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Assessment of clayey materials from Santa Maria (Azores, Portugal) for preparation of peloids

Published online by Cambridge University Press:  01 August 2019

Ângela Cerqueira ,
Cristiana Costa ,
Denise Terroso ,
Cristina Sequeira  and
Fernando Rocha Open the ORCID record for Fernando Rocha [Opens in a new window]
Ângela Cerqueira
Affiliation:
Aveiro University, GeoBioTec Research Centre, Geosciences Department, 3810-193 Aveiro, Portugal
Cristiana Costa
Affiliation:
Aveiro University, GeoBioTec Research Centre, Geosciences Department, 3810-193 Aveiro, Portugal
Denise Terroso
Affiliation:
Aveiro University, GeoBioTec Research Centre, Geosciences Department, 3810-193 Aveiro, Portugal
Cristina Sequeira
Affiliation:
Aveiro University, GeoBioTec Research Centre, Geosciences Department, 3810-193 Aveiro, Portugal
Fernando Rocha*
Affiliation:
Aveiro University, GeoBioTec Research Centre, Geosciences Department, 3810-193 Aveiro, Portugal
*
*E-mail: [email protected]
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Abstract

There is growing interest in the use of natural materials as alternatives to medicinal products composed of chemicals. For this reason, it is important to study materials which fill this need (e.g. the formulation of peloids). Historically, the Azores archipelago has long been visited for its mud baths, mainly on São Miguel Island, where volcanic muds demonstrate beneficial properties. The volcanic muds are scarce, however. Thus, residual clay materials of Santa Maria Island were studied to assess their suitability for the formulation of peloids. The results of tests from 20 samples, collected from all over the island, presented evidence that they are very favourable for peloid formulations, due to their mineralogical, chemical and technological properties. The materials showed good potential for blending with the São Miguel volcanic muds. The deposits studied show extensive outcrops.

Keywords

healing clayproperties assessmentSanta Maria Island
Type
Article
Information
Clay Minerals , Volume 54 , Issue 3 , September 2019 , pp. 299 - 307
Copyright
Copyright © Mineralogical Society of Great Britain and Ireland 2019 

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Footnotes

Associate Editor: Asuman Turkmenoglu

References

Alonso, M.L., Montaña, F.P., Miranda, M., Castillo, C. & Hernández, J. (2004) Interactions between toxic (As, Cd, Hg and Pb) and nutritional essential (Ca, Co, Cu, Fe, Mn, Mo, Ni, Se, Zn) elements in the tissues of cattle from NW Spain. BioMetals, 17, 389–379.Google Scholar
Awad, M.E., López-Galindo, A., Setti, M., El-Rahmany, M.M. & Iborra, C.V. (2017) Kaolinite in pharmaceutics and biomedicine. International Journal of Pharmaceutics, 533, 3448.Google Scholar
Bain, J.A. (1971) A plasticity chart as an aid to the identification and assessment of industrial clays. Clay Minerals, 9, 117.Google Scholar
Brindley, G.W. & Brown, G. (1980) Crystal Structures of Clay Minerals and Their X-Ray Identification. Mineralogical Society Monograph No. 5. Mineralogical Society, London, UK.Google Scholar
Carretero, M. (2002) Clay minerals and their beneficial effects upon human health. Applied Clay Science, 21, 155163.Google Scholar
Carretero, M.I., Gomes, C.S.F. & Tateo, F. (2013) Clays, drugs and human health. Pp. 711764 in: Handbook of Clay Science (Second Edition, Part B: Techniques and Applications) (Bergaya, F. & Lagaly, G., editors). Elsevier, Amsterdam, The Netherlands.Google Scholar
Carretero, M.I. & Pozo, M. (2009) Clay and non-clay minerals in the pharmaceutical industry. Part I. Excipients and medical applications. Applied Clay Science, 46, 7380.Google Scholar
Carretero, M.I. & Pozo, M. (2010) Clay and non-clay minerals in the pharmaceutical and cosmetic industries Part II. Active ingredients. Applied Clay Science, 47, 171181.Google Scholar
Carvalho, M.R., Mateus, A., Nunes, J.C. & Carvalho, J.M. (2014) Origin and chemical nature of the thermal fluids at Caldeiras da Ribeira Grande (Fogo Volcano, S. Miguel Island, Azores). Environment Earth Sciences, 73, 27932808.Google Scholar
Draidia, S., El Ouahabi, M., Daoudi, L., Havenith, H.-B. & Fagel, N. (2016) Occurences and genesis of palygorskite/sepiolite and associated minerals in Barzaman formation, United Arab Emirates. Clay Minerals, 51, 763779.Google Scholar
Galhano, C., Rocha, F. & Gomes, C. (1999) Geostatistical analysis of the influence of textural, mineralogical and geochemical parameters on the geotechnical behavior of the ‘Clays Aveiro’ formation (Portugal). Clay Minerals, 34, 109116.Google Scholar
Goldberga, K. & Humayun, M. (2010) The applicability of the Chemical Index of Alteration as a paleoclimatic indicator: an example from the Permian of the Paraná Basin, Brazil. Palaeogeography, Palaeoclimatology, Palaeoecology, 293, 175183.Google Scholar
Gomes, C. (2017) Healing and edible clays: a review of basic concepts, benefits and risks. Environmental Geochemistry and Health, 40, 17391765.Google Scholar
Gomes, C. & Silva, J. (2007) Minerals and clay minerals in medical geology. Applied Clay Science, 36, 421.Google Scholar
Guarino, A., Bisceglia, M., Castellucci, G., Iacono, G., Casali, L. G., Bruzzese, E., Musetta, A. & Greco, L. (2001) smectite in the treatment of acute diarrhea: a nationwide randomized controlled study of the Italian Society of Pediatric Gastroenterology and Hepatology (SIGEP) in collaboration with primary care pediatricians. Journal of Pediatric Gastroenterology and Nutrition, 32, 7175.Google Scholar
Karakaya, M.Ç., Karakaya, N., Sarıoğlan, Ş. & Koral, M. (2010) Some properties of thermal muds of some spas in Turkey. Applied Clay Science, 48, 531537.Google Scholar
Knidiri, A., Daoudi, L., El Ouahabi, M. & Rocha, F. (2014) Palaeogeographic controls on palygorskite occurrence in Maastrichtian–Palaeogene sediments of the Western High Atlas and Meseta Basins (Morocco). Clay Minerals, 49, 595608.Google Scholar
Legido, J.L., Medina, C., Mourelle, M.L., Carretero, M.I. & Pozo, M. (2007) Comparative study of the cooling rates of bentonite, sepiolite and common clays for their use in pelotherapy. Applied Clay Science, 36, 148160.Google Scholar
López-Galindo, A. & Viseras, C. (2004) Pharmaceutical and cosmetic application of clays. Interface Science and Technology, 1, 267289.Google Scholar
López-Galindo, A., Viseras, C. & Cerezo, P. (2006) Compositional, technical and safety specifications of clays to be used as pharmaceutical and cosmetic products. Applied Clay Science, 36, 5163.Google Scholar
Madeira, J.E.O. (1986) Geologia Estrutural e Enquadramento Geotectónico da Ilha de Santa Maria (Açores). MSc thesis, Departamento de Geologia, Faculdade de Ciências da Universidade de Lisboa, Lisbon, Portugal.Google Scholar
Murray, H.H. (1999) Applied clay mineralogy today and tomorrow. Clay Minerals, 34, 3949.Google Scholar
Nunes, J.C., Lima, E.A. & Medeiros, S. (2007) Os Açores, Ilhas de Geodiversidade: O Contributo da Ilha de Santa Maria. Açoreana, Suppl. 5, 74111.Google Scholar
Oliveira, A., Rocha, F., Rodrigues, A., Jouanneau, J., Dias, A., Weber, O. & Gomes, C. (2002) Clay minerals from the sedimentary cover from the Northwest Iberian shelf. Progress in Oceanography, 52, 233247.Google Scholar
Quintela, A., Costa, C., Terroso, D. & Rocha, F. (2014) Abrasiveness Index of dispersions of Portuguese clays using the Einlehner method: influence of clay parameters. Clay Minerals, 49, 2734.Google Scholar
Quintela, A., Costa, C., Terroso, D., , H., Nunes, J.C. & Rocha, F. (2015) Characterization and evaluation of hydrothermally influenced clayey sediments from Caldeiras da Ribeira Grande fumarolic field (Azores Archipelago, Portugal) used for aesthetic and pelotherapy purposes. Environmental Earth Sciences, 73, 28332842.Google Scholar
Quintela, A., Terroso, D., da Silva E., Ferreira & Rocha, F. (2012). Certification and quality criteria of peloids in use for therapeutic purposes. Clay Minerals, 47, 441451.Google Scholar
Rebelo, M., Rocha, F. & Ferreira da Silva, E. (2010) Mineralogical and physicochemical characterization of selected Portuguese Mesozoic–Cenozoic muddy/clayey raw materials to be potentially used as healing clays. Clay Minerals, 45, 229240.Google Scholar
Rebelo, M., Viseras, C., Galindo, A.L., Rocha, F. & Silva, E.F. (2011a) Rheological and thermal characterization of peloids made of selected Portuguese geological materials. Applied Clay Science, 52, 219227.Google Scholar
Rebelo, M., Viseras, C., Galindo, A.L., Rocha, F. & Silva, E.F. (2011b) Characterization of Portuguese geological materials to be used in medical hydrology. Applied Clay Science, 51, 258266.Google Scholar
Schultz, L.G. (1964) Quantitative interpretation of mineralogical composition from X-ray and chemical data for the Pierre Shale. US Geological Survey Professional Paper, 391-C, 131.Google Scholar
Serralheiro, A. (2003) A geologia da ilha de Santa Maria, Açores. Açoreana, 10, 141192.Google Scholar
Viseras, C., Aguzzi, C., Cerezo, P. & Lopez-Galindo, A. (2007) Uses of clay minerals in semisolid health care and therapeutic products. Applied Clay Science, 36, 3750.Google Scholar
Xie, Q., Qiu, G., Chen, T., Xu, X., Wang, X., Lu, H., Xu, H. & Ji, J. (2015) Palygorskite in the late Miocene red clay sediment from the Chinese Loess Plateau and its paleoclimatic implications. Proceedings of the 11th International Congress for Applied Mineralogy (ICAM), 425–440.Google Scholar
Yvon, J. & Ferrand, T. (1996) Preparation ex-situ de peloides. Proprietes thermiques, mecaniques et d'echange. Pp. 6778 in: Atti Convegno ‘Argille curative’, Salice Terme (PV) (Veniale, F., editor). Association Internationale pour l'Etude des Argiles, Paris, France.Google Scholar