Utilizando el Electrorretinograma para evaluar la función en el Roedor Retina y los efectos protectores de distancia Limb Preacondicionamiento Isquémico
Summary
The electroretinogram (ERG) is an electrical potential generated by the retina in response to light. This paper describes how to use the ERG to assess retinal function, in dark-adapted rats, and how it can be can be used to assess a neuroprotective intervention, in the present case remote ischemic preconditioning.
Abstract
The ERG is the sum of all retinal activity. The ERG is usually recorded from the cornea, which acts as an antenna that collects and sums signals from the retina. The ERG is a sensitive measure of changes in retinal function that are pan-retinal, but is less effective for detecting damage confined to a small area of retina. In the present work we describe how to record the ‘flash’ ERG, which is the potential generated when the retina is exposed to a brief light flash. We describe methods of anaesthesia, mydriasis and corneal management during recording; how to keep the retina dark adapted; electrode materials and placement; the range and calibration of stimulus energy; recording parameters and the extraction of data. We also describe a method of inducing ischemia in one limb, and how to use the ERG to assess the effects of this remote-from-the-retina ischemia on retinal function after light damage. A two-flash protocol is described which allows isolation of the cone-driven component of the dark-adapted ERG, and thereby the separation of the rod and cone components. Because it can be recorded with techniques that are minimally invasive, the ERG has been widely used in studies of the physiology, pharmacology and toxicology of the retina. We describe one example of this usefulness, in which the ERG is used to assess the function of the light-damaged retina, with and without a neuroprotective intervention; preconditioning by remote ischemia.
Introduction
El ERG es un potencial eléctrico generado por la retina en respuesta a la luz, y grabado de la superficie corneal del ojo. Cuando las condiciones de grabación se manejan con cuidado, el ERG se puede utilizar en una variedad de maneras para evaluar la función de la retina. Aquí describimos cómo grabar el 'Flash ERG', el potencial generado cuando la retina se expone a un breve, flash brillante presentado en un fondo Ganzfeld. El Ganzfeld dispersa la luz de forma homogénea y el flash de la luz alcanza toda la retina aproximadamente uniforme. Si la retina está oscuro adaptado antes de grabar, y la oscuridad, la adaptación se mantiene como el animal se prepara para la grabación, el ERG obtenido se genera por ambas fotorreceptores conos y bastones.
El oscuro-adaptado de flash ERG tiene una forma de onda característica, que ha sido analizada de dos maneras. En primer lugar, principios y finales de los componentes de la forma de onda ERG se han distinguido, y en relación con la secuencia de la neuronaal activación en la retina. El primer componente es una latencia corta en sentido negativo potencial, la onda a (Figura 1). Esto es seguido por un potencial positivo va, llamada la onda b. La fase ascendente de la onda b muestra oscilaciones, que se consideran un componente separado (potenciales oscilatorios o PO). La onda a se considera que está generada por fotorreceptores, la onda b por las células de la capa nuclear interna, y los PO por las células amacrinas 1.
Sobre la base de la fuerza del estímulo, las respuestas a destellos muy tenues denominan el umbral de respuesta escotópica son posibles. El umbral de respuesta escotópica se entiende que ser generado a partir de las células ganglionares de la retina 2-4. En segundo lugar, el flash ERG se puede separar por adaptación a la luz, o por un protocolo de dos flash descritos a continuación, en componentes de bastón y cono impulsada. En condiciones fotópicas, la onda a es no detectable en ratas, porque la población de cono es baja, pero PO y una onda b sonclaro 5. En los primates, cuyas retinas tienen poblaciones cono superior, tanto de varilla y las vías de cono generan una detectable una onda 6.
Dos medidas útiles a menudo extraídos de la ERG flash son las amplitudes de la a- y b-ondas, medidos como en la Figura 1, con respuestas de flash típicos mostrados en la Figura 2. Cuando la población fotorreceptor se reduce, por ejemplo por la exposición a damagingly brillante luz, se reducen todos los componentes del ERG. Intervenciones neuroprotectoras, como a distancia precondicionamiento isquémico (RIP), pueden ser validados por la preservación de las amplitudes de la a- y b-ondas (Figura 3). En resumen, el análisis de la ERG permite comparaciones entre sana, ligera y de la retina dañada neuroprotected.
Protocol
Representative Results
Discussion
El método ERG flash adaptada a la oscuridad descrito anteriormente es un método fiable para evaluar la función de la retina en ratas. Tanto la onda ay la onda b se redujeron en un daño de la luz. Remoto precondicionamiento isquémico mitigado reducciones inducidas daños-luz en la onda ay la onda b. Esta preservación de la función retiniana sugiere que el precondicionamiento isquémico remoto ha inducido neuroprotección, asemejándose a otras formas de acondicionamiento previo de protección, tales como hipoxia, …
Disclosures
The authors have nothing to disclose.
Acknowledgements
Los autores agradecen la asistencia de la señora Sharon Spana en el monitoreo de roedores, la manipulación y la experimentación. Apoyo financiero de doctorado ha sido proporcionada por la Universidad de Sydney y el Centro Australiano de Investigación de Excelencia en la visión.
Materials
| PC computer | |||
| Powerlab, 4 channel acquistion hardware | AD Instruments | PL 35044 | Acquistion of ERG |
| Animal Bio Amp | AD Instruments | FE 136 | Amplifier for ERG |
| Lab chart | AD Instruments | Signal collection software | |
| Ganzfield | Photometric solutions | FS-250A | Light stimulus |
| Ganzfield operating system | Photometric solutions | ||
| Research Radiometer | International light technologies | ILT-1700 | calibrate light series |
| Lux meter | LX-1010B | check red light illumanation | |
| Excel | microsoft | ||
| Lead wires | AD Instruments | Connect postive, negative ground electrodes to amplifier | |
| Lead wires -aligator | AD Instruments | ground ganzfield and acquistion hardware to computer | |
| Platinum wire 95% | A&E metals | postive electrode | |
| Mouth electrode Ag/AgCl Pellet | SDR | E205 | negative electode |
| 26 gauge needle | BD | ground electode | |
| Water pump | |||
| Water bath | |||
| Tubing | |||
| Homeothermic blanket system with flexible probe | Harvard Appartus | 507222F | |
| Atropine 1% w/v | Bausch & Lomb | topical mydriasis | |
| Proxmethycaine 0.5% w/v | Bausch & Lomb | topical anaesthetic | |
| Visco tears eye drops | Novartis | carbomer polymer | |
| Thread | retract eye lid | ||
| Tweezers | |||
| Reusable adhesive | Blu tac | Dim red headlamp. Affix electrodes | |
| Absorbent bedding | |||
| Ketamil – ketamine 100 mg/ml – 50 ml | Troy Laboratories Pty Ltd | dissociative | |
| Xylium – Xylazine 100 mg/ml – 50 ml | Troy Laboratories Pty Ltd | muscle relaxant | |
| Scale |
References
- Arden, G. B., Heckenlively, J. . Principles and practice of clinical electrophysiology of vision. , 139-183 (2006).
- Bui, B. V., Fortune, B. Ganglion cell contributions to the rat full-field electroretinogram. Journal of Physiology-London. 555 (1), 153-173 (2004).
- Fortune, B., et al. Selective ganglion cell functional loss in rats with experimental glaucoma. Investigative Ophthalmology & Visual Science. 45 (6), 1854-1862 (2004).
- Alarcon-Martinez, L., et al. Short and long term axotomy-induced ERG changes in albino and pigmented rats. Molecular Vision. 15 (254-255), 2373-2383 (2009).
- Lyubarsky, A. L., et al. Functionally rodless mice: transgenic models for the investigation of cone function in retinal disease and therapy. Vision Research. 42 (4), 401-415 (2002).
- Bush, R. A., Sieving, P. A. . A PROXIMAL RETINAL COMPONENT IN THE PRIMATE PHOTOPIC ERG A-WAVE. Investigative Ophthalmology & Visual Science. 35 (2), 635-645 (1994).
- Liu, K., et al. Development of the electroretinographic oscillatory potentials in normal and ROP rats. Investigative Ophthalmology & Visual Science. 47 (12), 5447-5452 (2006).
- Casson, R. J., Wood, J. P. M., Melena, J., Chidlow, G., Osborne, N. N. The effect of ischemic preconditioning on light-induced photoreceptor injury. Investigative Ophthalmology & Visual Science. 44 (3), 1348-1354 (2003).
- Lawson, E. C., et al. Aerobic Exercise Protects Retinal Function and Structure from Light-Induced Retinal Degeneration. Journal of Neuroscience. 34 (7), 2406-2412 (2014).
- Grimm, C., et al. HIF-1-induced erythropoietin in the hypoxic retina protects against light-induced retinal degeneration. Nature Medicine. 8 (7), 718-724 (2002).
- Weymouth, A. E., Vingrys, A. J. Rodent electroretinography: Methods for extraction and interpretation of rod and cone responses. Progress in Retinal and Eye Research. 27 (1), 1-44 (2008).
- Bayer, A. U., Cook, P., Brodie, S. E., Maag, K. P., Mittag, T. Evaluation of different recording parameters to establish a standard for flash electroretinography in rodents. Vision Research. 41 (17), 2173-2185 (2001).
- Pugh, E. N., Lamb, T. D. AMPLIFICATION AND KINETICS OF THE ACTIVATION STEPS IN PHOTOTRANSDUCTION. Biochimica Et Biophysica Acta. 1141 (2-3), 111-149 (1993).
- Breton, M. E., Schueller, A. W., Lamb, T. D., Pugh, E. N. ANALYSIS OF ERG A-WAVE AMPLIFICATION AND KINETICS IN TERMS OF THE G-PROTEIN CASCADE OF PHOTOTRANSDUCTION. Investigative Ophthalmology & Visual Science. 35 (1), 295-309 (1994).
- Mizota, A., Adachi-Usami, E. Effect of body temperature on electroretinogram of mice. Investigative Ophthalmology & Visual Science. 43 (12), 3754-3757 (2002).
- Szabo-Salfay, O., et al. The electroretinogram and visual evoked potential of freely moving rats. Brain Research Bulletin. 56 (1), 7-14 (2001).
- Charng, J., et al. Conscious Wireless Electroretinogram and Visual Evoked Potentials in Rats. Plos One. 8 (9), (2013).
- Galambos, R., Juhasz, G., Kekesi, A. K., Nyitrai, G., Szilagyi, N. NATURAL SLEEP MODIFIES THE RAT ELECTRORETINOGRAM. Proceedings of the National Academy of Sciences of the United States of America. 91 (11), 5153-5157 (1994).
- Galambos, R., Szabo-Salfay, O., Szatmar, E., Szilagyi, N., Juhasz, G. Sleep modifies retinal ganglion cell responses in the normal rat. Proceedings of the National Academy of Sciences of the United States of America. 98 (4), 2083-2088 (2001).
- Guarino, I., Loizzo, S., Lopez, L., Fadda, A., Loizzo, A. A chronic implant to record electroretinogram, visual evoked potentials and oscillatory potentials in awake, freely moving rats for pharmacological studies. Neural Plasticity. 11 (3-4), 241-250 (2004).
- Huang, J. C., Salt, T. E., Voaden, M. J., Marshall, J. NON-COMPETITIVE NMDA-RECEPTOR ANTAGONISTS AND ANOXIC DEGENERATION OF THE ERG B-WAVE IN-VITRO. Eye (London). 5 (4), 476-480 (1991).
- Sasovetz, D. . KETAMINE HYDROCHLORIDE – EFFECTIVE GENERAL ANESTHETIC FOR USE IN ELECTRORETINOGRAPHY. Annals of Ophthalmology. 10 (11), 1510-1514 (1978).
- Mojumder, D. K., Wensel, T. G. Topical Mydriatics Affect Light-Evoked Retinal Responses in Anesthetized Mice). Investigative Ophthalmology & Visual Science. 51 (1), 567-576 (2010).
- Fraunfel, F. t., Burns, R. P. ACUTE REVERSIBLE LENS OPACITY – CAUSED BY DRUGS, COLD, ANOXIA, ASPHYXIA, STRESS, DEATH AND DEHYDRATION. Experimental Eye Research. 10 (1), 19 (1970).
- Calderone, L., Grimes, P., Shalev, M. ACUTE REVERSIBLE CATARACT INDUCED BY XYLAZINE AND BY KETAMINE-XYLAZINE ANESTHESIA IN RATS AND MICE. Experimental Eye Research. 42 (4), 331-337 (1986).
- Behn, D., et al. Dark adaptation is faster in pigmented than albino rats. Documenta Ophthalmologica. 106 (2), 153-159 (2003).
- Sugawara, T., Sieving, P. A., Bush, R. A. Quantitative relationship of the scotopic and photopic ERG to photoreceptor cell loss in light damaged rats. Experimental Eye Research. 70 (5), 693-705 (2000).
- Machida, S., et al. P23H rhodopsin transgenic rat: Correlation of retinal function with histopathology. Investigative Ophthalmology & Visual Science. 41 (10), 3200-3209 (2000).
- Brandli, A., Stone, J. Remote Ischemia Influences the Responsiveness of the Retina. Observations in the Rat. Investigative Ophthalmology & Visual Science. 55 (4), 2088-2096 (2014).
- Maccarone, R., Di Marco, S., Bisti, S. Saffron supplement maintains morphology and function after exposure to damaging light in mammalian retina. Investigative Ophthalmology & Visual Science. 49 (3), 1254-1261 (2008).
- Hood, D. C., Birch, D. G. Assessing abnormal rod photoreceptor activity with the a-wave of the electroretinogram: Applications and methods. Documenta Ophthalmologica. 92 (4), 253-267 (1996).
- Robson, J. G., Frishman, L. J. The rod-driven a-wave of the dark-adapted mammalian electroretinogram. Progress in Retinal and Eye Research. 39, 1-22 (2014).
- Hood, D. C., Birch, D. G. A COMPUTATIONAL MODEL OF THE AMPLITUDE AND IMPLICIT TIME OF THE B-WAVE OF THE HUMAN ERG. Visual Neuroscience. 8 (2), 107-126 (1992).
- Wachtmeister, L. Oscillatory potentials in the retina: what do they reveal. Progress in Retinal and Eye Research. 17 (4), 485-521 (1998).
