eoe sub articles

EoE Sub Articles

Flow System Architecture
1. Flow chamber construction
<ol>
	<li>Using the provided Solid Works file, 3D print the flow tank using ABS thermoplastic or PLA plastic. Dimensions are provided below if SolidWorks is unavailable.&#160;Figure 1A&#160;shows a representation of this model. The body of the flow tank is 2.5 cm x 1.5 cm x 7.5 cm. The far ends of the flow tank include holes approximately 5 mm in diameter to allow for the entry of tubing containing the capillary tube. 
	NOTE: The flow tank has a 1 cm hole, perpendicular to the orientation of the capillary tube, for placement of the ultrasound transducer. A cylindrical extrusion with the same inner diameter as the hole extends 6 mm into the tank. For real-time imaging, the flow tank has a 1 mm x 3 mm slot directly below the capillary tube.</li>
	<li>After printing the 3D flow tank, clean and assemble the system for use.</li>
	<li>Place glass coverslips over the 1 mm x 3 mm slot and the 1 cm hole in the flow system.</li>
	<li>Carefully seal with silicone to prevent leakage.</li>
	<li>Fit the capillary tube into the silicone cured tubes. Insert the tubes into the flow chamber through the side of the flow tank such that the glass capillary tube is directly above and in front of the 3 mm slot and the 1 cm hole.</li>
	<li>Seal the tubing using silicone to prevent leakage.</li>
</ol>

2. Photoacoustic flow system setup
NOTE:&#160;Figure 1B&#160;and&#160;Figure 1C&#160;show an example of the flow system architecture.
<ol>
	<li>Connect the transducer to an ultrasound pulser/receiver. Amplify the signal with a 59 dB gain.</li>
	<li>Connect the output of the filter to a multipurpose reconfigurable oscilloscope equipped with a built-in field-programmable gate array.</li>
	<li>Connect one of the tubes coming from the flow chamber to a T-junction, connected to two syringe pumps at each branch.</li>
	<li>Fill one of the syringe pumps with air and the other pump with the sample to be analyzed. Set the pump containing air to a flow rate of 40 &#181;L/min and the pump having the sample to a flow rate of 20 &#181;L/min. The resulting two-phase flow will produce sample volumes of 1 &#181;L. At this flow rate, the system will test approximately 6.4 samples per minute. 
	NOTE: To maintain a consistent distribution of cells, lightly vortex each sample immediately before being tested. In addition, rotate the syringe every few minutes to prevent the cells from settling in the solution.</li>
	<li>Connect the remaining tube exiting the flow system to a container with 10% bleach, to dispose of cells after they exit the flow system. 
	NOTE: Before utilizing the flow system, check for leaks, as these can affect the flow. Cells must be contained within a closed system to maintain biological safety during the procedure.</li>
	<li>The design of the 3D printed tank allows for consistent and repeatable alignment between the transducer and laser light with minimal calibration. When placed correctly within the custom tank, the quartz capillary tube ensures that the transducer and laser are directly aligned.</li>
	<li>Place the section of the quartz capillary tube in direct alignment with the transducer, in the field of view of the microscope, allowing for careful placement of the optical fiber above the sample such that it illuminates the entire width of the tube.</li>
	<li>Irradiate the sample using an optical fiber channeling a diode-pumped solid-state laser operating at a wavelength of 1,053 nm. The laser light incident on the sample and the transducer used to measure the photoacoustic effect are both unfocused.</li>
	<li>The energy of the laser incident on the sample is approximately 8 mJ and the 10 Hz laser rate is sufficient to illuminate each sample multiple times as it passes through the system.</li>
	<li>Place the flow system on top of an inverted microscope and ensure both the laser pulse and the path of the sample are visible as the sample passes through the flow system. Record flow using a microscope-mounted camera.</li>
	<li>Record the ultrasound acquisitions utilizing data acquisition software. Trigger ultrasound and pulsed laser using the FPGA. Utilize PBS with 2% Tween, and FA-CuS NPs at a concentration of 100 &#181;g/mL in PBS 2% Tween, as negative and positive controls, respectively.</li>
	<li>Utilizing a microscope-mounted camera, record both the firing of the laser and the passage of samples through the flow system. These recordings will be utilized to correlate the acoustic signal recorded by the transducer with the firing of the laser. As the samples pass in front of the firing of the laser, the signal can then be correlated to the resulting photoacoustic signal for analysis. At a sampling rate of 10 Hz, the laser will illuminate each plug several times.</li>
</ol>

<table><tbody><tr><td>3D Printed Tank</td><td></td><td>Custom-made</td><td></td></tr><tr><td>Acquisition Card</td><td>National Instruments</td><td>PXIe-5170R</td><td>250 MS/s, 8-Channel, 14-bit</td></tr><tr><td>Alconox</td><td>Sigma-Aldrich</td><td>242985-1.8KG</td><td>Detergent used for cleaning glassware.</td></tr><tr><td>Amicon Ultra-15 Centrifugal Filters</td><td>Millipore</td><td>UFC903024</td><td></td></tr><tr><td>Amicon Ultra-4 Centrifugal Filters</td><td>Millipore</td><td>UFC803024</td><td></td></tr><tr><td>Data Acquisition software</td><td>National Instruments</td><td>NI LabVIEW 2017 (32-bit)</td><td>LabVIEW used to synchronize laser pulses with data acquisition.</td></tr><tr><td>Data Processing Software</td><td>Mathworks</td><td>Matlab R2016a</td><td>Reconstructions and graphs produced using Matlab software.</td></tr><tr><td>FBS</td><td>Sigma-Aldrich</td><td>F2442-500ML</td><td></td></tr><tr><td>Pulsed Laser</td><td>RPMC Lasers Inc</td><td>Quantus-Q1D-1053</td><td>Pulsed laser source with specifications 1053 nm, 8 ns pulse, 10 Hz maximum.</td></tr><tr><td>Pulser/Receiver</td><td>Olympus</td><td>5077PR</td><td>Receives, filters, and amplifies photoacoustic signals. Operated with 59 dB Gain.</td></tr><tr><td>Quartz Capillary Tube</td><td>Sutter Instrument</td><td>QF150-75-10</td><td></td></tr><tr><td>Syringe Pumps</td><td>New Era Pump Systems Inc</td><td>DUAL-1000</td><td></td></tr><tr><td>Coupling Stage</td><td>Newport</td><td>F-91-C1-T&amp;nbsp;</td><td>Stage for coupling pulsed light to objective. Holds FP-1A and LMH-10x-532</td></tr><tr><td>Coupling Objective</td><td>Thorlabs&amp;nbsp;</td><td>LMH-10x-532</td><td>To couple pulsed light to optical fiber.</td></tr><tr><td>Norm-Ject 10 mL Syringes</td><td>HENKE SASS WOLF</td><td>4100-X00V0</td><td></td></tr><tr><td>Transducer</td><td>Olynmpus</td><td>V214-BB-RM</td><td>Ultrasound detector with central frequency of 50 MHz and -6 dB fractional bandwidth of 82%.</td></tr><tr><td>Trypan Blue Solution 0.4%</td><td>Amresco</td><td>K940-100ML</td><td></td></tr><tr><td>Optical Fiber&amp;nbsp;</td><td>Thorlabs&amp;nbsp;</td><td>FG550LEC</td><td>Used to expose sample to pulsed light.</td></tr><tr><td>Tween 20</td><td>Sigma-Aldrich</td><td>P7949-100ML</td><td></td></tr></tbody></table>

in vitro photoacoustic flow cytometry: a non-invasive flow photoacoustic technique to detect nanoparticle-bearing circulating ovarian cancer cells

Source: Joel F. Lusk et al. <a href="https://www.jove.com/t/60279">Ovarian Cancer Detection Using Photoacoustic Flow Cytometry.</a> J. Vis. Exp. (2020)
In this video, we present a photoacoustic flow cytometric detection of ovarian cancer cells bearing nanoparticles in a circulating in vitro flow chamber. This non-invasive technique successfully identifies circulating tumor cells in a flow system utilizing a contrast agent.

<img alt="Figure 1" class="xfigimg" src="/files/ftp_upload/20369/20369_Figure1.jpg" /> 
Figure 1. Representative images of photoacoustic flow cytometry system and flow chamber.&#160;(A) Detailed view of the 3D printed flow chamber. (B) Diagram of PAFC system. (C) Flow system architecture: SP = syringe pump; DAQ/FPGA = data acquisition/field programmable gate array; Ob = objective len...

In Vitro Photoacoustic Flow Cytometry: A Non-invasive Flow Photoacoustic Technique to Detect Nanoparticle-bearing Circulating Ovarian Cancer Cells

Source: Joel F. Lusk et al. Ovarian Cancer Detection Using Photoacoustic Flow Cytometry. J. Vis. Exp. (2020)
In this video, we present a photoacoustic ...

Photoacoustic flow cytometry, or PAFC, utilizes the ability of biological samples to absorb laser light of a specific wavelength and emit acoustic sound waves. Begin by taking a suspension of the desired nanoparticle-bearing ovarian cancer cells in one syringe and air in a second syringe. Load the two syringes onto two separate syringe pumps set to their respective flow rates. The pumps deliver their contents through flexible tubes that merge to administer small volumes of sample trapped between alternating air bubbles to a pre-assembled flow chamber.
As the sample passes through the flow chamber, irradiate the cells using a short-pulsed laser of an appropriate wavelength. Localized absorption of laser energy by the nanoparticles within the cancer cells generates heat, causing thermoelastic expansion that produces acoustic sound waves. A pre-assembled transducer detects the acoustic signals and transmits them to a receiver. The receiver amplifies the signals and relays them to an oscilloscope for data acquisition. The oscilloscope processes the data and transfers them to a computer that displays information relating to the detected cancer cells.

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Research

JoVE Encyclopedia of Experiments

Cancer Research

Gynecologic Cancer

Assays & techniques

1.1K Views. Source: Joel F. Lusk et al. Ovarian Cancer Detection Using Photoacoustic Flow Cytometry. J. Vis. Exp. (2020) In this video, we present a photoacoustic flow cytometric detection of ovarian cancer cells bearing nanoparticles in a circulating in vitro flow chamber. This non-invasive technique successfully identifies circulating tumor cells in a flow system utilizing a contrast agent. 

Video: In Vitro Photoacoustic Flow Cytometry: A Non-invasive Flow Photoacoustic Technique to Detect Nanoparticle-bearing Circulating Ovarian Cancer Cells - Concept

Non-invasive Parenchymal, Vascular and Metabolic High-frequency Ultrasound and Photoacoustic Rat Deep Brain Imaging

Photoacoustics and high frequency ultrasound stands out as powerful tools for neurobiological applications enabling high-resolution imaging on the central nervous system of small animals. However, transdermal and transcranial neuroimaging is frequently affected by low sensitivity, image aberrations and loss of space resolution, requiring scalp or even skull removal before imaging. To overcome this challenge, a new protocol is presented to gain significant insights in brain hemodynamics by photoacoustic and high-frequency ultrasounds imaging with the animal skin and skull intact. The procedure relies on the passage of ultrasound (US) waves and laser directly through the fissures that are naturally present on the animal cranium. By juxtaposing the imaging transducer device exactly in correspondence to these selected areas where the skull has a reduced thickness or is totally absent, one can acquire high quality deep images and explore internal brain regions that are usually difficult to anatomically or functionally describe without an invasive approach. By applying this experimental procedure, significant data can be collected in both sonic and optoacoustic modalities, enabling to image the parenchymal and the vascular anatomy far below the head surface. Deep brain features such as parenchymal convolutions and fissures separating the lobes were clearly visible. Moreover, the configuration of large and small blood vessels was imaged at several millimeters of depth, and precise information were collected about blood fluxes, vascular stream velocities and the hemoglobin chemical state. This repertoire of data could be crucial in several research contests, ranging from brain vascular disease studies to experimental techniques involving the systemic administration of exogenous chemicals or other objects endowed with imaging contrast enhancement properties. In conclusion, thanks to the presented protocol, the US and PA techniques become an attractive noninvasive performance-competitive means for cortical and internal brain imaging, retaining a significant potential in many neurologic fields.

The present work describes a new protocol to perform non-invasive high-frequency ultrasound and photoacoustic based imaging on rat brain, to efficiently visualize deep subcortical regions and their vascular patterns by directing signals on skull foramina naturally present on animal cranium.

Photoacoustics and high frequency ultrasound stands out as powerful tools for neurobiological applications enabling high-resolution imaging on the central ...

JoVE Journal

Neuroscience

Switchable Acoustic and Optical Resolution Photoacoustic Microscopy for In Vivo Small-animal Blood Vasculature Imaging

Photoacoustic microscopy (PAM) is a fast-growing invivo imaging modality that combines both optics and ultrasound, providing penetration beyond the optical mean free path (~1 mm in skin) with high resolution. By combining optical absorption contrast with the high spatial resolution of ultrasound in a single modality, this technique can penetrate deep tissues. Photoacoustic microscopy systems can have either a low acoustic resolution and probe deeply or a high optical resolution and probe shallowly. It is challenging to achieve high spatial resolution and large depth penetration with a single system. This work presents an AR-OR-PAM system capable of both high-resolution imaging at shallow depths and low-resolution deep-tissue imaging of the same sample in vivo. A lateral resolution of 4 &#181;m with 1.4 mm imaging depth using optical focusing and a lateral resolution of 45 &#181;m with 7.8 mm imaging depth using acoustic focusing were successfully demonstrated using the combined system. Here,&#160;in vivo&#160;small-animal blood vasculature imaging is performed to demonstrate its biological imaging capability.

Switchable Acoustic and Optical Resolution Photoacoustic Microscopy for In Vivo Small-animal Blood Vasculature Imaging

Here a switchable acoustic resolution (AR) and optical resolution (OR) photoacoustic microscopy (AR-OR-PAM) system capable of both high resolution imaging at shallow depth and low resolution deep tissue imaging on the same sample in vivo is demonstrated.

Photoacoustic microscopy (PAM) is a fast-growing invivo imaging modality that combines both optics and ultrasound, providing penetration beyond the ...

Bioengineering

Differentiation of Monocytes into Phenotypically Distinct Macrophages After Treatment with Human Cord Blood Stem Cell (CB-SC)-Derived Exosomes

Stem Cell Educator (SCE) therapy is a novel clinical approach for the treatment of type 1 diabetes and other autoimmune diseases. SCE therapy circulates the isolated patient&#8217;s blood mononuclear cells (e.g., lymphocytes and monocytes) through an apheresis machine, co-cultures the patient&#8217;s blood mononuclear cells with adherent cord blood-derived stem cells (CB-SC) in the SCE device, and then returns these &#8220;educated&#8221; immune cells to the patient&#8217;s blood. Exosomes are nano-sized extracellular vesicles between 30&#8210;150 nm existing in all biofluid and cell culture media. To further explore molecular mechanisms underlying SCE therapy and determine the actions of exosomes released from CB-SC, we investigate which cells phagocytize these exosomes during the treatment with CB-SC. By co-culturing Dio-labeled CB-SC-derived exosomes with human peripheral blood mononuclear cells (PBMC), we found that CB-SC-derived exosomes were predominantly taken up by human CD14-positive monocytes, leading to the differentiation of monocytes into type 2 macrophages (M2), with spindle-like morphology and expression of M2-associated surface molecular markers. Here, we present a protocol for the isolation and characterization of CB-SC-derived exosomes and the protocol for the co-culture of CB-SC-derived exosomes with human monocytes and the monitoring of M2 differentiation.

Differentiation of Monocytes into Phenotypically Distinct Macrophages After Treatment with Human Cord Blood Stem Cell CB-SC-Derived Exosomes

Exosome application is an emerging tool for drug development and regenerative medicine. We establish an exosome isolation protocol with high purity to isolate exosomes from novel identified stem cells called CB-SC for mechanistic studies. We also coculture CB-SC-derived exosomes with human monocytes, leading to their differentiation into phenotypically distinct macrophages.

Stem Cell Educator (SCE) therapy is a novel clinical approach for the treatment of type 1 diabetes and other autoimmune diseases. SCE therapy circulates ...

In Vitro Photoacoustic Flow Cytometry: A Non-invasive Flow Photoacoustic Technique to Detect Nanoparticle-bearing Circulating Ovarian Cancer Cells

Transcript

In Vitro Photoacoustic Flow Cytometry: A Non-invasive Flow Photoacoustic Technique to Detect Nanoparticle-bearing Circulating Ovarian Cancer Cells

Non-invasive Parenchymal, Vascular and Metabolic High-frequency Ultrasound and Photoacoustic Rat Deep Brain Imaging

Switchable Acoustic and Optical Resolution Photoacoustic Microscopy for In Vivo Small-animal Blood Vasculature Imaging

Differentiation of Monocytes into Phenotypically Distinct Macrophages After Treatment with Human Cord Blood Stem Cell (CB-SC)-Derived Exosomes