Sains Malaysiana 48(11)(2019): 2451–2462

http://dx.doi.org/10.17576/jsm-2019-4811-15

 

Physico-chemical Characterisation and Potential Health Benefit of the Hulu Langat Hot Spring in Selangor, Malaysia

(Pencirian Fiziko-kimia dan Potensi Manfaat Kesihatan bagi Mata Air Panas Hulu Langat Selangor, Malaysia)

 

NORBERT SIMON1,2,3*, TANOT UNJAH1, MUZAFFAR YUSRY1 & MUHAMMAD ASHAHADI DZULKAFLI2

 

1Institute for Environment and Development (LESTARI), Universiti Kebangsaan Malaysia, 43600 UKM Bangi, Selangor Darul Ehsan, Malaysia

 

2Center for Earth Science and the Environment, Faculty of Science & Technology, Universiti Kebangsaan Malaysia, 43600 UKM Bangi, Selangor Darul Ehsan, Malaysia

 

3Natural Disaster Research Center, Faculty of Science and Natural Resources, Universiti Malaysia Sabah, Jalan UMS, 88400 Kota Kinabalu, Sabah, Malaysia

 

Diserahkan: 26 Mac 2019/Diterima: 15 Ogos 2019

 

ABSTRACT

Geotourism is a means in geology that contributes to one of the 17 sustainable development goals (SDGs). One of the key areas in geology that can contribute to geotourism activities is hot spring exploration. This study, therefore explores hot springs in Hulu Langat, Selangor for their potential in geotourism based on their physico-chemical properties and their attributed health benefits potential. These renowned hot springs are Batu 16, Dusun Tua, National Youth Training Institute (IKBN), Sg. Serai, and Sg. Lalang. Despite their popularity among tourists, their health benefits potential remain unclear. Therefore, the physico-chemical properties of these hot springs and their potential health benefits as indicated by the abundance of trace elements in each site will be determined in this study. The temperature (℃), conductivity (μs/cm), total dissolved solid (mg/L), salinity (ppt), dissolved oxygen (mg/L) and pH values of the hot springs have been measured in-situ, and the concentrations of trace elements (Si, Li, Fe, Pb, Mn, Ni, Se, Ag, Na, Zn, K, Mg, Ca, Al, As, Ba, Cd, Cr and Cu) in hot springs water have been determined in the laboratory. Based on the in-situ measurement results, the hot springs are classified according to their pH and temperature. The pH value range from 6.83-8.71 shows that these hot springs are neutral to weak alkaline. The lowest temperature (40.47°C) has been recorded in Dusun Tua hot spring, whereas the highest temperatures (70.41-74.03°C) have been observed in IKBN hot springs. High concentrations of Si, Li, Na, K, As and Cu are found in Batu 16 hot spring. The concentrations of Fe and Ca are higher in Sg. Serai and Sg. Lalang hot springs, and the highest K concentration is found in Dusun Tua hot spring. The other concentration of trace elements are generally low and similar across hot springs. Given the abundance of trace elements, the hot springs could possibly cure certain diseases, such as psoriasis and eczema. The Batu 16, Sg. Serai and Sg Lalang hot springs have the potential to be developed as important sites for health geotourism industries due to the high trace elements concentration. Thus, this study may serve as a basis for further investigations on this aspect.

 

Keywords: Hot spring; Hulu Langat; mineral; potential health benefit

 

ABSTRAK

Geopelancongan ialah satu usaha dalam bidang geologi yang menyumbang kepada salah satu daripada 17 matlamat Pembangunan Mampan (SDGs). Salah satu bidang utama dalam geologi yang boleh menyumbang kepada aktiviti geopelancongan ialah penerokaan mata air panas. Oleh itu, kajian ini mengenal pasti mata air panas di Hulu Langat, Selangor dan potensinya terhadap manfaat kesihatan, yang berpotensi dijadikan kawasan geopelancongan. Mata air panas yang dikenali ramai ini adalah Batu 16, Dusun Tua, Institut Kemahiran Belia Negara (IKBN), Sg. Serai, dan Sg. Lalang. Walau pun terkenal dalam kalangan pelancong, potensinya terhadap manfaat kesihatan masih kurang jelas. Oleh itu, pencirian fiziko-kimia dan potensi manfaat kesihatan bagi mata air panas tersebut yang ditunjukkan oleh kelimpahan unsur surih di setiap lokasi akan ditentukan dalam kajian ini. Suhu (℃), kekonduksian elektrik (μs/cm), jumlah pepejal terlarut (mg/L), kemasinan (ppt), oksigen terlarut (mg/L) dan nilai pH mata air panas diukur secara in-situ, dan kepekatan unsur kimia (Si, Li, Fe, Pb, Mn, Ni, Se, Ag, Na, Zn, K, Mg, Ca, Al, As, Ba, Cd, Cr and Cu) di dalam mata air panas ditentukan melalui kajian makmal. Berdasarkan hasil pengukuran in-situ, mata air panas dikelaskan berdasarkan nilai pH dan suhunya. Julat pH adalah 6.83-8.71 menunjukkan mata air panas ini adalah neutral ke alkali lemah. Suhu paling rendah (40.47°C) telah direkodkan di mata air panas Dusun Tua, manakala suhu tertinggi (70.41-74.03°C) telah didapati di mata air IKBN. Kepekatan Si, Li, Na, K, As dan Cu yang tinggi ditemukan di mata air panas Batu 16. Kepekatan Fe dan Ca didapati lebih tinggi di Sg Serai dan Sg Lalang, manakala kepekatan K tertinggi ditemukan di mata air Dusun Tua. Kepekatan unsur surih dalam mata air panas di lokasi lain secara umumnya rendah dan hampir sama. Berdasarkan kelimpahan unsur surih, Unsur kimia mata air panas ini mungkin juga dapat menyembuhkan penyakit-penyakit tertentu, seperti psoriasis dan ekzema. Mata air panas Batu 16, Sg. Serai dan Sg Lalang mempunyai potensi untuk dibangunkan sebagai tapak penting industri geopelancongan kesihatan. Oleh itu, kajian ini boleh dijadikan asas kepada kajian lanjutan dalam aspek yang sama.

 

Kata kunci: Hulu Langat; mata air panas; mineral; potensi manfaat untuk kesihatan

RUJUKAN

Ablin, J.N., Hauser, W. & Buskila, D. 2013. Spa treatment (Balneotherapy) for fibromyalgia-A qualitative-narrative review and a historical perspective. Evidence-Based Complementary and Alternative Medicine http://dx.doi. org/10.1155/2013/638050. Accessed on 22 February 2019.

Atiqah, A., Syafawanie, A., Syafiqah, A., Izhar, I., Zarif, M., Abdelazim, A., Syafiq, A. & Ong, Q.W. 2017. Hydrogeological and environmental study of Sungai Serai, Hulu Langat. Pakistan Journal of Geology 1(1): 8-11.

Anua, N.A. 2014. Geology and development of geothermal source potential map based on regional lineament density and thermal map around Hulu Langat, Selangor. BSc. Thesis, Geology Program, Universiti Kebangsaan Malaysia (Unpublished).

Bacle, I., Meges, S., Lauze, C., Macleod, P. & Dupuy, P. 1999. Sensory analysis of four medical spa spring waters containing various mineral concentrations. Int. J. Dermatol. 38: 784-786.

Baioumy, H., Nawawi, M., Wagner, K. & Arifin, M.H. 2015. Geochemistry and geothermometry of non-volcanic hot springs in West Malaysia. Journal of Volcanology and Geothermal Research 290: 12-22.

Bryan, K. 1919. Classification of springs. Journal of Geology 27(7): 522-561.

Chakrabarty, P. & Mandal, R. 2018. Geotourism mapping for sustainability: A basin oriented approach. Geojournal of Tourism and Geosites 21(1): 174-185.

Crystal Hot Spring. n.d. Mineral Benefits.

Health%20Benefits%20of%20Hotspring/Minerals%20 Benefits%20_%20Crystal%20Hot%20Springs_ withconcentration.htm. Accessed on 15 September 2016.

Dash, A., Palita, S.K. & Patra, H.K. 2013. Physico-chemical analysis of thermal spring of Atri in the district of Khurda, Odisha, India. International Journal of Chemical Sciences and Applications 4(2): 97-104.

Department of Sustainability, Environment, Water, Population & Communities. 2012. Salinity & Water Quality. Canberra: Department of Sustainability, Environment, Water, Population & Communities.

EPA. 2001. Parameters of Water Quality: Interpretation and Standards. Wexford: Environmental Protection Agency.

Erfurt-Cooper, P. 2010. Geotourism in Volcanic and Geothermal Environments: Playing with Fire? Geoheritage 3: 187-193. DOI: 10.1007/s12371-010-0025-6.

Finkelman, R.B. 2006. Health benefits of geologic materials and geologic processes. International Journal of Environmental Research and Public Health 3(4): 338-342.

Gill, J.C. 2017. Geology and the sustainable development goals. Episodes 40(1): 70-76.

Golusin, Z., Jovanovic, M., Jeremic, B. & Jolic, S. 2014. Balneotherapy of psoriasis. Serbian Journal of Dermatology and Venereology 6(3): 105-112.

Hamzah, Z., Abd Rani, N.L., Saat, A. & Wood, A.K. 2013. Determination of hot springs physic-chemical water quality potentially use for balneotherapy. The Malaysian Journal of Analytical Sciences 17(3): 436-444.

Javed, A., Iqbal, J., Asghar, U., Khan, F.A., Munshi, A.B. & Sddiqui, I. 2009. A study to evaluate therapeutic properties of minerals of Manghopir Hot Sping, Karachi. J. Chem. Soc. Pak. 31(3): 396-401.

Kamal Roslan Mohamed. 1999. Geologi Semenanjung Malaysia: Stratigrafi Jalur Barat. Bangi: Universiti Kebangsaan Malaysia (unpublished).

Kuleta, M. 2018. Geodiversity research methods in geotourism. Geosciences 8(197): 1-9. DOI: 10.3390/geosciences8060197.

Lund, J.W. 2000. Balneological use of thermal water in the USA. GHC Bulletin. pp. 31-34. https://oregontechsfstatic. azureedge.net/sitefinity-production/docs/default-source/ geoheat-center-documents/quarterly-bulletin/vol-21/art10. pdf?sfvrsn=34298d60_4. Accessed on 3 March 2019.

Matz, H., Orion, E. & Wolf, R. 2003. Balneotherapy in dermatology. Dermatologic Therapy 16: 132-140.

Markiey, C.K., Tong Pei, S., Lan Huang, H., Yin Pan, Y., Jie Guo, Y. & Lin Chen, Y. 2005. Developing the culture of Beitou Hot Spring. Applied English Department: Kun Shan University of Technology: 29.

Minerals and Geoscience Department of Malaysia. 1985. Geological Map of Peninsular Malaysia (1:500,000), 8th Ed. Minerals and Geoscience Department of Malaysia.

Moeini, V., Moore, F. & K’tso, N. 2014. Characterization of balneological properties of Mahallat Thermal Springs, Central Iran. Acta Balneologica 1(135): 27-32.

Mohd Hasni, J., Aminnuddin, M., Ariza, Z., Azwani, A., Engku Nurul Syuhadah, E.A., Nor Asikin, J. & Nor Dalila, M. 2017. Comparison of heavy metal levels in natural spring and bottled drinking water in Klang Valley, Malaysia. Malaysian Journal of Public Health Medicine 17: 46-50.

Newsome, D. & Dowling, R.K. 2006. The scope and nature of geotourism. In Geotourism, edited by Dowling, R.K. & Newsome, D. Massachusetts: Elsevier Butterworth- Heinemann. pp. 3-25.

Okpokwasili, G.C., Douglas, S.I. & Inengite, A.K. 2013. Seasonal variations of some physicochemical parameters of groundwater in crude oil flow stations. Journal of Environmental Science and Water Resources 2(1): 16-21.

Olivier, J., van Niekerk, H.J. & van der Walt, I.J. 2008. Physical and chemical characteristics of thermal springs in the Waterberg area in Limpopo Province, South Africa. Water SA 34(2): 163-174.

Peninsular hot spring. 2013. Peninsular Hot Springs. www. peninsularhotsprings.com/uploads/files/.../Media%20kit%20 August%202013.pdf. Accessed on 16 August 2016.

Prakash, P., Gupta, B.K. & Ahmad, M.F. 2017. Characteristics of hot water springs in a region of Rishikund Munger district of Bihar State, India. International Research Journal of Environmental Sciences 6(10): 15-21.

Raisbeck, M.F., Riker, S.L., Tate, C.M., Jackson, R., Smith, M.A., Reddy, K.J. & Zygmunt, J.R. 2008. Water Quality for Wyoming Livestock & Wildlife: A Review of the Literature Pertaining to Health Effects of Inorganic Contaminants. Wyoming: University of Wyoming.

Rapidah, M.S., Mohamed, K.R., Ali, C.A., Leman, M.S. & Saidin, M. 2018a. A geotouristic itinerary: A proposal for geotourism and archaeotourism development of Lenggong Valley, Perak, Malaysia. GeoJournal of Tourism and Geosites 22(2): 597- 624. https://doi.org/10.30892/gtg.22227-314.

Rapidah, M.S., Mohamed, K.R., Ali, C.A., Leman, M.S. & Saidin, M. 2018b. The application of market appeal-robusticity matrix: A case study of the archaeological heritage of Lenggong Valley, Perak, Malaysia. GeoJournal of Tourism and Geosites 23(3): 702-718. https://doi.org/10.30892/ gtg.23307-321.

Reyes, J.N., Jaramillo, M.E., Soriano, A.O. & Romero, I.V. 2015. Physical-chemical and therapeutic properties of hot springs and hydrothermal waters. International Journal of Research and Innovations in Earth Science 2(1): 1375-2394.

Rosca, M. 2003. Geothermal energy and therapy uses in Romanian spas. IGC2003 - short course, Geothermal Training Programme. pp. 99-117.

Sahin-Onat, S., Tasoglu, O., Ozisler, Z., Guneri, F.D. & Ozgirgin, N. 2015. Balneotherapy in the treatment of knee osteoarthritis: A controlled study. Arch. Rheumatol. 30(4): 292-297.

Seite, S. 2013. Thermal waters as cosmeceuticals: La Roche- Posay thermal spring water example. Clinical, Cosmetic and Investigational Dermatology 6: 23-28.

Shahub, M.S., Ibrahim, M.S., Algammal, M.I., Abdelgalil, M. & Alatrash, M.S. 2016. IOSR Journal of Environmental Science, Toxicology and Food Technology 10(6): 46-50.

Sherpa, M.T., Das, S. & Thakur, N. 2013. Physicochemical analysis of hot water springs of Sikkim-Polok Tatopani, Borong Tatopani and Reshi Tatopani. Recent Research in Science and Technology 5(1): 63-67.

Singh, S., Negi, R.S. & Dhanai, R. 2014. A study of physico-chemical parameters of springs around Srinagar Garhwal valley, Uttarakhand. International Journal of Engineering Development and Research 2(4): 3885-3887.

Singh, S.P. & Sunayana. 2017. Study of physico-chemical parameters of groundwater quality of Indira Nagar, Gorakhpur. Journal of Civil Engineering and Environmental Technology 4(5): 416-422.

Subtavewung, P.H., Raksaskulwong, M. & Tulyatid, J. 2005. The characteristic and classification of hot springs in Thailand. Proceedings World Geothermal Congress. Antalya, Turkey, 24-29 April.

Tanyatanaboon, B. & Penkar, R. 2016. Health & Wellness Industry Report - Issue 2: Thermal Hot Springs. Horwath HTL http://country-clone.htl-web.com/files/2016/06/HW-Thermal-Hot-Spring.pdf.

UKHCA. 2016. Controlling Scalding Risks from Bathing and Showering. Sutton: United Kingdom Homecare Association Ltd.

White, D.E. & Brannock, W.W. 1950. The sources of heat and water supply of thermal springs, with particular reference to Steamboat Springs, Nevada. Eos, Transaction American Geophysical Union 31(4): 566-574. https://doi.org/10.1029/ TR031i004p00566.

Young, B.L., Jun, Y.L., Hye, J.L., Seong, T.Y., Jong, T.L., Hong, J.K., Dong, S.Y., So, Y.W. & Jin, W.K. 2014. Immunomodulatory effects of balneotherapy with Hae-Un- Dae thermal water on imiquimod-induced psoriasis-like murine model. Ann. Dermatol. 26(2): 221-230.

Yusry, M., Simon, N. & Unjah, T. 2018. Geodiversity and geoheritage assessment in Hulu Langat District, Selangor, Malaysia. GeoJournal of Tourism and Geosites 23(3): 861-872. https://doi.org/10.30892/gtg.23320-334.

 

*Pengarang untuk surat-menyurat; email: norbsn@ukm.edu.my

 

 

 

 

 

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