Name: 视频: 将微气泡注射到离体小鼠胚胎中:一种将微泡造影剂输送到活小鼠胚胎的脉管系统的技术 - 概念
Uploaded: 2023-04-30T14:49:57.000+00:00
Duration: 1 min 54 s
Description: 2.1K 次观看. 来源:Denbeigh， J. M. et al.对比成像。J. Vis. Exp.（2015 年） 该视频演示了将微泡造影剂注射到分离的妊娠晚期小鼠胚胎中的程序。基于微泡造影剂的超声成像有助于可视化和表征胚胎的血管环境。

eoe sub articles

EoE Sub Articles

All procedures involving animal models have been reviewed by the local institutional animal care committee and the JoVE veterinary review board.
1. Microbubble Preparation
<ol>
	<li>Preparing microbubbles for injection 
	NOTE: The assistant performs this step when &#8216;Injection of Microbubbles (MB) into Embryos&#8217; is commenced. Each embryo is injected once, with the type of microbubble chosen for each injection to be randomly selected by the assistant such that all types of microbubbles are evenly distributed throughout the procedure but given in a random order. Ensure the surgeon is blind to the type of bubble being injected.
	<ol>
		<li>Determine the volume of stock bubble solution required to produce a final concentration of 1 x 108&#160;MB/mL in a volume of 400 &#181;L (calculate the volume using the stock concentrations). Aliquot the corresponding volume of saline into an empty microcentrifuge tube.</li>
		<li>Gently agitate the selected microbubble vial and draw an excess volume (~50 &#181;L greater than that calculated above) of the solution into a 1 mL syringe using the 21 G needle. Inject the microbubbles into an empty microcentrifuge tube.</li>
		<li>Pipette the necessary volume of microbubble stock solution and add to the aliquot of saline. Mix by stirring gently with the tip of the pipette.</li>
		<li>Draw the diluted microbubble solution into a clean syringe using the 21 G needle. Removing the needle, eliminate any air bubbles from the syringe and attach the luer and tubing. Slowly push the solution to the end of the tubing making sure not to generate any air bubbles.</li>
		<li>Insert the syringe into a syringe infusion pump set to dispense the microbubbles at a rate of 20 &#181;L/min for a total volume of 20 &#181;L. Attach a pulled glass needle to the end of the tubing. Move the pump close to the injection stage.</li>
	</ol>
	</li>
</ol>
2. Injection of Microbubbles into Embryos
<ol>
	<li>Randomly select and remove (with perforated spoon) one embryo from the chilled media dish. Place in dissection dish located on the ultrasound stage under the stereoscope and remove the yolk sac and amniotic membranes with the fine forceps, cutting/tearing from the side that appears least vascularized (the antimesometrial side). This is most easily achieved by piercing an area adjacent to the head region.
	<ol>
		<li>Cut enough to remove the embryo from within, but no more. Stabilize the dissection dishes using small pieces of plasticine.</li>
	</ol>
	</li>
	<li>Gently maneuver the sac from around the embryo. Position the embryo on its side, with the placenta and umbilical vessels in front. Using the insect pins, pin down the yolk sac (4 pins recommended) and edges of the placenta as necessary to affix in place. Avoid major vessels.</li>
	<li>Wash the embryo with pre-warmed 45&#176;C PBS until the embryo revives. Identify the umbilical vein and its associated vascular network. Position the dish so that injection can be done comfortably.&#160;&#160;&#160;&#160;&#160; 
	NOTE: Once warmed, blood in the embryo will begin to flow, visibly pumping in the umbilical artery. When flow first begins, the veins will be a bright red, with the blood in both vessels quickly appearing identical. The branches arising from the umbilical vein usually overlay those from the umbilical artery on the placental surface.</li>
	<li>Once the embryo has revived, cover it (but not the placenta) with pre-warmed US gel, being sure to delicately remove any air bubbles (using the fine forceps) from around the embryo. Top up the dish with pre-warmed PBS.&#160;&#160;&#160;&#160;&#160;&#160;&#160;&#160;&#160; 
	NOTE: Keep an eye on the level of solution in the PBS and gel syringes and add backup syringes to the heating beaker as needed.</li>
	<li>Mount the glass needle on a large ball of plasticine at the edge of the dissection dish and insert the needle end into the PBS. Choosing a vein on the chorionic surface of the placental disc, as far from the main branch as reasonable, trim the tip to size using scissors. Injection is easiest if the tip is cut at a slight angle. Remove any jagged edges of the glass using the edge of the spring scissors.</li>
	<li>Using the syringe pump, slowly inject the microbubble solution at 20 &#181;L/min into the glass needle until all of the air is expelled from the needle tip and microbubbles can be seen to flow freely into the PBS. Stop the pump and reset for an injection volume of 20 &#181;L. Do not allow air to enter the embryo&#8217;s vascular system during injection.</li>
	<li>Insert the glass needle tip gently into one of the veins in the placenta and ensure it is immobile. Swing away the stereoscope head and position the transducer above the embryo. Initiate imaging.</li>
</ol>

<table><tbody><tr><td>Ice</td><td></td><td></td><td></td></tr><tr><td>0.9% sodium chloride (saline)</td><td>Hospira</td><td>0409-7984-11</td><td></td></tr><tr><td>Phosphate Buffered Saline [1x]&amp;nbsp;</td><td>Sigma</td><td>D8537</td><td>1x, w/o calcium chloride &amp;amp; magnesium chloride</td></tr><tr><td>Ultrasound contrast agent, target ready and untargeted</td><td>MicroMarker; VisualSonics Inc.</td><td></td><td></td></tr><tr><td>Ultrasound gel (Aquasonic 100, colourless)</td><td>CSP Medical</td><td>133-1009</td><td></td></tr><tr><td>Ice bucket</td><td>Cole Parmer</td><td>RK 06274-01</td><td></td></tr><tr><td>Imaging Platform</td><td>VisualSonics Inc.</td><td>Integrated Rail System</td><td></td></tr><tr><td>Light source, fiber-optic</td><td>Fisher Scientific</td><td>12-562-36</td><td>Ideally has adjustable arms</td></tr><tr><td>Luers (12), polypropylene barbed female &amp;frac14;-28 UNF thread</td><td>Cole Parmer</td><td>45500-30</td><td></td></tr><tr><td>Micro-ultrasound system, high-frequency</td><td>VisualSonics Inc.</td><td>Vevo2100</td><td></td></tr><tr><td>Needles, 21 gauge&amp;nbsp; (1&amp;rdquo;)</td><td>VWR</td><td>305165</td><td></td></tr><tr><td>Perforated spoon (Moria)</td><td>Fine Science Tools</td><td>MC 17 10373-17</td><td></td></tr><tr><td>Pins (6), black anodized minutien 0.15 mm</td><td>Fine Science Tools</td><td>26002-15</td><td></td></tr><tr><td>Syringes, 1 mL Normject</td><td>Fisher</td><td>14-817-25</td><td></td></tr><tr><td>Syringe infusion pump&amp;nbsp;</td><td>Bio-lynx&amp;nbsp;</td><td>NE-1000</td><td></td></tr><tr><td>Pipettors [2-20 &amp;mu;L, 20-200 &amp;mu;L, 100-1,000 &amp;mu;L]</td><td>Eppendorf</td><td>Research Plus adjustable&lt;br/&gt; 3120000038;&lt;br/&gt; 3120000054;&lt;br/&gt; 3120000062</td><td></td></tr><tr><td>Pipettor tips [2-200&amp;nbsp;&amp;mu;L, 50-1,000&amp;nbsp;&amp;mu;L]</td><td>Eppendorf</td><td>epT.I.P.S.&lt;br/&gt; 22491334;&lt;br/&gt; 022491351</td><td></td></tr><tr><td>Scissors</td><td></td><td></td><td></td></tr><tr><td>Glass capillaries, 1 x 90&amp;nbsp;mm GD-1 with filament</td><td>Narishige</td><td>GD-1</td><td></td></tr><tr><td>Glass needle puller</td><td>Narishige</td><td>PN-30</td><td></td></tr><tr><td>Tubes, Eppendorf</td><td>VWR</td><td>20170-577</td><td></td></tr><tr><td>Tube racks (3)</td><td>VWR</td><td>82024-462</td><td></td></tr><tr><td>Hot plate</td><td>VWR</td><td>89090-994</td><td></td></tr><tr><td>Syringes (10), 30 mL</td><td>VWR</td><td>CA64000-041</td><td></td></tr><tr><td>Ultrasound transducer, 20 MHz</td><td>VisualSonics Inc.</td><td>MS250</td><td></td></tr></tbody></table>

injection of microbubbles into isolated mouse embryos: a technique to deliver microbubble contrast agents into the vasculature of living murine embryos

Source: Denbeigh, J. M. et al. <a href="https://www.jove.com/video/52520" target="_blank">Contrast Imaging in Mouse Embryos Using High-frequency Ultrasound</a>. J. Vis. Exp. (2015)
This video demonstrates a procedure to inject microbubble contrast agents into an isolated late gestation stage mouse embryo. The microbubble contrast agent-based ultrasound imaging helps visualize and characterize the vascular environment of the embryo.

Injection of Microbubbles into Isolated Mouse Embryos: A Technique to Deliver Microbubble Contrast Agents into the Vasculature of Living Murine Embryos

Source: Denbeigh, J. M. et al. Contrast Imaging in Mouse Embryos Using High-frequency Ultrasound. J. Vis. Exp. (2015)
This video demonstrates a procedure ...

For microbubble delivery, begin with a uniform suspension of endothelial cell-targeted lipid-shelled microbubbles comprising a gaseous core in a syringe connected to the tubing.
Load this assembly into a syringe pump and attach a glass needle to the tubing. Now, transfer a chilled mouse embryo expressing specific endothelial cell receptors into a dish placed on the stage of a stereoscope.
Gently exteriorize the embryo from the yolk sac and amniotic membrane. Secure the sac and the placental edges. Rinse the embryo with a warm buffer to restore its blood flow. Cover the embryo with pre-warmed ultrasound gel for optimal ultrasound wave transmission. Supplement with buffer to maintain its physiological conditions.
Carefully inject the microbubble suspension at the desired flow rate into a suitable vein on the fetal membrane surface of the placental disc using the syringe pump. The injected microbubbles travel through the circulation and bind to the specific receptors on the endothelial cells lining the blood vessels.
Use an ultrasound transducer to transmit high-frequency ultrasound waves to the embryo. The microbubbles&#39; highly compressible gas cores cause them to oscillate nonlinearly, scattering ultrasound waves with frequencies different from the incident waves. These signals and the tissue&#39;s linear signals return to the transducer.
The transducer relays them to an imaging system that differentiates the microbubble scattered signals from the tissue signals, producing contrast-enhanced ultrasound images of the embryonic blood vessels.

injection-microbubbles-into-isolated-mouse-embryos-technique-to

Research

JoVE Encyclopedia of Experiments

Biology

Rodent Models

Embryo

2.1K 次观看. 来源:Denbeigh， J. M. et al.对比成像。J. Vis. Exp.（2015 年） 该视频演示了将微泡造影剂注射到分离的妊娠晚期小鼠胚胎中的程序。基于微泡造影剂的超声成像有助于可视化和表征胚胎的血管环境。 

视频: 将微气泡注射到离体小鼠胚胎中:一种将微泡造影剂输送到活小鼠胚胎的脉管系统的技术 - 概念

High Frequency Ultrasound for the Analysis of Fetal and Placental Development In Vivo

Ultrasound imaging is a widespread method used to detect organ anomalies and tumors in human and animal tissues. The method is non-invasive, harmless, and painless, and the application is easy, fast, and can be done anywhere, even with mobile devices. During pregnancy, ultrasound imaging is standardly used to closely monitor fetal development. The technique is important to assess intrauterine growth restriction (IUGR), a pregnancy complication with short- and long-term health consequences for both the mother and fetus. Understanding the process of IUGR is indispensable for developing effective therapeutic strategies. 
The ultrasound system used in this manuscript is an ultrasound device produced for the analysis of small animals and can be used in various research fields, including pregnancy research. Here we describe the usage of the system for in vivo analysis of fetuses from natural killer (NK) cell/mast cell (MC)-deficient mothers that give birth to growth-restricted pups. The protocol includes preparation of the system, handling of the mice before and during measurements, and the usage of the B-mode, color doppler mode, and pulse-wave doppler mode. Fetal size, placental size, and blood supply to the fetus were analyzed. We found reduced implantation sizes and smaller placentas in NK/MC-deficient mice from mid-gestation onwards. In addition, MC/NK-deficiency was associated with absent and reversed end diastolic flow in the fetal Arteria umbilicalis(UmA) and an elevated resistance index. The methods described in the protocol can easily be used for related and non-related research topics.

High Frequency Ultrasound for the Analysis of Fetal and Placental Development In Vivo

Here we describe the technique of high frequency ultrasound for in vivo analysis of fetuses in mice. This method allows the follow-up of fetuses and the analysis of placental parameters as well as maternal and fetal blood flow throughout pregnancy.

高频超声在胎儿和胎盘发育分析中的影响

Ultrasound imaging is a widespread method used to detect organ anomalies and tumors in human and animal tissues. The method is non-invasive, harmless, and ...

科研

JoVE Journal

发育生物学

Contrast Enhanced Ultrasound Imaging for Assessment of Spinal Cord Blood Flow in Experimental Spinal Cord Injury

Reduced spinal cord blood flow (SCBF) (i.e., ischemia) plays a key role in traumatic spinal cord injury (SCI) pathophysiology and is accordingly an important target for neuroprotective therapies. Although several techniques have been described to assess SCBF, they all have significant limitations. To overcome the latter, we propose the use of real-time contrast enhanced ultrasound imaging (CEU). Here we describe the application of this technique in a rat contusion model of SCI. A jugular catheter is first implanted for the repeated injection of contrast agent, a sodium chloride solution of sulphur hexafluoride encapsulated microbubbles. The spine is then stabilized with a custom-made 3D-frame and the spinal cord dura mater is exposed by a laminectomy at ThIX-ThXII. The ultrasound probe is then positioned at the posterior aspect of the dura mater (coated with ultrasound gel). To assess baseline SCBF, a single intravenous injection (400 &#181;l) of contrast agent is applied to record its passage through the intact spinal cord microvasculature. A weight-drop device is subsequently used to generate a reproducible experimental contusion model of SCI. Contrast agent is re-injected 15 min following the injury to assess post-SCI SCBF changes. CEU allows for real time and in-vivo assessment of SCBF changes following SCI. In the uninjured animal, ultrasound imaging showed uneven blood flow along the intact spinal cord. Furthermore, 15 min post-SCI, there was critical ischemia at the level of the epicenter while SCBF remained preserved in the more remote intact areas. In the regions adjacent to the epicenter (both rostral and caudal), SCBF was significantly reduced. This corresponds to the previously described &#8220;ischemic penumbra zone&#8221;. This tool is of major interest for assessing the effects of therapies aimed at limiting ischemia and the resulting tissue necrosis subsequent to SCI.

Contrast Enhanced Ultrasound imaging is a reliable in-vivo tool for quantifying spinal cord blood flow in an experimental rat spinal cord injury model. This paper contains a comprehensive protocol for application of this technique in association with a contusion model of thoracic spinal cord injury.

超声造影成像脊髓血流量的评估实验脊髓损伤

Reduced spinal cord blood flow (SCBF) (i.e., ischemia) plays a key role in traumatic spinal cord injury (SCI) pathophysiology and is accordingly an ...

医学

Delivery of Antibodies into the Brain Using Focused Scanning Ultrasound

Only a small fraction of therapeutic antibodies targeting brain diseases are taken up by the brain. Focused ultrasound offers a possibility to increase uptake of antibodies and engagement through transient opening of the blood-brain barrier (BBB). In our laboratory, we are developing therapeutic approaches for neurodegenerative diseases in which an antibody in various formats is delivered across the BBB using microbubbles, concomitant with focused ultrasound application through the skull targeting multiple spots, an approach we refer to as scanning ultrasound (SUS). The mechanical effects of microbubbles and ultrasound on blood vessels increases paracellular transport across the BBB by transiently separating tight junctions and enhances vesicle- mediated transcytosis, allowing antibodies and therapeutic agents to effectively cross. Moreover, ultrasound also facilitates the uptake of antibodies from the interstitial brain into brain cells such as neurons where the antibody distributes throughout the cell body and even into neuritic processes. In our studies, fluorescently labeled antibodies are prepared, mixed with in-house prepared lipid-based microbubbles and injected into mice immediately before SUS is applied to the brain. The increased antibody concentration in the brain is then quantified. To account for alterations in normal brain homeostasis, microglial phagocytosis can be used as a cellular marker. The generated data suggest that ultrasound delivery of antibodies is an attractive approach to treat neurodegenerative diseases.

Presented here is a protocol to transiently open the blood-brain barrier (BBB) either focally or throughout a mouse brain to deliver fluorescently-labeled antibodies and activate microglia. Also presented is a method to detect the delivery of antibodies and microglia activation by histology.

使用聚焦扫描超声将抗体输送到大脑中

Only a small fraction of therapeutic antibodies targeting brain diseases are taken up by the brain. Focused ultrasound offers a possibility to increase ...

Injection of Microbubbles into Isolated Mouse Embryos: A Technique to Deliver Microbubble Contrast Agents into the Vasculature of Living Murine Embryos

成績單

Injection of Microbubbles into Isolated Mouse Embryos: A Technique to Deliver Microbubble Contrast Agents into the Vasculature of Living Murine Embryos