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http://dx.doi.org/10.3807/JOSK.2015.19.2.169

The Optical Measurement and Quantitative Analysis of Algesia in Spodoptera litura Larva  

Chen, Ying-Yun (Department of Optics and Photonics, National Central University)
Chang, Rong-Seng (Department of Optics and Photonics, National Central University)
Tsai, Mi-Yin (Department of Optics and Photonics, National Central University)
Chen, Der-Chin (Department of Electrical Engineering, Feng Chia University)
Publication Information
Journal of the Optical Society of Korea / v.19, no.2, 2015 , pp. 169-174 More about this Journal
Abstract
Muscle vibration measurement has long been an unique scientific study, in general, and the direct reaction of animals to feel pain (algesia), either from vascular or muscle contraction, is a complex perceptual experience. Thus this paper proposes a way to measure animal algesia quantitatively, by measuring the changes in muscle vibration due to a pinprick on the surface of the skin of a Spodoptera litura larva. Using the laser optical triangulation measurement principle, along with a CMOS image sensor, linear laser, software analysis, and other tools, we quantify the subtle object point displacement, with a precision of up to $10{\mu}m$, for our chosen Spodoptera litura larva animal model, in which it is not easy to identify the tiny changes in muscle contraction dynamics with the naked eye. We inject different concentrations of formalin reagent (empty needle, 12% formalin, and 37% formalin) to obtain a variety of different muscle vibration frequencies as the experimental results. Because of the high concentrations of reagent applied, we see a high frequency shift of muscle vibration, which can be presented as pain indices, so that the algesia can be quantified.
Keywords
Algesia; Laser optical triangulation; Formalin;
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1 A. E. Desjardins, B. H. W. Hendriks, M. Voort, R. Nachabe, W. Bierhoff, G. Braun, D. Babic, J. P. Rathmell, S. Holmin, M. Soderman, and B. Holmstrom, "Epidural needle with embedded optical fibers for spectroscopic differentiation of tissue: Ex vivo feasibility study," Biomedical Optics Express 2, 1452-1461 (2011).   DOI
2 K. Hargreaves, R. Dubner, F. Brown, C. Flores, and J. Joris, "A new and sensitive method for measuring thermal nociception in cutaneous hyperalgesia," Pain 32, 77-88 (1988).   DOI   ScienceOn
3 S. T. Kooa, Y. I. Parka, K. S. Lima, K. Chunga, and J. M. Chunga, "Acupuncture analgesia in a new rat model of ankle sprain pain," Pain 99, 423-431 (2002).   DOI   ScienceOn
4 J. H. Rosland, "The formalin test in mice: The influence of ambient temperature," Pain 45, 211-216 (1991).   DOI   ScienceOn
5 S. Candelletti and S. Ferri, "Antinociceptive profile of intracerebrovascular salmon calcitonin and calcitonin-gene related peptide in the mouse formalin test," Neuropeptides 17, 93-98 (1990).   DOI   ScienceOn
6 K. Shima, H. Nakahama, M. Yamanoto, K. Aya, and M. Inase, "Effects of morphine on two types of nucleus raphe dorsalis neurons in awake cats," Pain 29, 375-386 (1987).   DOI   ScienceOn
7 M. Alreja, P. Mutalik, U. Nayar, and S. K. Manchanda, "The formalin test: A tonic pain model in the primate." Pain 20, 97-105 (1984).   DOI   ScienceOn
8 G. Carli, F. Farabollini, and G. Fontani, "Effects of pain, morphine and naloxone on the duration of animal hypnosis," Behav. Brain Res. 2, 373-385 (1981).   DOI   ScienceOn
9 H. Takahashi, K. Shibata, T. Ohkubo, and S. Naruse, "Formalin induced minor tremor response as an indicator of pain," Nippon Yakurigaku Zasshi 84, 353-362 (1984).   DOI
10 E. H. Hofmeister, J. King, M. R. Read, and S. C. Budsberg, "Sample size and statistical power in the small-animal analgesia literature," Journal of Small Animal Practice 48, 76-79 (2007).   DOI   ScienceOn
11 A. Tjolsen and K. Hole, "Animal models of analgesia," The Pharmacology of Pain 130, 1-20 (1997).   DOI
12 L. F. Vendruscolo and R. N. Takahashi, "Synergistic interaction between mazindol, an anorectic drug, and swim-stress on analgesic responses in the formalin test in mice," Neurosci. Lett. 355, 13-16 (2004).   DOI   ScienceOn
13 S. Louisa, "Considerations for prospective studies in animal analgesia," Veterinary Anaesthesia and Analgesia 37, 303-305 (2010).   DOI   ScienceOn
14 I. Hiroki, I. L. Yasutomo, and S. Emiko, "Stress-induced hyperalgesia: Animal models and putative mechanisms," Frontiers in Bioscience 11, 2179-2192 (2006).   DOI
15 J. S. Mogil, "Animal models of pain: progress and challenges," Nature Reviews Neuroscience 10, 283-294 (2009).
16 F. V. Abbott, K. B. J. Franklin, R. J. Ludwick, and R. Melzack, "Apparent lack of tolerance in the formalin test suggests different mechanisms for morphine analgesia in different types of pain," Pharmacology Biochemistry and Behavior 15, 637-640 (1981).   DOI   ScienceOn
17 M. S. Fanselow, "Shock-induced analgesia on the formalin test: Effects of shock severity, naloxone, hypophysectomy, and associative variables," Behavioral Neuroscience 98, 79-95 (1984).   DOI   ScienceOn
18 T. Pelissier, H. Saavedra, D. Bustamante, and C. Panicle, "Further studies on the understanding of Octodon degus natural resistance to morphine; A comparative study with the Wistar rat," Comp. Biochem. Physiol. 192, 319-322 (1989).
19 T. I. Kanui, K. Hole, and J. O. Miaron, "Nociception in crocodiles: Capsaicin instillation in formalin and hot plate tests," Zool. Sci. 7, 537-540 (1990).
20 R. A. Hughes and J. Sulka, "Morphine hyperalgesic effects on the formalin test in domestic fowl," Pharmacol. Biochem. Behav. 38, 247-251 (1991).   DOI   ScienceOn
21 A. S. Oyadeyi, F. O. Ajao, A. O. Afolabi, U. S. Udoh, and O. M. Azeez, "The formalin test in African toad (Bufo regularis) - A novel pain model in amphibians," American-Eurasian Journal of Scientific Research 2, 24-28 (2007).
22 R. S. Chang, J. H. Chiu, F. P. Chen, J. C. Chen, and J. L. Yang, "A Parkinson's disease measurement system using laser lines and a CMOS image sensor," Sensors 11, 1462-1475 (2011).
23 J. H. Wu, R. S. Chang, and J. A. Jiang, "A novel pulse measurement system by using laser triangulation and a CMOS image sensor," Sensors 7, 3366-3385 (2007).   DOI