___

• 1.Almeida CMR, Mucha A, Vasonce Los MCSD (2004): Influence of the sea rush juncus maritimus on metal concentration and speciation in estuarine sediment colonized by the plant. Environ Sci Technol, 38, 3112-3118.
• 2.Anike FN, Yusuf M, Isikhuemhen OS (2016):Co-Substrating of peanut shells with cornstalks enhances biodegradation by pleurotus ostreatus.J Bioremed Biodeg, 7, 327-334.
• 3.Bonanno G (2011): Micro minerals accumulation and distribution in the organs of Phragmitesaustralis (common reed) and biomonitoring applications.Ecotoxicol Environ Saf, 74, 1057–1064.
• 4.Bonanno G (2013): Comparative performance of micro minerals bioaccumulation and biomonitoringin the plant species Typha domingensis, Phragmites australis and Arundo donax. Ecotoxicol Environ Saf, 97, 124–130.
• 5.Bonanno G, Vymazal J, Cirelli GR (2018): Translocation, accumulation and bioindication of trace elements in wetland plants. Sci of the Total Environ, 631–632, 252–261.
• 6.Cacador I, Vale C, Catarino F(2000): Seasonal variation of Zn, Pb, Cu and Cd concentrations in the rootsediment system of Spartina maritime and Halimione portulacoides from Tagus estuary salt marshes. Mar Environ Res, 49, 279-290.
• 7.Cetinkaya N, Erdem F (2015): Effects of different Juncus acutus: maise silage ratios on digestibility and rumen cellulolytic bacteria. Kafkas Univ Vet Fak Derg, 21, 499-505.
• 8.Ceylan S, Yoldas F, Elmacı O,et al (2016): Effect of green manure on yield and mineral nutrient content of pumpkin grown in sandy loam soil.Ege Üniv Ziraat Fak Derg, 53, 75-381.
• 9.Engin MS, Uyanık A, Cay S (2017): Investigation of micro metals distribution in water, sediments and wetland plants of Kızılırmak Delta, Turkey. Int J Sed Res, 32, 90–97.
• 10.Erdem F (2014): Determination the digestibility of Juncus acutusby in-vıtro gas production and its effect on ruminal cellulolytic bacteria by real-time PCR methods. PhD Thesis, Ondokuz Mayıs University, Graduate School of Health Sciences, Samsun.
• 11.Erdem F, Cetinkaya N (2016): Digestibility of Juncus acutus and its effects on ruminal cellulolytic bacteria. Italian JAgric Sci, 15, 69-75.
• 12.Erdem F, Cetinkaya N, Nisbet C, et al (2015): Estimation organic matter digestibility, metabolisable energy, phenolic compounds and antioxidant activity of stem and seed of Juncus acutus plant for ruminants.South African J Anim Sci,45, 502-509.
• 13.Feedipedia (2017)Animal Feed Resources Information System INRA CIRAD AFZ and FAO. Available at http://www.feedipedia.org/node/12167. (Accessed February 12, 2019).
• 14.Gursoy E, Muhlis M (2017): Determination of mineral contents of some legume and cereal forages grown as naturally in pastures of Erzurum province. Alinteri J Agric Sci, 32 (1), 1-9.
• 15.Hosseini Alhashemi AS, Karbassi AR, Hassanzadeh Kiabi B, et al (2011): Bioaccumulation of micro minerals n trophic levels of wetland plants and waterfowl birds. Biol Micro Elem Res, 142, 500-516.
• 16.Jamnıcká G, Hrivnák R, Oťaheľová H, et al (2006): Heavy metals content in aquatic plant species from some aquatic biotopes in Slovakia. 336-370. In: Proocedings of36thInternat Conf of IAD. Austrian Committee Danube Research/IAD.
• 17.Judson GJ, Mcfarlane JD (1998): Mineral disorders in grazing livestock and the usefulness of soil and plant analysis in the assessment of these disorders.Aust J Experi Agric, 38, 707-723.
• 18.Kuniyal JC, Sharma M, Chand K, et al (2015): Water soluble ionic components in particulate matter (PM10) during high pollution episode days at Mohal and Kothi in the North-Western Himalaya, India. Aerosol AırQualRes, 15, 529–543.
• 19.Mcdowell LR, Conrad JH, Ellis GL, et al (1983): Minerals for grazing ruminants in tropical regions.Extension bulletin 1149, Animal Science Department, University of Florida, Gainesville.
• 20.Medas D, De Giudici G, Pusceddu C, et al (2019): Impact of Zn excess on biomineralization processes in Juncus acutus grown in mine polluted sites. J Hazard Mater, 370, 98-107.
• 21.Milic D, Lukovic J, Ninkov J, et al (2012): Heavy metal content in halophytic plants from inland and maritime saline areas. Cent Eur J Biol, 7, 307-317.
• 22.Miller RO (1998): Microwave digestion of plant tissue in a closed vessel. 69-73. In, Kalra YP(Ed): Handbook of reference methods for plant analysis. CRC Press, New York.
• 23.Minson DJ (1990): Forage in ruminants. Academic Press Inc. San Diego, California, USA.
• 24.SAS (2007): SAS Statistic Software, SAS Campus Drive. Cary NC, USA.
• 25.Singh N, Kaur M, Kaur Katnoria J (2017): Analaysis on biaccumulaton of metals in aquatic environment od Beas River Basin: Acase study from Kanjli wetland. Geo Health, 1, 93-105.
• 26.Sousa AI, Cacador I, Lillebø AI, et al (2008): Heavy metal accumulation in Halimione portulacoides: Intra-and extra-cellular metal binding sites. Chemosphere, 70, 850-857.
• 27.Sundby B, Vale C, Caçador I, et al (1998): Metal-rich concretions on the roots of salt marsh plants: Mechanism and rate of formation. Limnol Oceanogr, 43, 245-252.
• 28.Teuchies J, Jacobs S, Oosterlee L, et al (2013): Role of plants in metal cycling in a tidal wetland: Implications for phytoremidiation. Sci Total Environ,445–446, 146–154.
• 29.Vodyanitskii YN, Shoba SA (2015): Biogeochemistry of carbon, iron, and heavy metals in wetlands (analytical review). Moscow Univ Soil Sci Bull, 70, 89–97.
• 30.Windham L, Weis JS, Weise P (2003): Uptake and distribution of metals in two dominant salt marsh macrophytes, Spartina alternifolia (cordgrass) and Phragmites australis (common reed). Mar Environ Res, 56, 63-72.
• 31.Yabanlı M, Yozukmaz A, Sel F (2014):Heavy Metal accumulation in the leaves, stem and root of the invasive submerged macrophyte Myriophyllum spicatum L. (Haloragaceae): An Example of kadın creek (Mugla, Turkey). Braz Arch Biol Technol,57, 434-440.