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.&#160;&#160;&#160;1. Assembling the Eyeglasses for Mice<ol><li>Prepare the parts needed for assembling the eyeglasses (Figure 1a). For each mouse, prepare all followings: one head-mounted nylon stick, one higher and one lower titanium frame, two lenses with proper powers according to the purpose of the experiment, one M1.4 size screw with a length of 10 mm, one nut for M1.4 size screw, one plain washer for M1.4 size screw with the thickness of 0.3 mm, and two artificial fingernail tips.&#160;NOTE:&#160;Two kinds of frames exist with different heights. For one mouse, one higher frame and one lower frame are used as a set. Higher frames should be put above the lower ones in order to make the vision fields symmetrical. Frames and lenses are specially designed and manufactured by the authors&#8217; research group. These are available by contacting the corresponding authors of this article. Other parts can be found in retail tool shops.</li><li>Assemble the frame for the right and left eye separately.<ol style='list-style-type:decimal;'><li>Arrange the fingernail tip to face the outside direction to achieve the best protective effect. Adjust the angle between the fingernail tip and the frame to be about 130&#176; to avoid masking the mouse vision field (Figure 1b). Adhere the artificial fingernail tips to the frame using cyanoacrylate adhesive. NOTE:&#160;Fingernail tips can help to protect the lens from being scratched by the mouse. The direction of the fingernail tips must be opposite because the higher frame and the lower frame are used for the right eye and the left eye, respectively.</li><li>Wait for at least 12 h to let the adhesive dry completely, then use a nail clipper to adjust the shape of the fingernail tips to be about 1 cm &#215; 1 cm by cutting and trimming.</li><li>Adhere the lens to the frame using cyanoacrylate adhesive. Put the lens onto the frame by hand and hold the frame horizontally. Inject the cyanoacrylate adhesive from the edge of the lens and let the adhesive spread by surface tension. NOTE:&#160;The adhesive will erode the lens and influence its transparency, so make sure the adhesive only touches the peripheral part of the lens. Use 0 diopters (D) Plano lens as control and minus lens to induce myopia. The effect of different powers of minus lenses (&#8211;10 D to &#8211;50 D) has been described elsewhere4. To maximize the myopia inducement, a &#8211;30 D lens is recommended for inducing myopia. FDM can also be induced with the same device simply by changing the lens into the cap of the 1.5 mL microtube as the diffuser.</li></ol></li><li>Tighten the screw into the nylon stick together with the washer from the flat side of the stick. Prepare the eyeglasses and sticks before the experiment respectively and stock them for further use (Figure 1c). NOTE:&#160;The protocol can be paused here.</li></ol>2. Fixation of the Frame onto the Mouse Cranium.<ol><li>Apply one drop of 0.1% purified sodium hyaluronate eye drop to prevent dryness on each eye. NOTE:&#160;Eye drops on the eye surface will influence the values of refraction and axial length measurements. Do not use the eye drop after the anesthesia until all the measurements are done.</li><li>Put the chin of the anesthetized mouse onto a slope made of clay or anything that can be used as a pillow to make the upfront plane of the cranium be horizontal.</li><li>Sterilize the hair and scalp between ears and eyes using a cotton swab with 70% ethanol.</li><li>Cut the skin between ears and eyes to expose the skull for about 0.8 sq.cm using surgical scissors and tweezers. Use dental etching liquid and a cotton swab to remove the periosteum. Sterilize the surgical scissors and tweezers with 70% ethanol before the surgery of each mouse. NOTE:&#160;Clipping the hair and wearing sterile gloves may be required. Check the provisions of the relevant animal care committee before this procedure. In most cases, the dental etching liquid is one of the attachments in the self-cure dental adhesive system. If the dental etching liquid is not available, use 70% ethanol instead.</li><li>Assemble a set of frames without lens to help fix the stick onto the right position. Put the frames onto the mouse head. Carefully adjust the position of the frames to make sure both eyes are in the middle of the empty frame.</li><li>Use a self-cure dental adhesive system to attach the stick onto the mouse head. Be careful not to let the liquid of the adhere system flow into the mouse eye. NOTE:&#160;The method for using the self-cure dental adhesive system is different between products. Refer to the instruction carefully. CAUTION: Some of the reagents in the dental adhesive system may be toxic.</li><li>Wait for about 5 min and take off the frame and the nut carefully without changing the position of the stick (Figure 2a).</li><li>Inject 0.75 mg/kg atipamezole hydrochloride intraperitoneally to help the mouse to recover from the anesthesia more quickly. Put the mouse into an individual cage until fully recovered. Do not leave the mouse unattended until it has regained sufficient consciousness to maintain sternal recumbency. The protocol can be paused here.</li></ol>3. Initiation of the Myopia Induction and the Maintenance Afterwards<ol><li>Wait for at least 24 h after the surgery to let the mouse recover from anesthesia completely. Grasp the stick and put on the frames with lenses. The inducement begins at this time point (Figure 2b). NOTE: To minimize the discomfort during the recovery from anesthesia and give enough time for the dental adhesive system to coagulate, it is highly recommended to put on the frame after the mice fully recover from anesthesia. The resin cement of the adhesive system will fully cover the cut of the scalp. Therefore, no specific post-surgical treatment is needed to prevent infection and ameliorate post-surgical pain. Right after the first time putting on the frame, mice will be over-conscious of the existence of the lens and scratch it a lot. The gross behavior will be back to normal after a few hours. The mice with lenses can be kept with the same density as the normal mice.</li><li>Remove the frame and clean the lenses and fingernail tips with cotton swabs at least twice a week to maintain the transparency of the lens. NOTE:&#160;It is not necessary to put the mouse under anesthesia for removing and putting on the frame. Providing support for the mice to sit on, rather than having them hang while working with them, could reduce distress.<ol style='list-style-type:decimal;'><li>If an interim measurement is necessary, put the mouse under anesthesia and measure the mouse as previously described. The inducement can be continued after the mouse recovering from the anesthesia.</li></ol></li><li>Clean the cage at least twice a week. NOTE: This helps to maintain lens clarity. Putting a net between the mouse and the cage bottom to filtrate the food scraps may also be helpful.</li><li>Monitor the body weight and gross behavior. Compare them with the same age untouched mice during the whole experimental process. NOTE: Except for some scratching behaviors, no significant change, including the body weight, is found between experiment mice with untreated mice.</li></ol>

<figure class='table' style='width:1071pt;'><table class='ck-table-resized'><colgroup><col style='width:21.38%;'><col style='width:18.67%;'><col style='width:17.83%;'><col style='width:42.12%;'></colgroup><tbody><tr><td style='height:14.5pt;'>screw</td><td>NBK</td><td>SNZS-M1.4-10</td><td>&#160;</td></tr><tr><td style='height:14.5pt;'>washer</td><td>MonotaRO</td><td style='text-align:right;'>42166397</td><td>&#160;</td></tr><tr><td style='height:14.5pt;'>nut</td><td>MonotaRO</td><td style='text-align:right;'>42214243</td><td>&#160;</td></tr><tr><td style='height:14.5pt;'>stick</td><td>DMM Make</td><td>none</td><td>designed by authers and output by the 3D printer rented from DMM Make.</td></tr><tr><td style='height:14.5pt;'>frame</td><td>DMM Make</td><td>none</td><td>designed by authers and output by the 3D printer rented from DMM Make.</td></tr><tr><td style='height:14.5pt;'>lenses</td><td>RAINBOW CONTACT LENS</td><td>none</td><td>customized for mice use by the company</td></tr><tr><td style='height:14.5pt;'>cyanoacrylate glue</td><td>OK MODEL</td><td>MP 20g</td><td>&#160;</td></tr><tr><td style='height:14.5pt;'>dental adhesive resin cement</td><td>SUN MEDICAL</td><td>super bond</td><td>contains the etching liquid used for removing the periosteum of the mouse skull</td></tr><tr><td style='height:14.5pt;'>Tropicamide, Penylephrine Hydrochloride solution</td><td>Santen</td><td>Mydrin-P</td><td>&#160;</td></tr><tr><td style='height:14.5pt;'>midazolam</td><td>Sandoz K.K.</td><td>SANDOZ</td><td>components for the anesthetic</td></tr><tr><td style='height:14.5pt;'>medetomidine</td><td>Orion Corporation</td><td>Domitor</td><td>components for the anesthetic</td></tr><tr><td style='height:14.5pt;'>butorphanol tartrate</td><td>Meiji Seika Pharma</td><td>Vetorphale</td><td>components for the anesthetic</td></tr><tr><td style='height:14.5pt;'>0.1 % purified sodium hyaluronate</td><td>Santen</td><td>Hyalein</td><td>&#160;</td></tr><tr><td style='height:14.5pt;'>atipamezole hydrochloride</td><td>Zenoaq</td><td>antisedan</td><td>&#160;</td></tr></tbody></table></figure>

developing myopia in a mouse model through lens-induced defocusing

<a href='https://appjove.unicartagenaproxy.elogim.com/v/58822/inducement-and-evaluation-of-a-murine-model-of-experimental-myopia'>Source: Jiang, X., et al. Inducement and evaluation of a murine model of experimental myopia. J. Vis. Exp. (2019)</a>This video demonstrates a procedure for inducing myopia in a mouse through the installation of a custom lens frame. The frame is secured to the exposed skull with dental adhesive, and concave lenses are inserted to shift the focal point behind the retina. This setup stimulates eyeball elongation leading to myopia.

<figure class='image image-style-align-center' style='display:table;margin-left:auto;margin-right:auto;'><img style='aspect-ratio:1928/885;' src='https://cloudfront.jove.com/files/ftp_upload/23329/23329_Figure_1_editor_23329.jpg' alt='23329_Figure_1.jpg' /></figure>Figure 1: The design of the skull-mounted eyeglasses. (a) All parts needed for assembling the mouse glasses. (b) An example of the position of the frame and the nail tip for the ...

Developing Myopia in a Mouse Model Through Lens-Induced Defocusing

Source: Jiang, X., et al. Inducement and evaluation of a murine model of experimental myopia. J. Vis. Exp. (2019)This video demonstrates a procedure for ...

Start with an anesthetized mouse with an exposed skull bone.Apply an etching agent to remove the periosteum and create a cleaner surface.Position the eyeglass holder with lens frames so the eyes are centered within the frames.Apply adhesive to the holder and let it set, securing it to the skull.Remove the lens frames to minimize discomfort during recovery.Intraperitoneally inject a recovery agent to recover the mouse.When the mouse is awake, reattach the frame containing concave lenses covering the eyes.These lenses disperse incoming light, causing it to converge behind the retina and resulting in blurred vision.Retinal neurons detect the blur and signal the brain to elongate the eyeball to focus the light on the retina for clear vision.After the lenses are removed, the elongated eyeball causes light to converge in front of the retina, impairing near vision in the mouse and resulting in myopia.

developing-myopia-in-a-mouse-model-through-lens-induced-defocusing

Universidad de Cartagena UDEC

Research

JoVE Encyclopedia of Experiments

Neuroscience

Neuropathology

Neurodegenerative Diseases

17 Views. Source: Jiang, X., et al. Inducement and evaluation of a murine model of experimental myopia. J. Vis. Exp. (2019) This video demonstrates a procedure for inducing myopia in a mouse through the installation of a custom lens frame. The frame is secured to the exposed skull with dental adhesive, and concave lenses are inserted to shift the focal point behind the retina. This setup stimulates eyeball elongation leading to myopia. 

Video: Developing Myopia in a Mouse Model Through Lens-Induced Defocusing - Concept

Scleral Cross-linking Using Riboflavin and Ultraviolet-A Radiation for Prevention of Axial Myopia in a Rabbit Model

Myopic individuals, especially those with severe myopia, are at higher-than-normal risk of cataract, glaucoma, retinal detachment and chorioretinal abnormalities. In addition, pathological myopia is a common irreversible cause of visual impairment and blindness1-3. Our study demonstrates the effect of scleral crosslinking using riboflavin and ultraviolet-A radiation on the development of axial myopia in a rabbit model. The axial length of the eyeball was measured by A-scan ultrasound in New Zealand white rabbits aged 13 days (male and female). The eye then underwent 360&#176; conjunctival peritomy with scleral crosslinking, followed by tarsorrhaphy. Axial elongation was induced in 13 day-old New Zealand rabbits by suturing their right eye eyelids (tarsorrhaphy). The eyes were divided into quadrants, and every quadrant had two scleral irradiation zones, each with an area of 0.2 cm&#178; and a radius of 4 mm. Crosslinking was performed by dropping 0.1% dextran-free riboflavin-5-phosphate onto the irradiation zones 20 sec before ultraviolet-A irradiation and every 20 sec during the 200 sec irradiation time. UVA radiation (370 nm) was applied perpendicular to the sclera at 57 mW/cm&#178; (total UVA light dose, 57 J/cm&#178;). Tarsorrhaphies were removed on day 55, followed by repeated axial length measurements. This study demonstrates that scleral crosslinking with riboflavin and ultraviolet-A radiation effectively prevents occlusion-induced axial elongation in a rabbit model.

We demonstrate the effect of scleral crosslinking with riboflavin and UVA on an axial elongation rabbit eye. Axial elongation was induced in 13 day-old New Zealand rabbits (male and female) by suturing their right eye eyelids (tarsorrhaphy).

Myopic individuals, especially those with severe myopia, are at higher-than-normal risk of cataract, glaucoma, retinal detachment and chorioretinal ...

JoVE Journal

Medicine

A Detailed Protocol for Perspiration Monitoring Using a Novel, Small, Wireless Device

Perspiration monitoring can be utilized for the detection of certain diseases, such as thermoregulation and mental disorders, particularly when the patients are unaware of such disorders or are having difficulty expressing their symptoms. Until now, several devices for perspiration monitoring have been developed; however, such devices tend to have a relatively large exterior, considerable power consumption, and/or less sensitivity.
Recently, we developed a small, wireless device for perspiration monitoring. The device consists of a temperature/relative humidity (T/RH) sensor, battery-driven small data logger, and silica gel as a desiccant in a small cylindrical exterior. The T/RH sensor is placed between the detection windows (through which the water vapor from the skin enters) and the silica gel. The underlying principle of the perspiration monitoring device is based on Fick&#39;s law of diffusion, which means that water vapor flux from the skin to the silica gel (i.e.&#160;transepidermal water loss and perspiration) can be captured by change in humidity at the T/RH sensor. In addition, a baseline subtraction method was adopted to distinguish perspiration and transepidermal water loss.
As shown in the previous report, the developed device can monitor the perspiration at any sites of the body in an easy, wireless manner. However, detailed methods of how to use the device have not been disclosed yet. In this article, therefore, we would like to show the point-by-point tutorials of how to use the device for perspiration monitoring, by showing the sympathetic activity test with the sympathetic skin response monitoring as an example.

Recently, we developed a small wireless device for perspiration monitoring. In this article, we present detailed protocols on how to use the device for perspiration monitoring with an example of the sympathetic activity test.

Perspiration monitoring can be utilized for the detection of certain diseases, such as thermoregulation and mental disorders, particularly when the ...

Second Harmonic Generation Signals in Rabbit Sclera As a Tool for Evaluation of Therapeutic Tissue Cross-linking (TXL) for Myopia

Methods to strengthen tissue by introducing chemical bonds (non-enzymatic cross-linking) into structural proteins (fibrillar collagens) for therapy include photochemical cross-linking and tissue cross-linking (TXL) methods. Such methods for inducing mechanical tissue property changes are being employed to the cornea in corneal thinning (mechanically weakened) disorders such as keratoconus as well as the sclera in progressive myopia, where thinning and weakening of the posterior sclera occurs and likely contributes to axial elongation. The primary target proteins for such tissue strengthening are fibrillar collagens which constitute the great majority of dry weight proteins in the cornea and sclera. Fortuitously, fibrillar collagens are the main source of second harmonic generation signals in the tissue extracellular space. Therefore, modifications of the collagen proteins, such as those induced through cross-linking therapies, could potentially be detected and quantitated through the use of second harmonic generation microscopy (SHGM). Monitoring SHGM signals through the use of a laser scanning microscopy system coupled with an infrared excitation light source is an exciting modern imaging method that is enjoying widespread usage in the biomedical sciences. Thus, the present study was undertaken in order to evaluate the use of SHGM microscopy as a means to measure induced cross-linking effects in ex vivo rabbit sclera, following an injection of a chemical cross-linking agent into the sub-Tenon&#39;s space (sT), an injection approach that is standard practice for causing ocular anesthesia during ophthalmologic clinical procedures. The chemical cross-linking agent, sodium hydroxymethylglycinate (SMG), is from a class of cosmetic preservatives known as formaldehyde releasing agents (FARs). Scleral changes following reaction with SMG resulted in increases in SHG signals and correlated with shifts in thermal denaturation temperature, a standard method for evaluating induced tissue cross-linking effects.

Second Harmonic Generation Signals in Rabbit Sclera As a Tool for Evaluation of Therapeutic Tissue Cross-linking TXL for Myopia

This protocol describes techniques for evaluating chemical cross-linking of the rabbit sclera using&#160;second harmonic generation imaging and differential scanning calorimetry.

Methods to strengthen tissue by introducing chemical bonds (non-enzymatic cross-linking) into structural proteins (fibrillar collagens) for therapy ...

Developing Myopia in a Mouse Model Through Lens-Induced Defocusing

Transcript

Developing Myopia in a Mouse Model Through Lens-Induced Defocusing

Scleral Cross-linking Using Riboflavin and Ultraviolet-A Radiation for Prevention of Axial Myopia in a Rabbit Model

A Detailed Protocol for Perspiration Monitoring Using a Novel, Small, Wireless Device

Second Harmonic Generation Signals in Rabbit Sclera As a Tool for Evaluation of Therapeutic Tissue Cross-linking (TXL) for Myopia