References
Acker, K.A. and Risk, M.J. 1985. Substrate Destruction and Sediment Production by the Boring Sponge
Cliona Caribbaea on Grand Cayman Island. Journal of Sedimentary Research, 55: 705-711
Alwany, M.A., Thaler, E. and Stachowitsch, M. 2009. Parrotfish bioerosion on Egyptain Red Sea Reef.
Journal of Experimental Marine Biology and Ecology, 371:170-176
Appana S.D. and Vuki V.C. 2006. Foraging behaviour, substrate preference and influence of Echinometra
sp. A on the carbonate budget of Nukubuco Reef, Fiji Islands. Micronesia 38(2): 191-205
Bak, R.P.M. (1976). The growth of coral colonies and the importance of crustose coralline algae and
burrowing sponges in relation with carbonate accumulation. Netherlands Journal of Sea Research 10:
285–337
Bak RPM (1990) Patterns of echinoid bioerosion in two PaciWc coral reef lagoons. Mar Ecol Prog Ser
66:267–272
Bak, R.P.M. 1994. Sea urchin bioerosion on coral reefs: place in the carbonate budget and relevant
variables. Coral Reefs, 13: 99-103
Bell, J.D., Craik, G.J.S, Pollard, D.A. and Russell, B.C. (1985) Estimating length frequency distributions of
large reef fish underwater. Coral Reefs 4: 41-44.
Bellwood, D.R. 1995. Direct estimate of bioerosion by two parrotfish species, Chlorurus gibbus and C.
sordidus, on the Great Barrier Reef, Australia. Marine Biology, 121: 419 – 429
Bellwood D.R. and Choat J.H. 1990. A functional analysis of grazing in parrotfishes (family Scaridae): the
ecological implications. Environmental Biology of Fishes, 28:189-214
Blanchon, P., and Jones B. 1997. Hurricane control on shelf-edge-reef architecture around Grand Cayman:
Sedimentology, 44: 479-506.
Bohnsack, J.A. and Bannerot, S.P. 1986. A Stationary Visual Census Technique for Quantitatively
Assessing Community Structure of Coral Reef Fishes. NOAA Tech Rep NMFS 41.
Bosence, D.W.J., 1984. Construction and preservation of two modern coralline algal reefs, St. Croix,
Caribbean. Palaeontology, 27: 549–574.
Bromley, R.G., 1994, The Palaeoecology of Bioerosion, in Donovan, S.K., ed., The Palaeobiology of Trace
Fossils. Chichester, John Wiley & Sons, p. 134-154.
Brown-Saracino J., Peckol, P., Curran, H.A. and Robbart, M.L. 2007. Spatial variation in sea urchins, fish
predators, and bioerosion rates on coral reefs of Belize. Coral Reefs 26: 71-78
Bruggemann JH, van Oppen MJH, Breeman AM (1994a) Foraging by the stoplight parrotfish Sparisoma
viride. I. Food selection in different, socially determined habitats. Mar Ecol Prog Ser 106:41-55
Bruggemann JH, Begeman J, Bosma EM, Verburg P, Breeman AM (1994b) Foraging by the stoplight
parrotfish Sparisoma viride. II. Intake and assimilation of food, protein and energy. Mar Ecol Prog Ser
106:57-71
Bruggemann JH, Kuyper MWM, Breeman AM (1994c) Comparative analysis of foraging and habitat use by
the sympatric Caribbean parrotfish Scarus vetula and Sparisoma viride (Scaridae). Mar Ecol Prog Ser 112:
51-66
Bruggemann, J.H., Van Kessel, A.M., Van Rooij, J.M. and Breeman, A.M. 1996. Bioerosion and sediment
ingestion by the Caribbean parrotfish Scarus vetula and Sparisoma viride: implications of fish size, feeding
mode and habitat use. Marine Ecology Progress Series, 134: 59-71
Cabioch, G., Camoin, G., Webb, G.E., Le Cornec, F., Molina, M.G., Pierre, C. and Joachimski, M.M. 2006.
Contribution of microbialites to the development of coral reefs during the last deglacial period: case study
from Vanuatu (Sout-West Pacific). Sedimentary Geology 185: 297-318
Camoin, G., Cabioch, G., Eisenhauer, A., Braga, J. C., Hamelin, B., and Lericolais, G., 2006.
Environmental significance of microbialites in reef environments during the last deglaciation. Sedimentary
Geology, 185, 277–295
Carreiro-Silva M, McClanahan TR (2001) Echinoid bioerosion and herbivory on Kenyan coral reefs: the role
of protection from fishing. J Exp Mar Biol Ecol 262:133–153
Chave, K.E., Smith, S.V. and Roy, K.J. 1972. Carbonate production by coral reefs. Marine Geology, 12:
123-140
Chazottes, V., Le Campion-Alsumard, T. and Peyrot-Clausade, M. 1995. Bioerosion rates on coral reefs:
interactions between macroborers, microborers and grazers (Moorea, French Polynesia).
Palaeogeography, Palaeoclimatology, Palaeoecology 113: 189-198
Chazottes, V., Le Campion-Alsumard, T., Peyrot-Clausade, M. and Cuet, P. 2002. The effects of
eutrophication-related alterations to coral reef communities on agents and rates of bioerosion (Reunion
Island, Indian Ocean). Coral Reefs 21: 375-390
Conand, C., Chabanet, P., Cuet, P. and Letourneur, Y. 1997 The carbonate budget of a fringing reef in La
Reunion Island (Indian Ocean): sea-urchin and fish bioerosion and net calcification. Proc. 8th Int. Coral
Reef Symp., 1: 953–958.
Done, T. J., 1992. Phase shifts in coral reef communities and their ecological significance. Hydrobiologia,
247: 121–132
Done, T. J., 1999. Coral community adaptability to environmental change at the scales of regions, reefs
and reef zones. American Zoologist, 39: 66–79
Downing, N., El-Zahr, C. R. (1987). Gut evacuation and filling rates in the rock-boring sea urchin,
Echinometra mathaei. Bull. Mar. Sci. 41: 579-584
Eakin C.M. 1996. Where have all the carbonates gone? A model comparison of calcium carbonate budgets
before and after the 1982-1983 El Nino at Uva Island in the eastern Pacific. Coral Reefs 15:109-119
Eakin C.M. 2001. A tale of two ENSO events: Carbonate budgets and the influence of two warming
disturbances and intervening variability, Uva Island, Panama. Bulletin of Marine Science 69(1): 171-186
Edinger, E.N., Limmon, G.V., Jompa, J., Widjatmoko, W., Heikoop, J.M. and Risk, M.J. 2000. Normal coral
reef growth rates on dying reefs: Are coral growth rates good indicators of reef health? Marine Pollution
Bulletin, 40: 404-425
English, S., Wilkinson, C.R., Baker, C., 1997. Survey Manual for Tropical Marine Resources. Australian
Institute of Marine Science, Townsville.
Frydl and Stearn (1978). Rate of Bioerosion by Parrotfish in Barbados Reef Environments. Journal of
Sedimentary Petrology, 48(4): 1149 – 1158
Fütterer, D.K. 1974. Significance of boring sponge Cliona for the origin of fine-grained material of carbonate
sediments. Journal of Sedimentary Petrology, 44: 79-80
Glynn, P.W. 1997. Bioerosion and coral reef growth: A dynamic balance. In: Birkeland, C. (ed.), Life and
death of coral reefs. New York: Chapman & Hall, pp. 69-98.
Glynn, P.W., Stewart, R.H. and McCosker, J.E. 1972. Pacific coral reefs of Panama: Structure, distribution
and predators. Geologische Rundschau, 61: 483-519
Glynn, P.W., Wellington, G.M. and Birkeland, C. 1979. Coral Reef Growth in the Galapagos: Limitation by
Sea Urchins. Science, 203: 47-49
Glynn, P.W., Veron, J.E.N and Wellington, G.M. 1996. Clipperton Atoll (eastern Pacific): oceanography,
geomorphology, reef-building coral ecology and biogeography. Coral Reefs 15: 71-79
Golubic, S., Perkins, R.D. and Lukas, K.J. 1975. Boring microorganisms and microborings in carbonate
substrates. In Frey, R.W. (ed). The Study of Trace Fossils, Berlin, Springer-Verlag, p. 229-259.
Golubic, S., Friedmann, I. and Schneider, J., 1981. The lithobiontic ecological niche, with special reference
to microorganisms. Journal of Sedimentary Petrology, 51: 475-478.
Goreau, T. and Hartman, W. 1963. Boring sponges as controlling factors in the formation and maintenance
of coral reefs. American Association for the Advancement of Science Publications, 75: 25-54
Griffin, P.S., Garcia, R.P. and Weil, E. 2003. Bioerosion in coral reef communities in southwest Puerto Rico
by the sea urchin Echinometra viridis. Marine Biology, 143: 79-84
Gygi, R.A. 1975. Sparisoma viride, (the Stoplight Parrotfish), a major sediment producer on coral reefs of
Bermuda. Ecologiae Geologicae Helvetiae, 68(2): 327-359
Hallock, P., 2001. Coral reefs, carbonate sediments, nutrients, and global change. In: Stanley, G. D. (ed.),
The history and sedimentology of ancient reef systems. Kluwer, Topics in Geobiology, Vol. 17, pp.
387–427.
Harney, J.N., and Fletcher, C.H. III, 2003. A budget of carbonate framework and sediment production,
Kailua Bay, Oahu, Hawaii. Journal of Sedimentary Research, 73: 856–868.
Hart, D.E. and Kench, P.S. 2007. Carbonate production of an emergent reef platform, Warraber Island,
Torres Strait, Australia. Coral Reefs, 26: 53-68.
Herrera-Escalante T, Lopez-Perez RA, Leyte-Morales GE 2005. Bioerosion caused by the sea urchin
Diadema mexicanum (Echinodermata: Echinoidea) at Bahías de Huatulco, Western Mexico. Rev. Biol.
Trop. (Int. J. Trop. Biol.). 53 (3): 263-273
Highsmith, R.C. 1981. Coral Bioerosion: Damage Relative to Skeletal Density. The American Naturalist,
117: 193-198
Highsmith, R. C., Lueptow, R. L. and Schonberg, S. C. (1983). Growth and bioerosion of three massive
corals on the Belize Barrier Reef. Marine Ecology Progress Series 13, 261–271.
Hixon, M.A. 1997. Effects of reef fishes on corals and algae. In: Birkeland, C. (ed.), Life and death of coral
reefs. New York: Chapman & Hall, pp 230-248
Hoey A.S. and Bellwood D.R. 2008. Cross Shelf variation in the role of parrotfishes on the Great Barrier
Reef. Coral Reefs, 27:37-47
Holmes, K.E., Edinger, E.N., Hariyadi, Limmon,G. V. and Risk, M.J. 2000. Bioerosion of live massive corals
and branching coral rubble on Indonesian coral reefs. Marine Pollution Bulletin, 40: 606-617.
Hubbard, D.K. 1986. Sedimentation as control of reef development: St. Croix, U.S.V.I. Coral Reefs, 5:
117-125
Hubbard, D.K. 1997. Reefs as dynamic systems. In: Birkeland, C. (ed.), Life and Death of Coral Reefs.
New York: Chapman & Hall, pp. 43–67.
Hubbard, D., Miller, A., and Scaturo, D., 1990. Production and cycling of calcium carbonate in a shelf-edge
reef system (St. Croix, US Virgin Island): applications to the nature of reef systems in the fossil record.
Journal of Sedimentary Petrology, 60: 335–360.
Kiene, W.E., Hutchings, P.A., 1994. Bioerosion experiments at Lizard Island, Great Barrier Reef. Coral
Reefs 13, 91–98.
Jokiel, P.L., Rodgers, K.S., Brown, E.K., Kenyon, J.C., Aeby, G., Smith, W.R. and Farrell, F. 2005.
Comparison of methods used to estimate coral cover in the Hawaiian Islands. NOAA.
Kiene, W.E., 1988. A model of bioerosion on the great Barrier Reef. Proceedings of 6th International Coral
Reef Symposium, Tahiti, v. 3, p. 449-454.
Kleypas, J., Buddemeier, R.W., and Gattuso, J. P., 2001. The future of coral reefs in an age of global
change. International Journal of Earth Sciences, 90: 426–437
Land, L. S. (1979). The fate of reef-derived sediment on the north Jamaican island slope. Marine Geology
29: 55–71
Leujak, W. and Ormond, R.F.G. 2007. Comparative accuracy and efficiency of six coral community survey
methods. Journal of Experimental Marine Biology and Ecology 351: 168-187
Mallela, J. and Perry, C.T., 2007. Calcium carbonate budgets for two coral reefs affected by different
terrestrial runoff regimes, Rio Bueno, Jamaica. Coral Reefs 26: 129-145
McClanahan TR, Muthiga NA (1988) Changes in Kenyan coral reef community structure and function due
to exploitation. Hydrobiologia 166:269–276
McClanahan, T.R., Graham, N.A.J., Maina, J., Chabanet, P., Bruggemann, J.H. and Polunin, N.V.C. 2007.
Influence of instantaneous variation on estimates of coral reef fish populations and communities. Marine
Ecology Progress Series, 340: 221-234
MacGeachy, J.K. and Stearn, C.W. 1976. Boring by Macro-organisms in the Coral Montastrea annularis on
Barbados reefs. International Revue ges. Hydrobiologia, 61: 715-745
Miller, A.W. and Ambrose, R.F. 2000. Sampling patchy distributions: comparison of sampling designs in
rocky intertidal habitats. Marine Ecology Progress Series, 196: 1-14
Mills SC, Peyrot-Clausade M, Fontaine, MF 2000. Ingestion and transformation of algal turf by Echinometra
mathaei on Tiahura fringing reef (French Polynesia). J Exp Mar Biol Ecol 254: 71-84
Mokady O, Lazar B, Loya Y, 1996. Echinoid bioerosion as a major structuring force of Red Sea coral reefs.
Biol. Bull. 190: 367-372
Moore, C. H. and Shedd, W. W. (1977). Effective rates of sponge bioerosion as a function of carbonate
production. In ‘‘Proceedings, Third International Coral Reef Symposium’’ (D. L. Taylor, ed.), Vol. 2, pp.
499–505. Rosenstiel School of Marine and Atmospheric Science, Miami, Florida.
Nadon, M.O. and Stirling, G. 2006. Field and simulation analyses of visual methods for sampling coral
cover. Coral Reefs 25: 177–185
Neumann, A.C. 1966. Observations on coastal erosion in Bermuda and measurements of the boring rate of
the sponge Cliona lampa. Limnology and Oceanography, 11: 92-107
Ohlhorst, S.L., Liddell, W.D., Taylor, R.J., Taylor, J.M. 1988. Evaluation of reef census techniques. Proc.
6th International Coral Reef Symposium: 319–324
Ong, L. and Holland, K.N. 2010. Bioerosion of coral reefs by two Hawaiian parrotfishes: species, size
differences and fishery implications. Marine Biology,157: 1313-1323.
Osorno,A., Peyrot-Clausade, M. and Hutchings, P.A. 2005. Patterns and rates of erosion in dead Porites
across the Great Barrier Reef (Australia) after 2 years and 4 years of exposure. Coral Reefs 24: 292-303
Pari, N., N., Peyrot-Clausade, M., Le Campion-Alsumard, T., Hutchings, P., Chazottes, V., Golubic, S., Le
Campion, J. and Fontaine, M.F. 1998. Bioerosion of experimental substrates on high island and on atoll
lagoons (French Polynesia) after two years of exposure. Marine Ecology Progress Series 166: 119-130
Perry, C.T. 1998. Macroborers within coral framework at Discovery Bay, north Jamaica: Species
distribution and abundance, and effects on coral preservation. Coral Reefs 17: 277–287.
Perry, C.T., and Hepburn, L.J., 2008. Syn-depositional alteration of coral reef framework through
bioerosion, encrustation and cementation: taphonomic signatures of reef accretion and reef depositional
events. Earth Science Reviews, 86: 106–144
Perry, C.T., Spencer, T., and Kench, P., 2008. Carbonate budgets and reef production states: a
geomorphic perspective on the ecological phase-shift concept. Coral Reefs, 27: 853–866
Peyrot-Clausade, M., Chabanet, P., Conand, C., Fontaine, F., Letourneur, Y. and Harmelin-Vivien, M.
2000. Sea Urchin and Fish Bioerosion on La Reunion and Moorea Reefs. Bulletin of Marine Science 66(2):
477-485
Rasser, M.W. and Riegl, B. 2002. Holocene coral reef rubble and its binding agents. Coral Reefs 21: 57-72
Reaka-Kudla, M.L., Feingold, J.S. and Glynn, W. 1996. Experimental studies of rapid bioerosion of coral
reefs in the Galfipagos Islands. Coral Reefs, 15: 101-107
Risk M.J., Heikoop J.M., Edinger E.N., Erdmann M.V. 2001. The assessment ‘toolbox’: community-based
reef evaluation methods coupled with geochemical techniques to identify sources of stress. Bulletin of
Marine Science 69:443–458
Rose, C.S., and Risk, M.J., 1985, Increase in Cliona delitrix infestation of Montastrea cavernosa heads on
an organically polluted protion of the Grand Cayman fringing reef: Marine Ecology-Pubblicazioni della
Stazione Zoologica di Napolii, v. 6, p. 345-363
Russo, A. R. (1980). Bioerosion by two rock-boring echinoids (Echinometra mathaei and Echinostrephus
aciculatus) on Eniwetak Atoll, Marshal1 Islands. J. mar. Res. 38: 99-110
Samoilys, M.A. and Carlos, G. 2000. Determining methods of underwater visual census for estimating the
abundance of coral reef fishes. Environmental Biology of Fishes 57: 289-304
Scoffin, T.P. 1981. Aspects of the preservation of deep and shallow water reefs. Proceedings of the 4 th
International Coral Reef Symposium 1: 499-501
Scoffin, T., 1992. Taphonomy of coral reefs: a review. Coral Reefs, 11: 57–77
Scoffin, T.P. 1997. Preservation and CaCO3 budget of reef-flat corals, Phuket, South Thailand.
Proceedings of the 8th International Coral Reef Symposium 2: 1795-1800
Scoffin, T.P., Stearn, C.W., Boucher, D., Frydl, P., Hawkins, C.M., Hunter, I.G. and McGeachy, J.K. 1980.
Calcium Carbonate Budget Of A Fringing Reef on the West Coast of Barbados Part II – Erosion, Sediments
and Internal Structure. Bulletin of Marine Science, 30(2): 475-508
Spencer, T. 1992. Bioerosion and biogeomorphology. In: John, D.M., Hawkins, S.J. and Price, J.H. (eds).
Plant-animal interactions in the marine benthos. Systematics Association Special Volume No. 46.
Clarendon Press (Oxford Science Publications), Oxford, pp 492-509
Sprachta, S., Camoin, G., Golubic, S. and Le Campion, T., 2001, Microbialites in a modern lagoonal
environment: nature and distribution, Tikehau atoll (French Polynesia). Palaeogeography,
Palaeoclimatology, Palaeoecology, 175: 103-124
Stearn, C.W., Scoffin, T.P. and Martindale, W., 1977. Calcium carbonate budget of a fringing reef on the
West Coast of Barbados. Part 1 – Zonation and Productivity. Bulletin of Marine Science, 27 (3): 479-510
Steneck, R.S. 1994. Is herbivore loss more damaging to reefs than hurricanes? Case studies from two
Caribbean reef systems (1978-1988). In ‘‘Global Aspects of Coral Reefs: Health, Hazards, and History’’ (R.
N. Ginsburg, ed.), pp. C32–C37. University of Miami, Florida.
Steneck, R.S. and Adey, W.H. 1976. The role of environment in control of morphology in Lithophyllum
congestum, a Caribbean algal ridge builder. Botanica Marina 19: 197-215
Tribollet, A. and Golubic, S. Cross-shelf differences in the pattern and pace of bioerosion of experimental
carbonate substrates exposed for 3 years on the northern Great Barrier Reef, Austrailia. Coral Reefs, 24:
422-434
Vecsei, A., 2004. A new estimate of global reefal carbonate production including the fore-reefs. Global and
Planetary Change, 43: 1–18.
Ward-Paige C.A., Risk M.J., Sherwood O.A., Jaap W.C. 2005. Clionid sponge surveys on the Florida Reef
Tract suggest land-based nutrient inputs. Mar Pollut Bull 51:570–579
Wilson, S.K., Graham, N.A.J. and Polunin, N.V.C. 2007. Appraisal of visual assessments of habitat
complexity and benthic composition on coral reefs. Marine Biology, 151:1069-1076