours. After successful peptide conjugation, spectral absorbance analysis reveals a distinct absorbance peak at the maximum excitation wavelength of the fluorescent reporter.The ability of the probe to sense protease activity is then tested by incubating an aliquot of nanosensors with recombinant proteases. It is typical to observe substrate cleavage velocities that follow Michaelis-Menten kinetics. Nanosensors coated with a near infrared fluorescent reporter are then used to visualize the pharmacokinetics in mouse models of cancer by whole animal fluorescent imaging.A fluorescent signal is seen to localize in the urine of mice, bearing LS 174 t colorectal, 60 to 90 minutes after intravenous administration of the nanosensors. Significantly lower fluorescent signals are observed in the bladders of control mice. It should be noted that the signal observed in the liver arises because particles are eventually scavenged by monocites and and macrophages in the ridiculoendophilial system, which are commonly found in the liver, spleen, and lymph nodes.Once mastered, this technique can be done in four days, if it's performed properly. While attempting this procedure, it's important to remember that flourescence is the primary readout, so it's important to keep the peptide substrates with fluorescent markers in the dark. Following this procedure, other methods like biodistribution studies and in viva imaging can be performed in order to answer additional questions, like localization of particles to various organs.After its development, this technique paved the way for researchers in the field of diagnostics to explore cancer biomarkers in mice. After watching this video, you should have a good understanding of how to synthesize and characterize iron oxide nanoparticles, use these to build nanosensors, then use the nanosensors in vivo. Don't forget that working with the chemicals involved in a nanoparticle synthesis can be extremely hazardous, and precautions such as personal protective equipment and working within a fume hood should always be taken while performing this procedure.

nanosensors-to-detect-protease-activity-vivo-for-noninvasive

Research

JoVE Journal

Bioengineering

Design of a Cyclic Pressure Bioreactor for the Ex Vivo Study of Aortic Heart Valves

The aortic valve, located between the left ventricle and the aorta, allows for unidirectional blood flow, preventing backflow into the ventricle. Aortic valve leaflets are composed of interstitial cells suspended within an extracellular matrix (ECM) and are lined with an endothelial cell monolayer. The valve withstands a harsh, dynamic environment and is constantly exposed to shear, flexion, tension, and compression. Research has shown calcific lesions in diseased valves occur in areas of high mechanical stress as a result of endothelial disruption or interstitial matrix damage1-3. Hence, it is not surprising that epidemiological studies have shown high blood pressure to be a leading risk factor in the onset of aortic valve disease4. 
The only treatment option currently available for valve disease is surgical replacement of the diseased valve with a bioprosthetic or mechanical valve5. Improved understanding of valve biology in response to physical stresses would help elucidate the mechanisms of valve pathogenesis. In turn, this could help in the development of non-invasive therapies such as pharmaceutical intervention or prevention. Several bioreactors have been previously developed to study the mechanobiology of native or engineered heart valves6-9. Pulsatile bioreactors have also been developed to study a range of tissues including cartilage10, bone11 and bladder12. The aim of this work was to develop a cyclic pressure system that could be used to elucidate the biological response of aortic valve leaflets to increased pressure loads. 
The system consisted of an acrylic chamber in which to place samples and produce cyclic pressure, viton diaphragm solenoid valves to control the timing of the pressure cycle, and a computer to control electrical devices. The pressure was monitored using a pressure transducer, and the signal was conditioned using a load cell conditioner. A LabVIEW program regulated the pressure using an analog device to pump compressed air into the system at the appropriate rate. The system mimicked the dynamic transvalvular pressure levels associated with the aortic valve; a saw tooth wave produced a gradual increase in pressure, typical of the transvalvular pressure gradient that is present across the valve during diastole, followed by a sharp pressure drop depicting valve opening in systole. The LabVIEW program allowed users to control the magnitude and frequency of cyclic pressure. The system was able to subject tissue samples to physiological and pathological pressure conditions. This device can be used to increase our understanding of how heart valves respond to changes in the local mechanical environment.

Design of a Cyclic Pressure Bioreactor for the Ex Vivo Study of Aortic Heart Valves

A cyclic pressure bioreactor capable of subjecting heart valve tissue to physiological and pathological pressure conditions has been designed. A LabVIEW program allows users to control pressure magnitude, amplitude and frequency. This device can be used to study the mechanobiology of heart valve tissue or isolated cells.

The aortic valve, located between the left ventricle and the aorta, allows for unidirectional blood flow, preventing backflow into the ventricle. Aortic ...

Quantitative FRET (F&#246;rster Resonance Energy Transfer) Analysis for SENP1 Protease Kinetics Determination

Reversible posttranslational modifications of proteins with ubiquitin or ubiquitin-like proteins (Ubls) are widely used to dynamically regulate protein activity and have diverse roles in many biological processes. For example, SUMO covalently modifies a large number or proteins with important roles in many cellular processes, including cell-cycle regulation, cell survival and death, DNA damage response, and stress response 1-5. SENP, as SUMO-specific protease, functions as an endopeptidase in the maturation of SUMO precursors or as an isopeptidase to remove SUMO from its target proteins and refresh the SUMOylation cycle 1,3,6,7.
The catalytic efficiency or specificity of an enzyme is best characterized by the ratio of the kinetic constants, kcat/KM. In several studies, the kinetic parameters of SUMO-SENP pairs have been determined by various methods, including polyacrylamide gel-based western-blot, radioactive-labeled substrate, fluorescent compound or protein labeled substrate 8-13. However, the polyacrylamide-gel-based techniques, which used the "native" proteins but are laborious and technically demanding, that do not readily lend themselves to detailed quantitative analysis. The obtained kcat/KM from studies using tetrapeptides or proteins with an ACC (7-amino-4-carbamoylmetylcoumarin) or AMC (7-amino-4-methylcoumarin) fluorophore were either up to two orders of magnitude lower than the natural substrates or cannot clearly differentiate the iso- and endopeptidase activities of SENPs.
Recently, FRET-based protease assays were used to study the deubiquitinating enzymes (DUBs) or SENPs with the FRET pair of cyan fluorescent protein (CFP) and yellow fluorescent protein (YFP) 9,10,14,15. The ratio of acceptor emission to donor emission was used as the quantitative parameter for FRET signal monitor for protease activity determination. However, this method ignored signal cross-contaminations at the acceptor and donor emission wavelengths by acceptor and donor self-fluorescence and thus was not accurate.
We developed a novel highly sensitive and quantitative FRET-based protease assay for determining the kinetic parameters of pre-SUMO1 maturation by SENP1. An engineered FRET pair CyPet and YPet with significantly improved FRET efficiency and fluorescence quantum yield, were used to generate the CyPet-(pre-SUMO1)-YPet substrate 16. We differentiated and quantified absolute fluorescence signals contributed by the donor and acceptor and FRET at the acceptor and emission wavelengths, respectively. The value of kcat/KM was obtained as (3.2 &plusmn; 0.55) x107 M-1s-1 of SENP1 toward pre-SUMO1, which is in agreement with general enzymatic kinetic parameters. Therefore, this methodology is valid and can be used as a general approach to characterize other proteases as well.

Quantitative FRET F&amp;#246;rster Resonance Energy Transfer Analysis for SENP1 Protease Kinetics Determination

A novel method involving quantitative analysis of FRET (F&ouml;rster Resonance Energy Transfer) signals is described for studying enzyme kinetics. KM and kcat were obtained for the hydrolysis of the catalytic domain of SENP1 (SUMO/Sentrin specific protease 1) to pre-SUMO1 (Small Ubiquitin-like MOdifier). The general principles of this quantitative-FRET-based protease kinetic study can be applied to other proteases.

Reversible posttranslational modifications of proteins with ubiquitin or ubiquitin-like proteins (Ubls) are widely used to dynamically regulate protein ...

FIBS-enabled Noninvasive Metabolic Profiling

In the era of computational biology, new high throughput experimental systems are necessary in order to populate and refine models so that they can be validated for predictive purposes. Ideally such systems would be low volume, which precludes sampling and destructive analyses when time course data are to be obtained. What is needed is an in situ monitoring tool which can report the necessary information in real-time and noninvasively. An interesting option is the use of fluorescent, protein-based in vivo biological sensors as reporters of intracellular concentrations. One particular class of in vivo biosensors that has found applications in metabolite quantification is based on F&#246;rster Resonance Energy Transfer (FRET) between two fluorescent proteins connected by a ligand binding domain. FRET integrated biological sensors (FIBS) are constitutively produced within the cell line, they have fast response times and their spectral characteristics change based on the concentration of metabolite within the cell. In this paper, the method for constructing Chinese hamster ovary (CHO) cell lines that constitutively express a FIBS for glucose and glutamine and calibrating the FIBS in vivo in batch cell culture in order to enable future quantification of intracellular metabolite concentration is described. Data from fed-batch CHO cell cultures demonstrates that the FIBS was able in each case to detect the resulting change in the intracellular concentration. Using the fluorescent signal from the FIBS and the previously constructed calibration curve, the intracellular concentration was accurately determined as confirmed by an independent enzymatic assay.

A description of how to calibrate F&#246;rster Resonance Energy Transfer integrated biological sensors (FIBS) for in situ metabolic profiling is presented.&#160;The FIBS can be used to measure intracellular levels of metabolites noninvasively aiding in the development of metabolic models and high throughput screening of bioprocess conditions.

In the era of computational biology, new high throughput experimental systems are necessary in order to populate and refine models so that they can be ...

A Full Skin Defect Model to Evaluate Vascularization of Biomaterials In Vivo

Insufficient vascularization is considered to be one of the main factors limiting the clinical success of tissue-engineered constructs. In order to evaluate new strategies that aim at improving vascularization, reliable methods are required to make the in-growth of new blood vessels into bio-artificial scaffolds visible and quantify the results. Over the past couple of years, our group has introduced a full skin defect model that enables the direct visualization of blood vessels by transillumination and provides the possibility of quantification through digital segmentation. In this model, one surgically creates full skin defects in the back of mice and replaces them with the material tested. Molecules or cells of interest can also be incorporated in such materials to study their potential effect. After an observation time of one&#8217;s own choice, materials are explanted for evaluation. Bilateral wounds provide the possibility of making internal comparisons that minimize artifacts among individuals as well as of decreasing the number of animals needed for the study. In comparison to other approaches, our method offers a simple, reliable and cost effective analysis. We have implemented this model as a routine tool to perform high-resolution screening when testing vascularization of different biomaterials and bio-activation approaches.

A Full Skin Defect Model to Evaluate Vascularization of Biomaterials In Vivo

Vascularization is key to approaches in successful tissue engineering. Therefore, reliable technologies are required to evaluate the development of vascular networks in tissue-constructs. Here we present a simple and cost-effective method to visualize and quantify vascularization in vivo.

Insufficient vascularization is considered to be one of the main factors limiting the clinical success of tissue-engineered constructs. In order to ...

Magnetic Levitation Coupled with Portable Imaging and Analysis for Disease Diagnostics

Currently, many clinical diagnostic procedures are complex, costly, inefficient, and inaccessible to a large population in the world. The requirements for specialized equipment and trained personnel require that many diagnostic tests be performed at remote, centralized clinical laboratories. Magnetic levitation is a simple yet powerful technique and can be applied to levitate cells, which are suspended in a paramagnetic solution and placed in a magnetic field, at a position determined by equilibrium between a magnetic force and a buoyancy force. Here, we present a versatile platform technology designed for point-of-care diagnostics which uses magnetic levitation coupled to microscopic imaging and automated analysis to determine the density distribution of a patient's cells as a useful diagnostic indicator. We present two platforms operating on this principle: (i) a smartphone-compatible version of the technology, where the built-in smartphone camera is used to image cells in the magnetic field and a smartphone application processes the images and to measures the density distribution of the cells and (ii) a self-contained version where a camera board is used to capture images and an embedded processing unit with attached thin-film-transistor (TFT) screen measures and displays the results. Demonstrated applications include: (i) measuring the altered distribution of a cell population with a disease phenotype compared to a healthy phenotype, which is applied to sickle cell disease diagnosis, and (ii) separation of different cell types based on their characteristic densities, which is applied to separate white blood cells from red blood cells for white blood cell cytometry. These applications, as well as future extensions of the essential density-based measurements enabled by this portable, user-friendly platform technology, will significantly enhance disease diagnostic capabilities at the point of care.

We present a magnetic levitation technique coupled with automated imaging and analysis in both a smartphone-compatible device and a device with embedded imaging and processing. This is applied to measure the density distribution of cells with two demonstrated biomedical applications: sickle cell disease diagnosis and separating white and red blood cells.

Currently, many clinical diagnostic procedures are complex, costly, inefficient, and inaccessible to a large population in the world. The requirements for ...

Development of an Electrochemical DNA Biosensor to Detect a Foodborne Pathogen

Vibrio parahaemolyticus (V. parahaemolyticus) is a common foodborne pathogen that contributes to a large proportion of public health problems globally, significantly affecting the rate of human mortality and morbidity. Conventional methods for the detection of V. parahaemolyticus such as culture-based methods, immunological assays, and molecular-based methods require complicated sample handling and are time-consuming, tedious, and costly. Recently, biosensors have proven to be a promising and comprehensive detection method with the advantages of fast detection, cost-effectiveness, and practicality. This research focuses on developing a rapid method of detecting V. parahaemolyticus with high selectivity and sensitivity using the principles of DNA hybridization. In the work, characterization of synthesized polylactic acid-stabilized gold nanoparticles (PLA-AuNPs) was achieved using X-ray Diffraction (XRD), Ultraviolet-visible Spectroscopy (UV-Vis), Transmission Electron Microscopy (TEM), Field-emission Scanning Electron Microscopy (FESEM), and Cyclic Voltammetry (CV). We also carried out further testing of stability, sensitivity, and reproducibility of the PLA-AuNPs. We found that the PLA-AuNPs formed a sound structure of stabilized nanoparticles in aqueous solution. We also observed that the sensitivity improved as a result of the smaller charge transfer resistance (Rct) value and an increase of active surface area (0.41 cm2). The development of our DNA biosensor was based on modification of a screen-printed carbon electrode (SPCE) with PLA-AuNPs and using methylene blue (MB) as the redox indicator. We assessed the immobilization and hybridization events by differential pulse voltammetry (DPV). We found that complementary, non-complementary, and mismatched oligonucleotides were specifically distinguished by the fabricated biosensor. It also showed reliably sensitive detection in cross-reactivity studies against various food-borne pathogens and in the identification of V. parahaemolyticus in fresh cockles.

A protocol for the development of an electrochemical DNA biosensor comprising a polylactic acid-stabilized, gold nanoparticles-modified, screen-printed carbon electrode to detect Vibrio parahaemolyticus is presented.

Vibrio parahaemolyticus (V. parahaemolyticus) is a common foodborne pathogen that contributes to a large proportion of public health problems globally, ...

Calorespirometry: A Powerful, Noninvasive Approach to Investigate Cellular Energy Metabolism

Many cell lines used in basic biological and biomedical research maintain energy homeostasis through a combination of both aerobic and anaerobic respiration. However, the extent to which both pathways contribute to the landscape of cellular energy production is consistently overlooked. Transformed cells cultured in saturating levels of glucose often show a decreased dependency on oxidative phosphorylation for ATP production, which is compensated by an increase in substrate-level phosphorylation. This shift in metabolic poise allows cells to proliferate despite the presence of mitochondrial toxins. In neglecting the altered metabolic poise of transformed cells, results from a pharmaceutical screening may be misinterpreted since the potentially mitotoxic effects may not be detected using model cell lines cultured in the presence of high glucose concentrations. This protocol describes the pairing of two powerful techniques, respirometry and calorimetry, which allows for the quantitative and noninvasive assessment of both aerobic and anaerobic contributions to cellular ATP production. Both aerobic and anaerobic respirations generate heat, which can be monitored via calorimetry. Meanwhile, measuring the rate of oxygen consumption can assess the extent of aerobic respiration. When both heat dissipation and oxygen consumption are measured simultaneously, the calorespirometric ratio can be determined. The experimentally obtained value can then be compared to the theoretical oxycaloric equivalent and the extent of the anaerobic respiration can be judged. Thus, calorespirometry provides a unique method to analyze a wide range of biological questions, including drug development, microbial growth, and fundamental bioenergetics under both normoxic and hypoxic conditions.

This protocol describes calorespirometry, the direct and simultaneous measurement of both heat dissipation and respiration, which provides a noninvasive approach to assess energy metabolism. This technique is used to assess the contribution of both aerobic and anaerobic pathways to energy utilization by monitoring the total cellular energy flow.

Many cell lines used in basic biological and biomedical research maintain energy homeostasis through a combination of both aerobic and anaerobic ...

Rigid Embedding of Fixed and Stained, Whole, Millimeter-Scale Specimens for Section-free 3D Histology by Micro-Computed Tomography

For over a hundred years, the histological study of tissues has been the gold standard for medical diagnosis because histology allows all cell types in every tissue to be identified and characterized. Our laboratory is actively working to make technological advances in X-ray micro-computed tomography (micro-CT) that will bring the diagnostic power of histology to the study of full tissue volumes at cellular resolution (i.e., an X-ray Histo-tomography modality). Toward this end, we have made targeted improvements to the sample preparation pipeline. One key optimization, and the focus of the present work, is a straightforward method for rigid embedding of fixed and stained millimeter-scale samples. Many of the published methods for sample immobilization and correlative micro-CT imaging rely on placing the samples in paraffin wax, agarose, or liquids such as alcohol. Our approach extends this work with custom procedures and the design of a 3-dimensional printable apparatus to embed the samples in an acrylic resin directly into polyimide tubing, which is relatively transparent to X-rays. Herein, sample preparation procedures are described for the samples from 0.5 to 10 mm in diameter, which would be suitable for whole zebrafish larvae and juveniles, or other animals and tissue samples of similar dimensions. As proof of concept, we have embedded the specimens from Danio, Drosophila, Daphnia, and a mouse embryo; representative images from 3-dimensional scans for three of these samples are shown. Importantly, our methodology leads to multiple benefits including rigid immobilization, long-term preservation of laboriously-created resources, and the ability to re-interrogate samples.

We developed protocols and designed a custom apparatus to enable embedding of millimeter-scale specimens. We present sample preparation procedures with an emphasis on embedding in acrylic resin and polyimide tubing to achieve rigid immobilization and long-term storage of specimens for the interrogation of tissue architecture and cell morphology by micro-CT.

For over a hundred years, the histological study of tissues has been the gold standard for medical diagnosis because histology allows all cell types in ...

Methylation Specific Multiplex Droplet PCR using Polymer Droplet Generator Device for Hematological Diagnostics

A multiplexed droplet PCR (mdPCR) workflow and detailed protocol for determining epigenetic-based white blood cell (WBC) differential count is described, along with a thermoplastic elastomer (TPE) microfluidic droplet generation device. Epigenetic markers are used for WBC&#160;subtyping which is of important prognostic value in different diseases. This is achieved through the quantification of DNA methylation patterns of specific CG-rich regions in the genome (CpG loci). In this paper, bisulfite-treated DNA from peripheral blood mononuclear cells (PBMCs) is encapsulated in droplets with mdPCR reagents including primers and hydrolysis fluorescent probes specific for CpG loci that correlate with WBC sub-populations. The multiplex approach allows for the interrogation of many CpG loci without the need for separate mdPCR reactions, enabling more accurate parametric determination of WBC sub-populations using epigenetic analysis of methylation sites. This precise quantification can be extended to different applications and highlights the benefits for clinical diagnosis and subsequent prognosis.

Epigenetic markers are used for white blood cell (WBC) subtyping through the quantification of DNA methylation patterns. This protocol presents a multiplex droplet polymerase chain reaction (mdPCR) method using a thermoplastic elastomer (TPE)-based microfluidic device for droplet generation allowing for precise and multiplex methylation-specific target quantification of WBC differential counts.

A multiplexed droplet PCR (mdPCR) workflow and detailed protocol for determining epigenetic-based white blood cell (WBC) differential count is described, ...

Developing 3D Organized Human Cardiac Tissue within a Microfluidic Platform

The leading cause of death worldwide persists as cardiovascular disease (CVD). However, modeling the physiological and biological complexity of the heart muscle, the myocardium, is notoriously difficult to accomplish in vitro. Mainly, obstacles lie in the need for human cardiomyocytes (CMs) that are either adult or exhibit adult-like phenotypes and can successfully replicate the myocardium&#39;s cellular complexity and intricate 3D architecture. Unfortunately, due to ethical concerns and lack of available primary patient-derived human cardiac tissue, combined with the minimal proliferation of CMs, the sourcing of viable human CMs has been a limiting step for cardiac tissue engineering. To this end, most research has transitioned toward cardiac differentiation of human induced pluripotent stem cells (hiPSCs) as the primary source of human CMs, resulting in the wide incorporation of hiPSC-CMs within in vitro assays for cardiac tissue modeling.
Here in this work, we demonstrate a protocol for developing a 3D mature stem cell-derived human cardiac tissue within a microfluidic device. We specifically explain and visually demonstrate the production of a 3D in vitro anisotropic cardiac tissue-on-a-chip model from hiPSC-derived CMs. We primarily describe a purification protocol to select for CMs, the co-culture of cells with a defined ratio via mixing CMs with human CFs (hCFs), and suspension of this co-culture within the collagen-based hydrogel. We further demonstrate the injection of the cell-laden hydrogel within our well-defined microfluidic device, embedded with staggered elliptical microposts that serve as surface topography to induce a high degree of alignment of the surrounding cells and the hydrogel matrix, mimicking the architecture of the native myocardium. We envision that the proposed 3D anisotropic cardiac tissue-on-chip model is suitable for fundamental biology studies, disease modeling, and, through its use as a screening tool, pharmaceutical testing.

The goal of this protocol is to explain and demonstrate the development of a three-dimensional (3D) microfluidic model of highly aligned human cardiac tissue, composed of stem cell-derived cardiomyocytes co-cultured with cardiac fibroblasts (CFs) within a biomimetic, collagen-based hydrogel, for applications in cardiac tissue engineering, drug screening, and disease modeling.

The leading cause of death worldwide persists as cardiovascular disease (CVD). However, modeling the physiological and biological complexity of the heart ...