Name: using a microfluidics device for mechanical stimulation and high resolution imaging of c. elegans
Uploaded: 2018-02-19T13:00:00
Description: Watch this Scientific Journal Video about Using a Microfluidics Device for Mechanical Stimulation and High Resolution Imaging of C. elegans at JoVE.com

We thank Sandra N. Manosalvas-Kjono, Purim Ladpli, Farah Memon, Divya Gopisetty, and Veronica Sanchez for support in device design and generation of mutant animals. This research was supported by NIH grants R01EB006745 (to BLP), R01NS092099 (to MBG), K99NS089942 (to MK), F31NS100318 (to ALN) and received funding from the European Research Council (ERC) under the European Union&#39;s Horizon 2020 research and innovation program (grant agreement No. 715243 to MK).

1. Device Fabrication
<ol>
	<li>Download the attached mask file (Supplemental File 1) and generate a chrome mask using a commercial service or in-house facility. As the smallest dimension on the device is 10 &#181;m (actuator membrane thickness), ensure that the mask has sufficiently high resolution, within &#177; 0.25 &#181;m, to reliably produce the features.</li>
	<li>Follow standard SU-8 photolithography methods (e.g., references24,<stron...

<ol>
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B., Chalfie, M. <a target="_blank" href="http://www.ncbi.nlm.nih.gov/entrez/query.fcgi?db=PubMed&cmd=Search&doptcmdl=Citation&defaultField=Title+Word&term=The+DEG/ENaC+protein+MEC-10+regulates+the+transduction+channel+complex+in+Caenorhabditis+elegans+touch+receptor+neurons.">The DEG/ENaC protein MEC-10 regulates the transduction channel complex in Caenorhabditis elegans touch receptor neurons.</a> J. Neurosci. 31 (35), 12695-12704 (2011).</li><li>Lockhead, D., et al. <a target="_blank" href="http://www.ncbi.nlm.nih.gov/entrez/query.fcgi?db=PubMed&cmd=Search&doptcmdl=Citation&defaultField=Title+Word&term=The+tubulin+repertoire+of+Caenorhabditis+elegans+sensory+neurons+and+its+context-dependent+role+in+process+outgrowth.">The tubulin repertoire of Caenorhabditis elegans sensory neurons and its context-dependent role in process outgrowth.</a> Mol. Biol. Cell. 27 (23), 3717-3728 (2016).</li><li>Goodman, M. B., Ernstrom, G. G., Chelur, D. S., O'hagan, R., Yao, C. 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This protocol demonstrates a method for delivering precise mechanical stimulation to the skin of a roundworm trapped in a microfluidic chip. It is intended to facilitate the integration of physical stimuli for answering biological questions and aims to streamline mechanobiology research in biological labs. This method extends previous assays to assess the function of mechanosensory neurons in C. elegans. Previous quantitative and semi-quantitative techniques measured forces1,<s...

The sense of touch provides animals with crucial information about their environment. Depending on the applied force, touch is perceived as innocuous, pleasurable, or painful. The tissue deformation during touch is detected by specialized mechanoreceptor cells embedded in the skin that express receptor proteins, most commonly ion channels. The steps linking force perception to ion channel activation during touch and pain are not fully understood. Even less is known about how the skin tissue filters mechanical deformation and whether mechanoreceptors detect changes in strain or stress1,2,3. This gap in understanding arises, in part, from a lack of suitable tools to apply precise mechanical stimulations to the surface of the skin of a living animal while observing the responses at the cellular level. Whereas atomic force microscopy has been used extensively to apply and measure forces in isolated cells4,5 and also to activate Piezo1 receptors in living cells6, similar experiments using living animals, especially C. elegans, have been notoriously challenging due to the intrinsic mobility of the subject. This challenge is traditionally circumvented by using veterinary- or surgical-grade cyanoacrylate glue to immobilize individual animals on agar pads1,7,8,9. This approach has been productive, but has limitations related to the skill required for immobilization by gluing and the soft agar surface on mechanical compliance. A microfluidics strategy is a complimentary alternative that avoids some of the complications linked to gluing.
The nematode C. elegans is a genetic model organism with a completely mapped nervous system that, due to the animal&#39;s size, is a good fit for microfluidics technology. Microfluidics-based devices offer the advantage that the otherwise extremely mobile animals can be restrained while performing high-resolution imaging and delivery of relevant neuro-modulatory stimuli. With the help of microfluidic technologies, living animals can be immobilized without harm10,11, enabling monitoring of behavioral activity over the entire lifetime12,13 and high-resolution imaging of neuronal activity14,15,16,17. Further, many mechanoreceptor neurons needed for the sense of touch and pain can be characterized on their physiological1,8, mechanical4,18,19, and molecular level20,21,22.
C. elegans senses gentle mechanical stimuli to its body wall using six TRNs, three of which innervate the animal&#39;s anterior (ALML/R and AVM) and three of which innervate the animal&#39;s posterior (PLML/R and PVM). The ion channel molecules needed for transducing an applied force into a biochemical signal have been extensively studied in its TRNs8. This article presents a microfluidic platform23 that enables researchers to apply precise mechanical forces to the skin of an immobilized C. elegans roundworm, while reading out the deformation of its internal tissues by optical imaging. In addition to presenting well-defined mechanical stimuli, calcium transients can be recorded in mechanoreceptor neurons with subcellular resolution and correlated with morphological and anatomical features. The device consists of a central trapping channel that holds a single animal and presents its skin next to six pneumatic actuation channels (Figure 1 and Figure 2). The six channels are positioned along the trapping channel to deliver mechanical stimuli to each of the worm&#39;s six TRNs. These channels are separated from the trapping chamber by thin PDMS diaphragms, which can be driven by an external air pressure source (Figure 1). We calibrated the deflection with respect to pressure and provide the measurements in this article. Each actuator can be addressed individually and used to stimulate a mechanoreceptor of choice. The pressure is delivered using a piezo-driven pressure pump but any alternative device can be used. We show that the pressure protocol can be used to activate TRNs in vivo and demonstrate operating devices suitable for delivering mechanical stimuli to adult C. elegans, loading adult animals into devices, performing calcium imaging experiments, and analyzing the results. Device fabrication consists of two main steps: 1) photolithography to make a mold from SU-8; and 2) molding PDMS to make a device. For the sake of brevity and clarity, readers are referred to previously published articles and protocols24,25 for instructions on how to produce the molds and devices.

<table>
	<tbody>
		<tr>
			<td>Chrome mask</td>
			<td>Compugraphics (http://www.compugraphics-photomasks.com/)</td>
			<td></td>
			<td>5&#39;&#39;, designed in AutoCAD (Autodesk, Inc.)</td>
		</tr>
		<tr>
			<td>Chrome mask</td>
			<td>Mitani-Micronics (http://www.mitani-micro.co.jp/en/)</td>
			<td></td>
			<td>5&#39;&#39;, designed in AutoCAD (Autodesk, Inc.)</td>
		</tr>
		<tr>
			<td>Chrome mask</td>
			<td>Kuroda-Electric (http://www.kuroda-electric.eu/</td>
			<td></td>
			<td>5&#39;&#39;, designed in AutoCAD (Autodesk, Inc.)</td>
		</tr>
		<tr>
			<td>4&#39;&#39; Silicon wafer (B-test)</td>
			<td>Stanford Nanofabrication Facility</td>
			<td></td>
			<td></td>
		</tr>
		<tr>
			<td>SU-8 2002</td>
			<td>MicroChem</td>
			<td></td>
			<td></td>
		</tr>
		<tr>
			<td>SU-8 2050</td>
			<td>MicroChem</td>
			<td></td>
			<td></td>
		</tr>
		<tr>
			<td>Spin-coater</td>
			<td>Laurell Technologies</td>
			<td>WS-400BZ-6NPP/LITE</td>
			<td></td>
		</tr>
		<tr>
			<td>Exposure timer</td>
			<td>Optical Associates, Inc</td>
			<td>OAI 150</td>
			<td></td>
		</tr>
		<tr>
			<td>Illumination controller</td>
			<td>Optical Associates, Inc</td>
			<td>2105C2</td>
			<td></td>
		</tr>
		<tr>
			<td>SU-8 developer</td>
			<td>MicroChem</td>
			<td></td>
			<td></td>
		</tr>
		<tr>
			<td>2-Propanol</td>
			<td>Fisher Scientific</td>
			<td>A426F-1GAL</td>
			<td></td>
		</tr>
		<tr>
			<td>Acetone</td>
			<td>Fisher Scientific</td>
			<td>A18-4</td>
			<td></td>
		</tr>
		<tr>
			<td>Trichloromethylsilane (TCMS)</td>
			<td>Sigma-Aldrich</td>
			<td>92361-500ML</td>
			<td>Caution: TCMS is toxic and water-reactive</td>
		</tr>
		<tr>
			<td>Sylgard 184 Elastomer Kit</td>
			<td>Dow Corning</td>
			<td></td>
			<td>PDMS prepolymer</td>
		</tr>
		<tr>
			<td>Biopsy punch, 1 mm</td>
			<td>VWR</td>
			<td>95039-090</td>
			<td></td>
		</tr>
		<tr>
			<td>Oxygen Plasma Asher</td>
			<td>Branson/IPC</td>
			<td></td>
			<td></td>
		</tr>
		<tr>
			<td>Small metal tubing (0.635 mm OD, 0.4318 mm ID, 12.7 mm long); gage size 23TW</td>
			<td>New England Small Tube Corporation</td>
			<td>NE-1300-01</td>
			<td></td>
		</tr>
		<tr>
			<td>Nalgene syringe filter, 0.22 &#956;m</td>
			<td>Thermo Scientific</td>
			<td>725-2520</td>
			<td>to filter all solution, small particles would clog the chip</td>
		</tr>
		<tr>
			<td>Polyethylene tubing; 0.9652 mm OD, 0.5842 mm ID</td>
			<td>Solomon Scientific</td>
			<td>BPE-T50</td>
			<td></td>
		</tr>
		<tr>
			<td>Syringe, 1 ml</td>
			<td>BD Scientific</td>
			<td>309628</td>
			<td>for worm trapping and release</td>
		</tr>
		<tr>
			<td>Syringe, 20 ml</td>
			<td>BD Scientific</td>
			<td>309661</td>
			<td>for gravity-based flow</td>
		</tr>
		<tr>
			<td>Gilson Minipuls 3, Peristaltic pump</td>
			<td>Gilson</td>
			<td></td>
			<td>to suck solutions and worms out of the chip</td>
		</tr>
		<tr>
			<td>Microfluidic flow controller, equipped with 0&#8211;800 kPa pressure channel</td>
			<td>Elveflow</td>
			<td>OB1 MK3</td>
			<td>pressure delivery</td>
		</tr>
		<tr>
			<td>Water-Resistant Clear Poly- urethane Tubing, 4 mm ID and 6 mm OD</td>
			<td>McMaster-Carr</td>
			<td>5195 T52</td>
			<td>connection from house air to pressure pump</td>
		</tr>
		<tr>
			<td>Water-Resistant Clear Polyurethane Tubing, 2.6mm ID and 4mm OD</td>
			<td>McMaster-Carr</td>
			<td>5195 T51</td>
			<td>connect pressure pump to small tubng</td>
		</tr>
		<tr>
			<td>Push-to-Connect Tube Fitting for Air</td>
			<td>McMaster-Carr</td>
			<td>5111K468</td>
			<td>metric - imperial converter</td>
		</tr>
		<tr>
			<td>Straight Connector for 6 mm &#215; 1/4&#8243; Tube OD</td>
			<td>McMaster-Carr</td>
			<td>5779 K258</td>
			<td></td>
		</tr>
		<tr>
			<td>Leica DMI 4000 B microscopy system</td>
			<td>Leica</td>
			<td></td>
			<td></td>
		</tr>
		<tr>
			<td>63&#215;/1.32 NA HCX PL APO oil objective</td>
			<td>Leica</td>
			<td>506081</td>
			<td></td>
		</tr>
		<tr>
			<td>Hamamatsu Orca-Flash 4.0LT digital CMOS camera</td>
			<td>Hamamatsu</td>
			<td>C11440-42U</td>
			<td></td>
		</tr>
		<tr>
			<td>Lumencor Spectra X light engine</td>
			<td>Lumencor</td>
			<td></td>
			<td>With cyan and green/yellow light source</td>
		</tr>
		<tr>
			<td>Excitation beam splitter</td>
			<td>Chroma</td>
			<td>59022bs</td>
			<td>in the microscope</td>
		</tr>
		<tr>
			<td>Hamamatsu W-view Gemini Image splitting optics</td>
			<td>Hamamatsu</td>
			<td>A12801-01</td>
			<td>to split green and red emission and project them on different areas on the camera chip</td>
		</tr>
		<tr>
			<td>Emission beam splitter</td>
			<td>Chroma</td>
			<td>T570lpxr</td>
			<td>in the image splitter</td>
		</tr>
		<tr>
			<td>Emission filters GCamp6s</td>
			<td>Chroma</td>
			<td>ET525/50m</td>
			<td>in the image splitter</td>
		</tr>
		<tr>
			<td>Emission filters mCherry</td>
			<td>Chroma</td>
			<td>ET632/60m</td>
			<td>in the image splitter</td>
		</tr>
	</tbody>
</table>

using a microfluidics device for mechanical stimulation and high resolution imaging of c. elegans

One central goal of mechanobiology is to understand the reciprocal effect of mechanical stress on proteins and cells. Despite its importance, the influence of mechanical stress on cellular function is still poorly understood. In part, this knowledge gap exists because few tools enable simultaneous deformation of tissue and cells, imaging of cellular activity in live animals, and efficient restriction of motility in otherwise highly mobile model organisms, such as the nematode Caenorhabditis elegans. The small size of C. elegans makes them an excellent match to microfluidics-based research devices, and solutions for immobilization have been presented using microfluidic devices. Although these devices allow for high-resolution imaging, the animal is fully encased in polydimethylsiloxane (PDMS) and glass, limiting physical access for delivery of mechanical force or electrophysiological recordings. Recently, we created a device that integrates pneumatic actuators with a trapping design that is compatible with high-resolution fluorescence microscopy. The actuation channel is separated from the worm-trapping channel by a thin PDMS diaphragm. This diaphragm is deflected into the side of a worm by applying pressure from an external source. The device can target individual mechanosensitive neurons. The activation of these neurons is imaged at high-resolution with genetically-encoded calcium indicators. This article presents the general method using C. elegans strains expressing calcium-sensitive activity indicator (GCaMP6s) in their touch receptor neurons (TRNs). The method, however, is not limited to TRNs nor to calcium sensors as a probe, but can be expanded to other mechanically-sensitive cells or sensors.

SU-8 Lithography and Chip Bonding 
The lithography protocol and PDMS molding follow standard procedures. Details can be found elsewhere23,24,25,26. The PDMS should peel off the wafer without problems after curing. If the SU-8 features rip off during PDMS peeling, either the SU-8 adhesion layer or the silanization was insufficient. If plasma...

Watch this Scientific Journal Video about Using a Microfluidics Device for Mechanical Stimulation and High Resolution Imaging of C. elegans at JoVE.com

Using a Microfluidics Device for Mechanical Stimulation and High Resolution Imaging of C. elegans

New tools for mechanobiology research are needed to understand how mechanical stress activates biochemical pathways and elicits biological responses. Here, we showcase a new method for selective mechanical stimulation of immobilized animals with a microfluidic trap allowing high-resolution imaging of cellular responses.

Using a Microfluidics Device for Mechanical Stimulation and High Resolution Imaging of C. elegans

One central goal of mechanobiology is to understand the reciprocal effect of mechanical stress on proteins and cells. Despite its importance, the ...

The overall goal of this technique is to measure how nematodes and their neurons respond to external mechanical stimuli using a microfluidic chip setup with pressure actuators. This method can answer key questions in the fields of mechanobiology and sensory biology such as how cells, tissues and animals respond to mechanical stimulation. The main advantage of this technique is that it sufficiently reduces the worm's mobility in a non-invasive way to allow high-resolution imaging while still having access to the worm's cuticle for mechanical stimulation.This method can also be used to study the influence of mechanical cues on development. It could even be applied to other systems such ex vivo organ exponse or other animals of similar size to C.Elegans. Set up a microscope system for simultaneous excitation of GCaMP and RFP.One option is a discreet light source that transmits only cyan and yellow light. For viewing, use a 10-times objective and high-magnification objective. Also, send the image to a computer via digital camera.Next, include a florescence cube, and if needed, an excitation filter. Add a dichroic mirror to the cube that reflects cyan and yellow light and transmits green and red light. Set up a beam splitter with a long-pass dichroic mirror with a cutoff at 570 nanometers.Also, provide a band-pass emission filter for green light at 525 nanometers with a 50-nanometer width and a band-pass emission filter for red light at 632 nanometers with a 60-nanometer width. Project both beams into the camera's field of view. Make sure the green part is projected to the top half of the screen, and the red part to the bottom.Always use microfluidic chips that are less than one month old. For the setup, first load the gravity flow reservoir with filtered M9.Position the reservoir about 60 centimeters above the chip and connect it to a chip outlet. Next, connect the other outlet to a waste container with two inputs, and connect the second input to the waste container to a peristaltic pump.Make all the connections with polyethylene tubing. Next, assemble interconnects, 50-millimeter tubing lengths with metal tubing connectors on both ends. Press-fit and interconnect onto each of the six actuation fingers and into the worm inlet.Now, position the chip under the optics. Be sure to leave the interconnects attached to the chip as the PDMS will wear out quickly with repeated manipulations. It is vital that the PDMS actuator and the tubing connecting the chip to the air reservoir are properly sealed to ensure good chromatic actuation of the diaphragm.Before loading animals, check for loss of pressure in the microfluidic chip. Measure the deflection of the diaphragm by performing several actuation cycles at the desired pressure. Then, compare the quantitative values with theoretical predictions.If the measured values are not as expected, check for leaks in the tubing or tubing connectors. The PDMS may also have a different elasticity due to an alternative ratio of base polymer and curing agent, or the PD mass could be old and excessively crosslinked. Have prepared age-synchronized-to-young-adult or adult-day-one C.elegans as described by Porta-de-la-Riva and company in their Jove publication from 2012.Now, pick two to five young adults or one-day-old hermaphrodites. Choosing animals of the correct size is critical. Small animals will not get trapped in the channel, and overly large animals will be difficult to remove and can clog the device.Pull the picked worms in a drop of filtered M9.Then, draw them into a length of tubing using a one-milliliter syringe without pulling them into the syringe body itself. Next, connect the tubing to the interconnect at the worm inlet of the chip. Then, activate the gravity flow by opening the valve to the reservoir and starting the pump.Now, observe the trapping channel at four-times magnification and gently push the animals into the device. After loading the animals into the waiting chamber, use the plunger to gently flow one of them to the front of the trapping channel such that its head enters the tapered shape of the channel. If the worm does not fill the entire cross-section of the channel from the nose to near the end of the body, remove the worm.Many times, worms that are too small will go straight through the chip without being trapped. If an animal that got caught in the trapping channel needs to be removed, simply press the plunger of the syringe until the worm disappears from the channel and then load a new worm. Once a worm is properly loaded, switch to florescence mode and increase the magnification.To prevent saturation, be sure to adjust the excitation intensity based on the florescence intensity. Check whether the neurite of a neuron of interest lies across the diaphragm of one of the actuators. That actuator must also be anterior to the cell body of the neuron.If not, adjust the position of the animal by pulling or pushing on the plunger. If that does not help, remove the worm and load a new one. Also, if there happens to be autofluorescence around the neuron, replace the worm.Once a worm is properly loaded, focus on the cell body of the neuron of interest, then determine which actuator the chip is on its anterior side and connect this actuator to the programmable pressure pump using the associated interconnect. If the experiment requires measuring the distance between the actuator and the neuron, fit both into the field of view with the channel wall parallel to the upper and lower edge of the image. Next, define a pressure protocol using the programmable pressure pump.Always start by taking at least 50 images at zero kilopascals to define a baseline. Then, program the stimulus waveform and pressure. Now, run the imaging and pressure protocol.While recording, the neuron of interest must be the brightest spot in a 10-square-pixel area. It cannot move more than 10 pixels in two sequential images, and it must stay in the field of view. While recording, you may observe changes in the florescence intensity when the pressure and the actuators change.This indicates a successful stimulation of the neurons. Between stimuli, include 10 seconds at a constant pressure of zero kilopascal. It is possible to simultaneously record signals from multiple neurons in the field of view so long as they are separated by at least 10 pixels during the entire recording.To keep worms for further study, disconnect the outlets of the chip toward the gravity flow and the waste container. Then, gently press the plunger until the entire worm is pushed through the trapping channel into the flow channel, and continue to press the plunger until the animal appears in a droplet outside of the chip. Now, disconnect the syringe with the tubing and aspirate the worm in the droplet onto an agar plate.To remove and sacrifice a worm in the channel, press the plunger until the entire worm is pushed through the trapping channel and into the flow channel. Then, the worm will flow out of the chip and into the waste container. After setting up the microfluidic chip, the deflection of the diaphragm was tested.The measured values were reproducible with slight variation not exceeding one micron at 450 kilopascal of pressure. After inserting the worms into the inlet of the chip, the skin of a single animal inside the trapping channel was presented to the six actuators. With this design, the PLM neuron usually cannot be immobilized completely, so it free to move laterally and vertically.Although successful activation of PLM neurons is possible, recording calcium transients from them is difficult due to the tail movement. Once in place, the animal was stimulated using one of the six actuators positioned to deliver mechanical stimuli to each of the six TRNs. One of the three different two-second stimuli were presented.A hold at 275 kilopascals, a ramp to 275 kilopascals or a buzz consisting of a 75-kilopascal 10-hertz sine superimposed with the 275-kilopascal step. 10-second gaps with no pressure separated the stimuli. Pressure ramps and pressure steps activated TRNs only if the stimuli achieved pressures above 400 kilopascals, whereas the buzz stimuli robustly activated all TRN.Once mastered, this technique can be performed within five minutes per worm. It is important to remember that a poor seal between the chip and the coverslip, or between the chip and the interconnectors will cause the device to leak and fail. Following this procedure, other methods like voltage imaging or targeted delivery of mechanical stimuli to different neurons can be performed in order to characterize the mechanical response of nociceptors.Also, because the animals can be recovered following this procedure, the technique could be used to screen for mutants defective in their response to mechanical stimuli. Don't forget that working with compressed gases and chemicals can be extremely hazardous. Take precautions such as wearing personal protective garments and working in fume hoods when necessary to avoid those hazards.

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Research

JoVE Journal

Neuroscience

Assaying &beta;-amyloid Toxicity using a Transgenic C. elegans Model

Accumulation of the &beta;-amyloid peptide (A&beta;) is generally believed to be central to the induction of Alzheimer's disease, but the relevant mechanism(s) of toxicity are still unclear. A&beta; is also deposited intramuscularly in Inclusion Body Myositis, a severe human myopathy. The intensely studied nematode worm Caenorhabditis elegans can be transgenically engineered to express human A&beta;. Depending on the tissue or timing of A&beta; expression, transgenic worms can have readily measurable phenotypes that serve as a read-out of A&beta; toxicity. For example, transgenic worms with pan-neuronal A&beta; expression have defects is associative learning (Dosanjh et al. 2009), while transgenic worms with constitutive muscle-specific expression show a progressive, age-dependent paralysis phenotype (Link, 1995; Cohen et al. 2006). One particularly useful C. elegans model employs a temperature-sensitive mutation in the mRNA surveillance system to engineer temperature-inducible muscle expression of an A&beta; transgene, resulting in a reproducible paralysis phenotype upon temperature upshift (Link et al. 2003). Treatments that counter A&beta; toxicity in this model [e.g., expression of a protective transgene (Hassan et al. 2009) or exposure to Ginkgo biloba extracts (Wu et al. 2006)] reproducibly alter the rate of paralysis induced by temperature upshift of these transgenic worms. Here we describe our protocol for measuring the rate of paralysis in this transgenic C. elegans model, with particular attention to experimental variables that can influence this measurement.

Assaying &amp;#946;-amyloid Toxicity using a Transgenic C. elegans Model

The intensely studied nematode worm Caenorhabditis elegans can be transgenically engineered to express the human &beta;-amyloid peptide (A&beta;). Induced expression of A&beta; in C. elegans muscle leads to a rapid, reproducible paralysis phenotype that can be used to monitor treatments that modulate A&beta; toxicity.

Accumulation of the &beta;-amyloid peptide (A&beta;) is generally believed to be central to the induction of Alzheimer's disease, but the relevant ...

Combining Transcranial Magnetic Stimulation and fMRI to Examine the Default Mode Network

The default mode network is a group of brain regions that are active when an individual is not focused on the outside world and the brain is at "wakeful rest."1,2,3 It is thought the default mode network corresponds to self-referential or "internal mentation".2,3
It has been hypothesized that, in humans, activity within the default mode network is correlated with certain pathologies (for instance, hyper-activation has been linked to schizophrenia 4,5,6 and autism spectrum disorders 7 whilst hypo-activation of the network has been linked to Alzheimer's and other neurodegenerative diseases 8). As such, noninvasive modulation of this network may represent a potential therapeutic intervention for a number of neurological and psychiatric pathologies linked to abnormal network activation. One possible tool to effect this modulation is Transcranial Magnetic Stimulation: a non-invasive neurostimulatory and neuromodulatory technique that can transiently or lastingly modulate cortical excitability (either increasing or decreasing it) via the application of localized magnetic field pulses.9
In order to explore the default mode network's propensity towards and tolerance of modulation, we will be combining TMS (to the left inferior parietal lobe) with functional magnetic resonance imaging (fMRI). Through this article, we will examine the protocol and considerations necessary to successfully combine these two neuroscientific tools.

In this article, we examine the methodology and considerations relevant to the combination of TMS and fMRI to examine the effects of brain stimulation on the default network.

The default mode network is a group of brain regions that are active when an individual is not focused on the outside world and the brain is at "wakeful ...

TMS: Using the Theta-Burst Protocol to Explore Mechanism of Plasticity in Individuals with Fragile X Syndrome and Autism

Fragile X Syndrome (FXS), also known as Martin-Bell Syndrome, is a genetic abnormality found on the X chromosome.1,2 Individuals suffering from FXS display abnormalities in the expression of FMR1 - a protein required for typical, healthy neural development.3 Recent data has suggested that the loss of this protein can cause the cortex to be hyperexcitable thereby affecting overall patterns of neural plasticity.4,5
In addition, Fragile X shows a strong comorbidity with autism: in fact, 30% of children with FXS are diagnosed with autism, and 2 - 5% of autistic children suffer from FXS.6
Transcranial Magnetic Stimulation (a non-invasive neurostimulatory and neuromodulatory technique that can transiently or lastingly modulate cortical excitability via the application of localized magnetic field pulses 7,8) represents a unique method of exploring plasticity and the manifestations of FXS within affected individuals. More specifically, Theta-Burst Stimulation (TBS), a specific stimulatory protocol shown to modulate cortical plasticity for a duration up to 30 minutes after stimulation cessation in healthy populations, has already proven an efficacious tool in the exploration of abnormal plasticity.9,10 
Recent studies have shown the effects of TBS last considerably longer in individuals on the autistic spectrum - up to 90 minutes.11 This extended effect-duration suggests an underlying abnormality in the brain's natural plasticity state in autistic individuals - similar to the hyperexcitability induced by Fragile X Syndrome.
In this experiment, utilizing single-pulse motor-evoked potentials (MEPs) as our benchmark, we will explore the effects of both intermittent and continuous TBS on cortical plasticity in individuals suffering from FXS and individuals on the Autistic Spectrum.

In this article, we examine the effects of Theta-Burst TMS stimulation on cortical plasticity in individuals suffering from Fragile X syndrome and individuals on the autistic spectrum.

Fragile X Syndrome (FXS), also known as Martin-Bell Syndrome, is a genetic abnormality found on the X chromosome.1,2 Individuals suffering from FXS ...

State-Dependency Effects on TMS:  A Look at Motive Phosphene Behavior

Transcranial magnetic stimulation (TMS) is a non-invasive neurostimulatory and neuromodulatory technique that can transiently or lastingly modulate cortical excitability (either increasing or decreasing it) via the application of localized magnetic field pulses.1,2 Within the field of TMS, the term state dependency refers to the initial, baseline condition of the particular neural region targeted for stimulation. As can be inferred, the effects of TMS can (and do) vary according to this primary susceptibility and responsiveness of the targeted cortical area.3,4,5

In this experiment, we will examine this concept of state dependency through the elicitation and subjective experience of motive phosphenes. Phosphenes are visually perceived flashes of small lights triggered by electromagnetic pulses to the visual cortex. These small lights can assume varied characteristics depending upon which type of visual cortex is being stimulated. In this particular study, we will be targeting motive phosphenes as elicited through the stimulation of V1/V2 and the V5/MT+ complex visual regions.6

In this article, we examine the effects of visually relevant state dependency on TMS induced motive phosphenic presentations.

Transcranial magnetic stimulation (TMS) is a non-invasive neurostimulatory and neuromodulatory technique that can transiently or lastingly modulate ...

The NeuroStar TMS Device: Conducting the FDA Approved Protocol for Treatment of Depression

The Neuronetics NeuroStar Transcranial Magnetic Stimulation (TMS) System is a class II medical device that produces brief duration, pulsed magnetic fields. These rapidly alternating fields induce electrical currents within localized, targeted regions of the cortex which are associated with various physiological and functional brain changes.1,2,3
In 2007, O'Reardon et al., utilizing the NeuroStar device, published the results of an industry-sponsored, multisite, randomized, sham-stimulation controlled clinical trial in which 301 patients with major depression, who had previously failed to respond to at least one adequate antidepressant treatment trial, underwent either active or sham TMS over the left dorsolateral prefrontal cortex (DLPFC). The patients, who were medication-free at the time of the study, received TMS five times per week over 4-6 weeks.4
The results demonstrated that a sub-population of patients (those who were relatively less resistant to medication, having failed not more than two good pharmacologic trials) showed a statistically significant improvement on the Montgomery-Asberg Depression Scale (MADRS), the Hamilton Depression Rating Scale (HAMD), and various other outcome measures. In October 2008, supported by these and other similar results5,6,7, Neuronetics obtained the first and only Food and Drug Administration (FDA) approval for the clinical treatment of a specific form of medication-refractory depression using a TMS Therapy device (FDA approval K061053).
In this paper, we will explore the specified FDA approved NeuroStar depression treatment protocol (to be administered only under prescription and by a licensed medical profession in either an in- or outpatient setting).

In this article, we examine the methodology and considerations relevant to the FDA approved depression treatment protocol using the Neuronetics NeuroStar TMS device.

The Neuronetics NeuroStar Transcranial Magnetic Stimulation (TMS) System is a class II medical device that produces brief duration, pulsed magnetic ...

Enabling High Grayscale Resolution Displays and Accurate Response Time Measurements on Conventional Computers

Display systems based on conventional computer graphics cards are capable of generating images with 8-bit gray level resolution. However, most experiments in vision research require displays with more than 12 bits of luminance resolution. Several solutions are available. Bit++ 1 and DataPixx 2 use the Digital Visual Interface (DVI) output from graphics cards and high resolution (14 or 16-bit) digital-to-analog converters to drive analog display devices. The VideoSwitcher 3 described here combines analog video signals from the red and blue channels of graphics cards with different weights using a passive resister network 4 and an active circuit to deliver identical video signals to the three channels of color monitors. The method provides an inexpensive way to enable high-resolution monochromatic displays using conventional graphics cards and analog monitors. It can also provide trigger signals that can be used to mark stimulus onsets, making it easy to synchronize visual displays with physiological recordings or response time measurements.
Although computer keyboards and mice are frequently used in measuring response times (RT), the accuracy of these measurements is quite low. The RTbox is a specialized hardware and software solution for accurate RT measurements. Connected to the host computer through a USB connection, the driver of the RTbox is compatible with all conventional operating systems. It uses a microprocessor and high-resolution clock to record the identities and timing of button events, which are buffered until the host computer retrieves them. The recorded button events are not affected by potential timing uncertainties or biases associated with data transmission and processing in the host computer. The asynchronous storage greatly simplifies the design of user programs. Several methods are available to synchronize the clocks of the RTbox and the host computer. The RTbox can also receive external triggers and be used to measure RT with respect to external events. 
Both VideoSwitcher and RTbox are available for users to purchase. The relevant information and many demonstration programs can be found at <a href="http://lobes.usc.edu/">http://lobes.usc.edu/</a>.

Conventional computer hardware can not generate visual stimuli with sufficiently high grayscale resolution and measure response times with sufficient accuracy. We describe how to use the VideoSwitcher to produce high-resolution monochromatic displays, and the RTbox to measure response times with high accuracy on conventional computer hardware.

Display systems based on conventional computer graphics cards are capable of generating images with 8-bit gray level resolution. However, most experiments ...

High-resolution Functional Magnetic Resonance Imaging Methods for Human Midbrain

Functional MRI (fMRI) is a widely used tool for non-invasively measuring correlates of human brain activity. However, its use has mostly been focused upon measuring activity on the surface of cerebral cortex rather than in subcortical regions such as midbrain and brainstem. Subcortical fMRI must overcome two challenges: spatial resolution and physiological noise. Here we describe an optimized set of techniques developed to perform high-resolution fMRI in human SC, a structure on the dorsal surface of the midbrain; the methods can also be used to image other brainstem and subcortical structures.
High-resolution (1.2 mm voxels) fMRI of the SC requires a non-conventional approach. The desired spatial sampling is obtained using a multi-shot (interleaved) spiral acquisition1. Since, T2* of SC tissue is longer than in cortex, a correspondingly longer echo time (TE ~ 40 msec) is used to maximize functional contrast. To cover the full extent of the SC, 8-10 slices are obtained. For each session a structural anatomy with the same slice prescription as the fMRI is also obtained, which is used to align the functional data to a high-resolution reference volume.
In a separate session, for each subject, we create a high-resolution (0.7 mm sampling) reference volume using a T1-weighted sequence that gives good tissue contrast. In the reference volume, the midbrain region is segmented using the ITK-SNAP software application2. This segmentation is used to create a 3D surface representation of the midbrain that is both smooth and accurate3. The surface vertices and normals are used to create a map of depth from the midbrain surface within the tissue4.
Functional data is transformed into the coordinate system of the segmented reference volume. Depth associations of the voxels enable the averaging of fMRI time series data within specified depth ranges to improve signal quality. Data is rendered on the 3D surface for visualization.
In our lab we use this technique for measuring topographic maps of visual stimulation and covert and overt visual attention within the SC1. As an example, we demonstrate the topographic representation of polar angle to visual stimulation in SC.

This article describes techniques to perform high-resolution functional magnetic resonance imaging with 1.2 mm sampling in human midbrain and subcortical structures using a 3T scanner. Use of these techniques to resolve topographic maps of visual stimulation in the human superior colliculus (SC) is given as an example.

Functional MRI (fMRI) is a widely used tool for non-invasively measuring correlates of human brain activity. However, its use has mostly been focused upon ...

High-resolution Live Imaging of Cell Behavior in the Developing Neuroepithelium

The embryonic spinal cord consists of cycling neural progenitor cells that give rise to a large percentage of the neuronal and glial cells of the central nervous system (CNS). Although much is known about the molecular mechanisms that pattern the spinal cord and elicit neuronal differentiation1, 2, we lack a deep understanding of these early events at the level of cell behavior. It is thus critical to study the behavior of neural progenitors in real time as they undergo neurogenesis.
In the past, real-time imaging of early embryonic tissue has been limited by cell/tissue viability in culture as well as the phototoxic effects of fluorescent imaging. Here we present a novel assay for imaging such tissue for long periods of time, utilizing a novel ex vivo slice culture protocol and wide-field fluorescence microscopy (Fig. 1). This approach achieves long-term time-lapse monitoring of chick embryonic spinal cord progenitor cells with high spatial and temporal resolution.
This assay may be modified to image a range of embryonic tissues3, 4 In addition to the observation of cellular and sub-cellular behaviors, the development of novel and highly sensitive reporters for gene activity (for example, Notch signaling5) makes this assay a powerful tool with which to understand how signaling regulates cell behavior during embryonic development.

Imaging embryonic tissue in real-time is challenging over long periods of time. Here we present an assay for monitoring cellular and sub-cellular changes in chick spinal cord for long periods with high spatial and temporal resolution. This technique can be adapted for other regions of the nervous system and developing embryo.

The embryonic spinal cord consists of cycling neural progenitor cells that give rise to a large percentage of the neuronal and glial cells of the central ...

Automated Quantification of Synaptic Fluorescence in C. elegans

Synapse strength refers to the amplitude of postsynaptic responses to presynaptic neurotransmitter release events, and has a major impact on overall neural circuit function. Synapse strength critically depends on the abundance of neurotransmitter receptors clustered at synaptic sites on the postsynaptic membrane. Receptor levels are established developmentally, and can be altered by receptor trafficking between surface-localized, subsynaptic, and intracellular pools, representing important mechanisms of synaptic plasticity and neuromodulation. Rigorous methods to quantify synaptically-localized neurotransmitter receptor abundance are essential to study synaptic development and plasticity. Fluorescence microscopy is an optimal approach because it preserves spatial information, distinguishing synaptic from non-synaptic pools, and discriminating among receptor populations localized to different types of synapses. The genetic model organism Caenorhabditis elegans is particularly well suited for these studies due to the small size and relative simplicity of its nervous system, its transparency, and the availability of powerful genetic techniques, allowing examination of native synapses in intact animals.
Here we present a method for quantifying fluorescently-labeled synaptic neurotransmitter receptors in C. elegans. Its key feature is the automated identification and analysis of individual synapses in three dimensions in multi-plane confocal microscope output files, tabulating position, volume, fluorescence intensity, and total fluorescence for each synapse. This approach has two principal advantages over manual analysis of z-plane projections of confocal data. First, because every plane of the confocal data set is included, no data are lost through z-plane projection, typically based on pixel intensity averages or maxima. Second, identification of synapses is automated, but can be inspected by the experimenter as the data analysis proceeds, allowing fast and accurate extraction of data from large numbers of synapses. Hundreds to thousands of synapses per sample can easily be obtained, producing large data sets to maximize statistical power. Considerations for preparing C. elegans for analysis, and performing confocal imaging to minimize variability between animals within treatment groups are also discussed. Although developed to analyze C. elegans postsynaptic receptors, this method is generally useful for any type of synaptically-localized protein, or indeed, any fluorescence signal that is localized to discrete clusters, puncta, or organelles.
The procedure is performed in three steps: 1) preparation of samples, 2) confocal imaging, and 3) image analysis. Steps 1 and 2 are specific to C. elegans, while step 3 is generally applicable to any punctate fluorescence signal in confocal micrographs.

Automated Quantification of Synaptic Fluorescence in C. elegans

The abundance of neurotransmitter receptors clustered at synapses strongly influences synaptic strength. This method quantifies fluorescently-labeled neurotransmitter receptors in three dimensions with single-synapse resolution in C. elegans, allowing hundreds of synapses to be rapidly characterized within a single sample without distortions introduced by z-plane projection.

Synapse strength refers to the amplitude of postsynaptic responses to presynaptic neurotransmitter release events, and has a major impact on overall ...

A Molecular Readout of Long-term Olfactory Adaptation in C. elegans

During sustained stimulation most sensory neurons will adapt their response by decreasing their sensitivity to the signal. The adaptation response helps shape attention and also protects cells from over-stimulation. Adaptation within the olfactory circuit of C. elegans was first described by Colbert and Bargmann1,2. Here, the authors defined parameters of the olfactory adaptation paradigm, which they used to design a genetic screen to isolate mutants defective in their ability to adapt to volatile odors sensed by the Amphid Wing cells type C (AWC) sensory neurons. When wildtype C. elegans animals are exposed to an attractive AWC-sensed odor3 for 30 min they will adapt their responsiveness to the odor and will then ignore the adapting odor in a chemotaxis behavioral assay for ~1 hr. When wildtype C. elegans animals are exposed to an attractive AWC-sensed odor for ~1 hr they will then ignore the adapting odor in a chemotaxis behavioral assay for ~3 hr. These two phases of olfactory adaptation in C. elegans were described as short-term olfactory adaptation (induced after 30 min odor exposure), and long-term olfactory adaptation (induced after 60 min odor exposure). Later work from L'Etoile et al.,4 uncovered a Protein Kinase G (PKG) called EGL-4 that is required for both the short-term and long-term olfactory adaptation in AWC neurons. The EGL-4 protein contains a nuclear localization sequence that is necessary for long-term olfactory adaptation responses but dispensable for short-term olfactory adaptation responses in the AWC4. By tagging EGL-4 with a green fluorescent protein, it was possible to visualize the localization of EGL-4 in the AWC during prolonged odor exposure. Using this fully functional GFP-tagged EGL-4 (GFP::EGL-4) molecule we have been able to develop a molecular readout of long-term olfactory adaptation in the AWC5. Using this molecular readout of olfactory adaptation we have been able to perform both forward and reverse genetic screens to identify mutant animals that exhibit defective subcellular localization patterns of GFP::EGL-4 in the AWC6,7. Here we describe: 1) the construction of GFP::EGL-4 expressing animals; 2) the protocol for cultivation of animals for long-term odor-induced nuclear translocation assays; and 3) the scoring of the long-term odor-induced nuclear translocation event and recovery (re-sensitization) from the nuclear GFP::EGL-4 state.

A Molecular Readout of Long-term Olfactory Adaptation in C. elegans

Here we describe a molecular readout of long-term olfactory adaptation in Caenorhabditis elegans. The Protein Kinase G, EGL-4, is necessary for stable adaptation responses in the primary sensory neuron pair called AWC. During prolonged odor exposure EGL-4 translocates from the cytosol to nucleus of the AWC.

During sustained stimulation most sensory neurons will adapt their response by decreasing their sensitivity to the signal. The adaptation response helps ...