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Andres P., 1999 – Ecological risks of the use of sewage sludge as fertilizer in soil restoration: effects on the soil microarthropod populations, Land Degradation & Development, 10, 1, 67-77.Search in Google Scholar
Antunes L. F. D. S., Scoriza R. N., Silva D. G. D. and Correia M. E. F., 2016 – Production and efficiency of organic compost generated by millipede activity, Ciência Rural, 46, 815-819.Search in Google Scholar
Ashraf M., Zulkifli R., Sanusi R., Tohiran K. A., Terhem R., Moslim R. and Azhar B., 2018 – Alley-cropping system can boost arthropod biodiversity and ecosystem functions in oil palm plantations, Agriculture, Ecosystems & Environment, 260, 19-26.Search in Google Scholar
Ashwini K. M. and Sridhar K. R., 2006 – Seasonal abundance and activity of pill millipedes (Arthrosphaera magna) in mixed plantation and semi-evergreen forest of southern India, Acta Oecologica, 29, 1, 27-32.Search in Google Scholar
Berg M. P. and Hemerik L., 2004 – Secondary succession of terrestrial isopod, centipede, and millipede communities in grasslands under restoration, Biology and Fertility of Soils, 40, 163-170.Search in Google Scholar
Birkhofer K., Dietrich C., John K., Schorpp Q., Zaitsev A. S. and Wolters V., 2016 – Regional conditions and land-use alter the potential contribution of soil arthropods to ecosystem services in grasslands, Frontiers in Ecology and Evolution, 3, 150.Search in Google Scholar
Blanchart E., Villenave C., Viallatoux A., Barthès B., Girardin C., Azontonde A. and Feller C., 2006 – Long-term effect of a legume cover crop (Mucuna pruriens var. utilis) on the communities of soil macrofauna and nematofauna, under maize cultivation, in southern Benin, European Journal of Soil Biology, 42, S136-S144.Search in Google Scholar
Bozzatto V. and Fontanetti C. S., 2012 – Sewage sludge toxicity in edaphic organism: analysis of midgut responses in the diplopod Rhinocricus padbergi, Microscopy Research and Technique, 75, 7, 869-875.Search in Google Scholar
Brévault T., Bikay S., Maldes J. M. and Naudin K., 2007 – Impact of a no-till with mulch soil management strategy on soil macrofauna communities in a cotton cropping system, Soil and Tillage Research, 97, 2, 140-149.Search in Google Scholar
Bufebo B., Elias E. and Getu E., 2021 – Abundance and diversity of soil invertebrate macro-fauna in different land uses at Shenkolla watershed, South Central Ethiopia, The Journal of Basic and Applied Zoology, 82, 1-12.Search in Google Scholar
Bunyangha J., Muthumbi A. W., Gichuki N. N., Majaliwa M. J. and Egeru A., 2022 – Soil macroinvertebrate response to paddy rice farming pathways in Mpologoma Catchment, Uganda, Agronomy, 12, 2, 312.Search in Google Scholar
Callaham Jr. M. A., Richter Jr. D. D., Coleman D. C. and Hofmockel M., 2006 – Long-term land-use effects on soil invertebrate communities in Southern Piedmont soils, USA, European Journal of Soil Biology, 42, S150-S156.Search in Google Scholar
Car C. A., 2010 – Pine plantations and native millipedes (Diplopoda: Polydesmida: Paradoxosomatidae) in south-eastern New South Wales, Australia, Australian Journal of Entomology, 49, 4, 317-323.Search in Google Scholar
Christofoletti C. A., Francisco A., Pedro-Escher J., Gastaldi V. D. and Fontanetti C. S., 2016 – Diplopods as soil bioindicators of toxicity after application of residues from sewage treatment plants and ethanol industry, Microscopy and Microanalysis, 22, 5, 1098-1110.Search in Google Scholar
Chumak V., Obrist M. K., Moretti M. and Duelli P., 2015 – Arthropod diversity in pristine vs. managed beech forests in Transcarpathia (Western Ukraine), Global Ecology and Conservation, 3, 72-82.Search in Google Scholar
Coelho M. P. M., Moreira-de-Sousa C., de Souza R. B., Ansoar-Rodríguez Y., Silva-Zacarin E. C. M. and Fontanetti C. S., 2017 – Toxicity evaluation of vinasse and biosolid samples in diplopod midgut: heat shock protein in situ localization, Environmental Science and Pollution Research, 24, 22007-22017.Search in Google Scholar
Coq S., Nahmani J., Resmond R., Segrestin J., David J. F., Schevin P. and Kazakou E., 2018 – Intraspecific variation in litter palatability to macroarthropods in response to grazing and soil fertility, Functional Ecology, 32, 11, 2615-2624.Search in Google Scholar
Dairo O. S. and Soyelu O. J., 2017 – Consequences of prolonged agronomic practices: faunal composition and abundance in cultivated and fallowed soils, International Journal of Conservation Science, 8, 3.Search in Google Scholar
Dauber J., Purtauf T., Allspach A., Frisch J., Voigtländer K. and Wolters V, 2005 – Local vs. landscape controls on diversity: a test using surface-dwelling soil macroinvertebrates of differing mobility, Global Ecology and Biogeography, 14, 3, 213-221.Search in Google Scholar
De Godoy J. A. P. and Fontanetti C. S., 2010 – Diplopods as bioindicators of soils: analysis of midgut of individuals maintained in substract containing sewage sludge, Water, Air, & Soil Pollution, 210, 389-398.Search in Google Scholar
De Smedt P., Baeten L., Proesmans W., Berg M. P., Brunet J., Cousins S. A. and Verheyen K., 2018 – Linking macrodetritivore distribution to desiccation resistance in small forest fragments embedded in agricultural landscapes in Europe, Landscape Ecology, 33, 407-421.Search in Google Scholar
De Souza R. B. and Fontanetti C. S., 2012 – Alterations in the fat body cells of Rhinocricus padbergi (Diplopoda) resulting from exposure to substrate containing sewage sludge, Microscopy and Microanalysis, 18, 2, 317-323.Search in Google Scholar
Diekötter T., Wamser S., Wolters V. and Birkhofer K., 2010 – Landscape and management effects on structure and function of soil arthropod communities in winter wheat, Agriculture, ecosystems & environment, 137, 1-2, 108-112.Search in Google Scholar
Dittmer J., Lesobre J., Raimond R., Zimmer M. and Bouchon D., 2012 – Influence of changing plant food sources on the gut microbiota of saltmarsh detritivores, Microbial ecology, 64, 814-825.Search in Google Scholar
Dobrovodská M., Kanka R., Gajdoš P., Krištín A., Kollár J., Stašiov S. and Lieskovský J., 2023 – Factors affecting the biodiversity of historical landscape elements: detailed analyses from three case studies in Slovakia, Environmental Monitoring and Assessment, 195, 6, 1-17.Search in Google Scholar
Duran-Bautista E. H., Angel-Sanchez Y. K., Bermúdez, M. F. and Suárez J. C., 2023 – Agroforestry systems generate changes in soil macrofauna and soil physical quality relationship in the northwestern Colombian Amazon, Agroforestry Systems, 97, 5, 927-938.Search in Google Scholar
Emmerling C., 1995 – Long-term effects of inundation dynamics and agricultural land-use on the distribution of soil macrofauna in fluvisols, Biology and fertility of soils, 20, 130-136.Search in Google Scholar
Errouissi F., Moussa-Machraoui S. B., Ben-Hammouda M. and Nouira S., 2011 – Soil invertebrates in durum wheat (Triticum durum L.) cropping system under Mediterranean semi arid conditions: A comparison between conventional and no-tillage management, Soil and Tillage Research, 112, 2, 122-132.Search in Google Scholar
Fiera C., Ulrich W., Popescu D., Bunea C. I., Manu M., Nae I. and Zaller J. G., 2020 – Effects of vineyard inter-row management on the diversity and abundance of plants and surface-dwelling invertebrates in Central Romania, Journal of insect conservation, 24, 175-185.Search in Google Scholar
Forero N., Serrano P. A. and Forero F. E., 2021 – Influence of land use on the diversity and composition of edaphic arthropods in the Granja Tunguavita, Temas Agrarios, 26, 1, 80-91.Search in Google Scholar
Forio M. A. E., De Troyer N., Lock K., Witing F., Baert L., Saeyer N. D. and Goethals P., 2020 – Small patches of riparian woody vegetation enhance biodiversity of invertebrates, Water, 12, 11, 3070.Search in Google Scholar
Francisco A., Christofoletti C. A., Neto N. R. and Fontanetti C. S., 2015 – Histopathological changes in the perivisceral fat body of Rhinocricus padbergi (Diplopoda, Spirobolida) triggered by biosolids, Environmental Science and Pollution Research, 22, 18590-18600.Search in Google Scholar
García R. R., Ocharan F. J., García U., Osoro K. and Celaya R., 2010 – Arthropod fauna on grassland–heathland associations under different grazing managements with domestic ruminants, Comptes Rendus Biologies, 333, 3, 226-234.Search in Google Scholar
García R. R., Ocharan F. J., Jáuregui B. M., García U., Osoro K. and Celaya R., 2010 – Ground-dwelling arthropod communities present in three types of Cantabrian (NW Spain) heathland grazed by sheep or goats, European Journal of Entomology, 107, 2.Search in Google Scholar
Gaylor M. O., Mears G. L., Harvey E., La Guardia M. J. and Hale R. C., 2014 – Polybrominated diphenyl ether accumulation in an agricultural soil ecosystem receiving wastewater sludge amendments, Environmental Science & Technology, 48, 12, 7034-7043.Search in Google Scholar
Jabin M., Mohr D., Kappes H. and Topp W, 2004 – Influence of deadwood on density of soil macro-arthropods in a managed oak–beech forest, Forest Ecology and Management, 194, 1-3, 61-69.Search in Google Scholar
Kappes H., Clausius A. and Topp W., 2012 – Historical small-scale surface structures as a model for post-mining land reclamation, Restoration Ecology, 20, 3, 322-330.Search in Google Scholar
Lagerlöf J., Maribie C. and John J. M., 2017 – Trophic interactions among soil arthropods in contrasting land-use systems in Kenya, studied with stable isotopes, European Journal of Soil Biology, 79, 31-39.Search in Google Scholar
Laossi K. R., Barot S., Carvalho D., Desjardins T., Lavelle P., Martins M. and Grimaldi M., 2008 – Effects of plant diversity on plant biomass production and soil macrofauna in Amazonian pastures, Pedobiologia, 51, 5-6, 397-407.Search in Google Scholar
Manetti P. L., Faberi A. J., Clemente N. L. and López A. N., 2013 – Macrofauna activity density in contrasting tillage systems in Buenos Aires Province, Argentina, Agronomy Journal, 105, 6, 1780-1786.Search in Google Scholar
Manetti P. L., López A. N., Clemente N. L. and Faberi A. J., 2010 – Tillage system does not affect soil macrofauna in southeastern Buenos Aires province, Argentina, Spanish Journal of Agricultural Research, 8, 2, 377-384.Search in Google Scholar
Marchão R. L., Lavelle P., Celini L., Balbino L. C., Vilela L. and Becquer T., 2009 – Soil macrofauna under integrated crop-livestock systems in a Brazilian Cerrado Ferralsol, Pesquisa Agropecuária Brasileira, 44, 1011-1020.Search in Google Scholar
Marichal R., Grimaldi M., Feijoo A., Oszwald J., Praxedes C., Cobo D. H. R. and Lavelle P., 2014 – Soil macroinvertebrate communities and ecosystem services in deforested landscapes of Amazonia, Applied Soil Ecology, 83, 177-185.Search in Google Scholar
Meitiyani and Dharma A. P., 2018 – Diversity of soil arthropods in different soil stratification layers, The National Park of Gede Pangrango Mountain, Cisarua Resort, West Java, Indonesia, IOP Conference Series: Earth and Environmental Science, 197, 012019.Search in Google Scholar
Mikula J., Sarapatka B., Kopecky O. and Tuf I. H, 2014 – Assemblages of millipedes and centipedes according to the type of pasture management: preliminary results from the Czech Republic, Revue d’Ecologie, Terre et Vie, 69, 2, 167-172.Search in Google Scholar
Morón-Ríos A., Rodríguez M. Á., Pérez-Camacho L. and Rebollo S., 2010 – Effects of seasonal grazing and precipitation regime on the soil macroinvertebrates of a Mediterranean old-field, European Journal of Soil Biology, 46, 2, 91-96.Search in Google Scholar
Mujeeb Rahman P., Varma R. V. and Sileshi G. W., 2012 – Abundance and diversity of soil invertebrates in annual crops, agroforestry and forest ecosystems in the Nilgiri biosphere reserve of Western Ghats, India, Agroforestry systems, 85, 165-177.Search in Google Scholar
Naiman R. J. and Decamps H., 1997 – The ecology of interfaces: riparian zones, Annual Review of Ecology and Systematics, 28, 1, 621-658.Search in Google Scholar
Nash M. A., Hoffmann A. A. and Thomson L. J., 2010 – Identifying signature of chemical applications on indigenous and invasive nontarget arthropod communities in vineyards, Ecological Applications, 20, 6, 1693-1703.Search in Google Scholar
Nogarol L. R. and Fontanetti C. S., 2010 – Acute and subchronic exposure of diplopods to substrate containing sewage mud: Tissular responses of the midgut, Micron, 41, 3, 239-246.Search in Google Scholar
Nogarol L. R. and Fontanetti C. S., 2011 – Ultrastructural alterations in the midgut of diplopods after subchronic exposure to substrate containing sewage mud, Water, Air, & Soil Pollution, 218, 539-547.Search in Google Scholar
Perez D. G. and Fontanetti C. S., 2011 – Assessment of the toxic potential of sewage sludge in the midgut of the diplopod Rhinocricus padbergi, Water, Air, & Soil Pollution, 218, 437-444.Search in Google Scholar
Popescu C., Oprina-Pavelescu M., Dinu V., Cazacu C., Burdon F. J., Forio M. A. E., Rîșnoveanu G., 2021 – Riparian vegetation structure influences terrestrial invertebrate communities in an agricultural landscape, Water, 13, 2, 188.Search in Google Scholar
Ramey T. L. and Richardson J. S., 2017 – Terrestrial invertebrates in the riparian zone: mechanisms underlying their unique diversity, BioScience, 67, 9, 808-819.Search in Google Scholar
Rossi J. P. and Blanchart E., 2005 – Seasonal and land-use induced variations of soil macrofauna composition in the Western Ghats, southern India, Soil Biology and Biochemistry, 37, 6, 1093-1104.Search in Google Scholar
Sabatté M. L., Massobrio M. J., Cassani M. T. and Momo F. R., 2021 – Macro and mesofauna soil food webs in two temperate grasslands: responses to forestation with Eucalyptus, Heliyon, 7, 1.Search in Google Scholar
Salvio C., López A. N., Manetti P. L. and Clemente N. L., 2011 – Effects of granulated baits on meso and macrofauna in soybean soil system, Journal of Environmental Biology, 32, 6, 793.Search in Google Scholar
Sharley D. J., Hoffmann A. A. and Thomson L. J., 2008 – The effects of soil tillage on beneficial invertebrates within the vineyard, Agricultural and Forest Entomology, 10, 3, 233-243.Search in Google Scholar
Sileshi G. and Mafongoya P. L., 2006 – Long-term effects of improved legume fallows on soil invertebrate macrofauna and maize yield in eastern Zambia, Agriculture, Ecosystems & Environment, 115, 1-4, 69-78.Search in Google Scholar
Sileshi G. and Mafongoya P. L., 2006 – Variation in macrofaunal communities under contrasting land use systems in eastern Zambia, Applied Soil Ecology, 33, 1, 49-60.Search in Google Scholar
Sileshi G., Mafongoya P. L., Chintu R. and Akinnifesi F. K., 2008 – Mixed-species legume fallows affect faunal abundance and richness and N cycling compared to single species in maize-fallow rotations, Soil Biology and Biochemistry, 40, 12, 3065-3075.Search in Google Scholar
Sithole N. J., Magwaza L. S., Mafongoya P. L. and Thibaud G. R., 2018 – Long-term impact of no-till conservation agriculture on abundance and order diversity of soil macrofauna in continuous maize monocropping system, Acta Agriculturae Scandinavica, Section B-Soil & Plant Science, 68, 3, 220-229.Search in Google Scholar
Skłodowski J. and Tracz H., 2018 – Consequences for millipedes (Myriapod, Dipolopoda) of transforming a primeval forest into amanaged forest – a case study from Białowieża (Poland), Forest Ecology and Management, 409, 593-600.Search in Google Scholar
Smith J., Potts S. G., Woodcock B. A. and Eggleton P., 2008 – Can arable field margins be managed to enhance their biodiversity, conservation and functional value for soil macrofauna?, Journal of Applied Ecology, 45,1, 269-278.Search in Google Scholar
Sridhar K. R., Kadamannaya B. S. and Karamchand K. S., 2013 – Nutrient composition of pill millipede manure of the Western Ghats, India, Journal of Forestry Research, 24, 539-545.Search in Google Scholar
Stašiov S., Hazuchová L., Vician V., Kočík K. and Svitok M., 2014 – Millipede (Diplopoda) communities in agricultural landscape: influence of management form, Polish Journal of Ecology, 62, 3, 587-598.Search in Google Scholar
Steinwandter M., Rief A., Scheu S., Traugott M. and Seeber J., 2018 – Structural and functional characteristics of high alpine soil macro-invertebrate communities, European journal of soil biology, 86, 72-80.Search in Google Scholar
Steinwandter M., Schlick-Steiner B. C., Seeber G. U. H., Steiner F. M. and Seeber J., 2017 – Effects of alpine land-use changes: soil macrofauna community revisited, Ecology and evolution, 7, 14, 5389-5399.Search in Google Scholar
Tóth Z., Hornung E. and Báldi A., 2018 – Effects of set-aside management on certain elements of soil biota and early stage organic matter decomposition in a High Nature Value Area, Hungary, Nature Conservation, 29, 1-26.Search in Google Scholar
Tóth Z., Hornung E., Báldi A. and Kovács-Hostyánszki A., 2016 – Effects of set-aside management on soil macrodecomposers in Hungary, Applied soil ecology, 99, 89-97.Search in Google Scholar
Trabaniño C. R., Pitre H. N., Andrews K. L. and Meckenstock D. H., 1990 – Soil-inhabiting phytophagous arthropod pests in intercropped sorghum and maize in southern Honduras, Turrialba, 40, 2, 172-183.Search in Google Scholar
Van Noordwijk C. G. E., Baeten L., Turin H., Heijerman T., Alders K., Boer P. and Bonte D., 2017 – 17 years of grassland management leads to parallel local and regional biodiversity shifts among a wide range of taxonomic groups, Biodiversity and Conservation, 26, 717-734.Search in Google Scholar
Vohland K. and Schroth G., 1999 – Distribution patterns of the litter macrofauna in agroforestry and monoculture plantations in central Amazonia as affected by plant species and management, Applied Soil Ecology, 13, 1, 57-68.Search in Google Scholar
Wu P., Zhang H. and Wang Y., 2015 – The response of soil macroinvertebrates to alpine meadow degradation in the Qinghai–Tibetan Plateau, China, Applied Soil Ecology, 90, 60-67.Search in Google Scholar
Zulu S. G., Motsa N. M., Sithole N. J., Magwaza L. S. and Ncama K., 2022 – Soil macrofauna abundance and taxonomic richness under long-term no-till conservation agriculture in a semi-arid environment of South Africa, Agronomy, 12, 3, 722.Search in Google Scholar