Design and Testing of an Underwater Microscope with Variable Objective Lens for the Study of Benthic Communities

Kamran Shahani; Hong Song; Syed Raza Mehdi; Awakash Sharma; Ghulam Tunio; Junaidullah Qureshi; Noor Kalhoro; Nooruddin Khaskheli

doi:10.1007/s11804-020-00185-9

Journal of Marine Science and Application ›› 2021, Vol. 20 ›› Issue (1) : 170 -178. DOI: 10.1007/s11804-020-00185-9

Research Article

Design and Testing of an Underwater Microscope with Variable Objective Lens for the Study of Benthic Communities

Author information +

History +

PDF

Abstract

Monitoring the ecology and physiology of corals, sediments, planktons, and microplastic at a suitable spatial resolution is of great importance in oceanic scientific research. To meet this requirement, an underwater microscope with an electrically controlled variable lens was designed and tested. The captured microscopic images of corals, sediments, planktons, and microplastic revealed their physical, biological, and morphological characteristics. Further studies of the images also revealed the growth, degradation, and bleaching patterns of corals; the presence of plankton communities; and the types of microplastics. The imaging performance is majorly influenced by the choice of lenses, camera selection, and lighting method. Image dehazing, global saturation masks, and image histograms were used to extract the image features. Fundamental experimental proof was obtained with micro-scale images of corals, sediments, planktons, and microplastic at different magnifications. The designed underwater microscope can provide relevant new insights into the observation and detection of the future conditions of aquatic ecosystems.

Keywords

Underwater microscope / Optics / Corals / Sediments / Planktons / Microplastic / Arduino

Cite this article

Download citation ▾

Kamran Shahani, Hong Song, Syed Raza Mehdi, Awakash Sharma, Ghulam Tunio, Junaidullah Qureshi, Noor Kalhoro, Nooruddin Khaskheli. Design and Testing of an Underwater Microscope with Variable Objective Lens for the Study of Benthic Communities. Journal of Marine Science and Application, 2021, 20(1): 170-178 DOI:10.1007/s11804-020-00185-9

登录浏览全文

4963

注册一个新账户忘记密码

References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	Akiba T, Kakui Y. Design and testing of an underwater microscope and image processing system for the study of zooplankton distribution. IEEE J Ocean Eng, 2000, 25(1): 97-104

[2]	Arora M, Sahoo D. Concepts and techniques for the study of algae. The Algae World, 2015, Dordrecht: Springer

[3]	Ateweberhan M, Feary DA, Feshavmurthy S, Chen A, Schleyer MH, Sheppard CR. Climate change impacts on coral reefs: synergies with local effects, possibilities for acclimation, and management implications. Mar Pollut Bull, 2013, 74(2): 526-539

[4]	Blaschko MB, Holness G, Mattar MA, Lisin D, Utgoff PE, Hanson AR, Schultz H, Riseman EM, Sieracki ME, Balch WM, Tupper B (2005) Automatic in situ identification of plankton. 7th IEEE Workshop on Applications of Computer Vision 1, 79-86. https://doi.org/10.1109/ACVMOT.2005.29

[5]	Dai J, Yu Z, Zheng H, Zheng B, Wang N (2017) A hybrid convolutional neural network for plankton classification. 2016 Asian Conference on Vision, 102-114. https://doi.org/10.1007/978-3-319-54526-4_8

[6]	Delgadillo-Nuño MA, Liñán-Cabello MA, Reyes-Gómez J, Soriano-Santiago O. Response to pH stress in the reef-building coral Pocillopora capitata (Anthozoa: Scleractinia). Rev Biol Mar Oceanogr, 2014, 49(3): 449-459

[7]	Gao S, Collins MB. Analysis of grain size trends, for defining sediment transport pathways in marine environments. J Coast Res, 1994, 10(1): 70-78 https://www.jstor.org/stable/4298194

[8]	Grottoli AG, Martins PD, Wilkins MJ, Johnston MD, Warner ME, Cai WJ, Melman TF, Hoadley KD, Pettay DT, Levas SJ. Coral physiology and microbiome dynamics under combined warming and ocean acidification. PLoS One, 2018, 13(1): e0191156

[9]	Huggett MJ, Apprill AJ. Coral microbiome database: integration of sequences reveals high diversity and relatedness of coral-associated microbes. Environ Microbiol Rep, 2018, 11(3): 372-385

[10]	Hughes TP, Anderson KD, Connolly SR, Heron SF, Kerry JT, Lough JM, Baird AH, Baum JK, Berumen ML, Bridge TC. Spatial and temporal patterns of mass bleaching of corals in the Anthropocene. Science, 2018, 359(6371): 80-83

[11]	Jafarabadi AR, Bakhtiari AR, Hedouin L, Toosi AS, Cappello T. Spatio-temporal variability, distribution and sources of n-alkanes and polycyclic aromatic hydrocarbons in reef surface sediments of Kharg and Lark coral reefs, Persian Gulf, Iran. Ecotoxicol Environ Saf, 2018, 163: 307-322

[12]	Jaffe JS, Moore KD, Mclean J, Strand MP. Underwater optical imaging: status and prospects. Oceanography, 2001, 14(3): 66-76

[13]	Kennelly SJ, Underwood AJ. Underwater microscopic sampling of a sublittoral kelp community. J Exp Mar Biol Ecol, 1984, 76(1): 67-78

[14]	Li J, Qu X, Su L, Zhang W, Yang D, Kolandhasamy P, Li D, Shi H. Microplastics in mussels along the coastal waters of China. Environ Pollut, 2016, 214: 177-184

[15]	Massé A, Domart-coulon I, Golubic S, Duché D, Tribollet A. Early skeletal colonization of the coral holobiont by the microboring Ulvophyceae Ostreobium sp. Sci Rep, 2018, 8(1): 1-11

[16]	Mccook L, Jompa J, Diaz-pulido G. Competition between corals and algae on coral reefs: a review of evidence and mechanisms. Coral Reefs, 2001, 19(4): 400-417

[17]	Mullen AD, Treibitz T, Roberts PL, Kelly EL, Horwitz R, Smith JE, Jaffe JS. Underwater microscopy for in situ studies of benthic ecosystems. Nat Commun, 2016, 7(1): 1-9

[18]	Neushul M. Underwater microscopy with an encased incident-light dipping-cone microscope. J Microsc, 1972, 95(3): 421-424

[19]	Peng G, Zhu B, Yang D, Su L, Shi H, Li D. Microplastics in Sediments of the Changjiang Estuary, China. Environ Pollut, 2017, 225: 283-290

[20]	Rabbani A, Ayatollahi S. Comparing three image processing algorithms to estimate the grain-size distribution of porous rocks from binary 2D images and sensitivity analysis of the grain overlapping degree. Spec Top Rev Porous Media, 2015, 6(1): 71-89

[21]	Rubin DM. A simple autocorrelation algorithm for determining grain size from digital images of sediment. J Sediment Res, 2004, 74(1): 160-165

[22]	Rubin DM, Chezar H, Harney JN, Topping DJ, Melis TS, Sherwood CR. Underwater microscope for measuring spatial and temporal changes in bed-sediment grain size. Sediment Geol, 2007, 202(3): 402-408

[23]	Schutte VG, Selig ER, Bruno JF. Regional spatio-temporal trends in Caribbean coral reef benthic communities. Mar Ecol Prog Ser, 2010, 402(1): 115-122

[24]	Serrano XM, Miller MW, Hendee JC, Jensen BA, Gapayao JZ, Pasparakis C, Grosell M, Baker AC. Effects of thermal stress and nitrate enrichment on the larval performance of two Caribbean reef corals. Coral Reefs, 2018, 37(1): 173-182

[25]	Shelyakin PV, Garushyants SK, Nikitin MA, Mudrova SV, Berumen M, Speksnijder AG, Hoeksema BW, Fontaneto D, Gelfand MS, Ivanenko VN. Microbiomes of gall-inducing copepod crustaceans from the corals Stylophora pistillata (Scleractinia) and Gorgonia ventalina (Alcyonacea). Sci Rep, 2018, 8(1): 1-10

[26]	Talapatra S, Hong J, Mcfarland M, Nayak AR, Zhang C, Katz J, Sullivan J, Twardowski M, Rines J, Donaghay PJ. Characterization of biophysical interactions in the water column using in situ digital holography. Mar Ecol Prog Ser, 2013, 473: 29-51

[27]	Tucker ME (2009) Sedimentary petrology: an introduction to the origin of sedimentary rocks. John Wiley & Sons

[28]	Ullah E, Nawaz R, Iqbal J (2013) Single image haze removal using improved dark channel prior. 5th International Conference on Modelling, Identification and Control (ICMIC), IEEE, Cairo, 245-248. http://ieeexplore.ieee.org/stamp/stamp.jsp?tp=&arnumber=6642199&isnumber=6642159

[29]	Vaasma T. Grain-size analysis of lacustrine sediments: a comparison of pre-treatment methods. Estonian J Ecol, 2008, 57(4): 231-243

[30]	Wentworth CK. A scale of grade and class terms for clastic sediments. J Geol, 1922, 30(5): 377-392

[31]	Zheng H, Wang R, Yu Z, Wang N, Gu Z, Zheng B. Automatic plankton image classification combining multiple view features via multiple kernel learning. BMC Bioinf, 2017, 18(16): 570 1-18