The Miltochrista obliquilinea (Swinhoe, 1901) species-group is revised. Four new species are described: M. konta Volynkin, Černý N. Singh, sp. n. (Thailand, Laos and Vietnam), M. adelfika Volynkin, N. Singh, Černý, Kirti Datta, sp. n. (India, Myanmar, China, Thailand, Laos and Vietnam), M. stenovalva Volynkin, N. Singh, Černý, Kirti Datta, sp. n. (India and Thailand) and M. lavides Volynkin, Černý N. Singh, sp. n. (Malaysia, Thailand, Myanmar, Laos and Vietnam). The lectotype for Lyclene obliquilinea Swinhoe, 1901 is designated. Adults, male and female genitalia are illustrated.
The first representative of the genus Cerapus in Malaysian waters, Cerapus bumbumiensis sp. nov. is described from specimens sampled from Pulau Bum Bum, Sabah (east Malaysia). The main identifying characteristics of this new amphipod species are: pereonites 1, 2 with constriction; male gnathopod 2 carpochelate, carpus large with long defining posterior tooth and well-developed anterodistal tooth; pereopod 6 coxa with fine hair/fringe setae ventrally; and telson with deep cleft. An updated identification key for the 23 known species in the genus is also presented.
The genus Olios Walckenaer, 1837 is revised, a generic diagnosis is given and an identification key to eight species groups is provided. Olios in its revised sense includes 87 species and is distributed in Africa, southern Europe and Asia. Three species groups are revised in this first part, an identification key to species for each group is provided, five new species are described and all included species are illustrated. The Olios argelasius-group includes O. argelasius Walckenaer, 1806, O. canariensis (Lucas, 1838), O. pictus (Simon, 1885), O. fasciculatus Simon, 1880 and O. kunzi spec. nov. (male, female; Namibia, Zambia, South Africa); it is distributed in the Mediterranean region, northern Africa including Canary Islands, in the Middle East, South Sudan, East Africa, and southern Africa. The Olios coenobitus-group includes O. angolensis spec. nov. (male; Angola), O. coenobitus Fage, 1926, O. denticulus spec. nov. (male; Java), O. erraticus Fage, 1926, O. gambiensis spec. nov. (male, female; Gambia), O. milleti (Pocock, 1901b), O. mordax (O. Pickard-Cambridge, 1899) and O. pusillus Simon, 1880; it is distributed in Africa (Gambia, Angola, Tanzania, Madagascar) and Asia (India, Sri Lanka, Indonesia: Java). The Olios auricomis-group includes only O. auricomis (Simon, 1880), distributed in Africa south of 10°N. Other species groups are introduced briefly and will be revised in forthcoming revisions. The Olios correvoni-group includes currently O. claviger (Pocock, 1901a), O. correvoni Lessert, 1921, O. correvoni choupangensis Lessert, 1936, O. darlingi (Pocock, 1901a), O. faesi Lessert, 1933, O. freyi Lessert, 1929, O. kassenjicola Strand, 1916b, O. kruegeri (Simon, 1897a), O. quadrispilotus (Simon, 1880) comb. nov., O. lucieni comb. nov. nom. nov., O. sjostedti Lessert, 1921 and O. triarmatus Lessert, 1936; it is distributed in Africa (Zimbabwe, Tanzania incl. Zanzibar, Angola, Congo, Central Africa, South Africa, Botswana; O. darlingi was recorded from Zimbabwe and Botswana and not from South Africa). The Olios rossettii-group includes: O. baulnyi (Simon, 1874), O. bhattacharjeei (Saha Raychaudhuri, 2007), O. brachycephalus Lawrence, 1938, O. floweri Lessert, 1921, O. jaldaparaensis Saha Raychaudhuri, 2007, O. japonicus Jäger Ono, 2000, O. kolosvaryi (Caporiacco, 1947b) comb. nov., O. longipes (Simon, 1884b), O. lutescens (Thorell, 1894), O. mahabangkawitus Barrion Litsinger, 1995, O. obesulus (Pocock, 1901b), O. rossettii (Leardi, 1901), O. rotundiceps (Pocock, 1901b), O. sericeus (Kroneberg, 1875), O. sherwoodi Lessert, 1929, O. suavis (O. Pickard-Cambridge, 1876), O. tarandus (Simon, 1897d), O. tener (Thorell, 1891) and O. tiantongensis (Zhang Kim, 1996); it is distributed in the Mediterranean region, in Africa (especially eastern half) and Asia (Middle East and Central Asia to Japan, Philippines and Java). The Olios nentwigi-group includes O. diao Jäger, 2012, O. digitatus Sun, Li Zhang, 2011, O. jaenicke Jäger, 2012, O. muang Jäger, 2012, O. nanningensis (Hu Ru, 1988), O. nentwigi spec. nov. (male, female; Indonesia: Krakatau), O. perezi Barrion Litsinger, 1995, O. scalptor Jäger Ono, 2001 and O. suung Jäger, 2012; it is distributed in Asia (Thailand, Laos, Vietnam, Cambodia, China, Taiwan, Indonesia, Philippines), Papua New Guinea and Mariana Islands. Olios diao is newly recorded from Cambodia and Champasak Province in Laos. The Olios stimulator-group includes O. admiratus (Pocock, 1901b), O. hampsoni (Pocock, 1901b), O. lamarcki (Latreille, 1806) and O. stimulator Simon, 1897c; it is distributed in Africa (Madagascar, Seychelles), Middle East and South Asia (United Arab Emirates, Iraq, Afghanistan, Pakistan, India, Maldives, Sri Lanka). The Olios hirtus-group includes O. bungarensis Strand, 1913b, O. debalae (Biswas Roy, 2005), O. ferox (Thorell, 1892), O. hirtus (Karsch, 1879a), O. igraya (Barrion Litsinger, 1995) comb. nov., O. menghaiensis (Wang Zhang, 1990), O. nigrifrons (Simon, 1897b), O. punctipes Simon, 1884a, O. punctipes sordidatus (Thorell, 1895), O. pyrozonis (Pocock, 1901b), O. sungaya (Barrion Litsinger, 1995) comb. nov., O. taprobanicus Strand, 1913b and O. tikaderi Kundu et al., 1999; it is distributed in South, East and Southeast Asia (Sri Lanka, India, Nepal, Bangladesh, Myanmar, China, Laos, Thailand, Cambodia, Vietnam, Malaysia, Indonesia, Philippines). Nineteen synonyms are recognised: Nisueta Simon, 1880, Nonianus Simon, 1885, both = Olios syn. nov.; O. spenceri Pocock, 1896, O. werneri (Simon, 1906a), O. albertius Strand, 1913a, O. banananus Strand, 1916a, O. aristophanei Lessert, 1936, all = O. fasciculatus; O. subpusillus Strand, 1907c = O. pusillus; O. schonlandi (Pocock, 1900b), O. rufilatus Pocock, 1900c, O. chiracanthiformis Strand, 1906, O. ituricus Strand, 1913a, O. isongonis Strand, 1915, O. flavescens Caporiacco, 1941 comb. nov., O. pacifer Lessert, 1921, all = O. auricomis; Olios sanguinifrons (Simon, 1906b) = O. rossettii Leardi, 1901; O. phipsoni (Pocock, 1899), Sparassus iranii (Pocock, 1901b), both = O. stimulator; O. fuligineus (Pocock, 1901b) = O. hampsoni. Nine species are transferred to Olios: O. gaujoni (Simon, 1897b) comb. nov., O. pictus comb. nov., O. unilateralis (Strand, 1908b) comb. nov. (all three from Nonianus), O. affinis (Strand, 1906) comb. nov., O. flavescens Caporiacco, 1941 comb. nov., O. quadrispilotus comb. nov., O. similis (Berland, 1922) comb. nov. (all four from Nisueta), O. sungaya (Barrion Litsinger, 1995) comb. nov., O. igraya (Barrion Litsinger, 1995) comb. nov. (both from Isopeda L. Koch 1875). Olios lucieni nom. nov. comb. nov. is proposed for Nisueta similis Berland, 1922, which becomes a secondary homonym. The male of O. quadrispilotus comb. nov. is described for the first time. Sixteen species are currently without affiliation to one of the eight species groups: O. acolastus (Thorell, 1890), O. alluaudi Simon, 1887a, O. batesi (Pocock, 1900c), O. bhavnagarensis Sethi Tikader, 1988, O. croseiceps (Pocock, 1898b), O. durlaviae Biswas Raychaudhuri, 2005, O. gentilis (Karsch, 1879b), O. gravelyi Sethi Tikader, 1988, O. greeni (Pocock, 1901b), O. inaequipes (Simon 1890), O. punjabensis Dyal, 1935, O. ruwenzoricus Strand, 1913a, O. senilis Simon, 1880, O. somalicus Caporiacco, 1940, O. wroughtoni (Simon, 1897c) and O. zulu Simon, 1880. Five of these species are illustrated in order to allow identification of the opposite (male) sex and to settle their systematic placement. Thirty-seven species are considered nomina dubia, mostly because they were described from immatures, three of them are illustrated: O. abnormis (Blackwall, 1866), O. affinis (Strand, 1906) comb. nov., O. africanus (Karsch, 1878), O. amanensis Strand, 1907a, O. annandalei (Simon, 1901), O. bivittatus Roewer, 1951, O. ceylonicus (Leardi, 1902), O. conspersipes (Thorell, 1899), Palystes derasus (C.L. Koch, 1845) comb. nov., O. detritus (C.L. Koch, 1845), O. digitalis Eydoux Souleyet, 1842, O. exterritorialis Strand, 1907b, O. flavovittatus (Caporiacco, 1935), O. fugax (O. Pickard-Cambridge, 1885), O. guineibius Strand, 1911c, O. guttipes (Simon, 1897a), O. kiranae Sethi Tikader, 1988, O. longespinus Caporiacco, 1947b, O. maculinotatus Strand, 1909, O. morbillosus (MacLeay, 1827), O. occidentalis (Karsch, 1879b), O. ornatus (Thorell, 1877), O. pagurus Walckenaer, 1837, O. patagiatus (Simon, 1897b), O. praecinctus (L. Koch, 1865), O. provocator Walckenaer, 1837, O. quesitio Moradmand, 2013, O. quinquelineatus Taczanowski, 1872, O. sexpunctatus Caporiacco, 1947a, Heteropoda similaris (Rainbow, 1898) comb. rev., O. socotranus (Pocock, 1903), O. striatus (Blackwall, 1867), O. timidus (O. Pickard-Cambridge, 1885), Remmius variatus (Thorell, 1899) comb. nov., O. vittifemur Strand, 1916b, O. wolfi Strand, 1911a and O. zebra (Thorell, 1881). Eighty-nine species are misplaced in Olios but cannot be affiliated to any of the known genera. They belong to the subfamilies Deleninae Hogg, 1903, Sparassinae Bertkau, 1872 and Palystinae Simon, 1897a, nineteen of them are illustrated: O. acostae Schenkel, 1953, O. actaeon (Pocock, 1898c), O. artemis Hogg, 1915, O. atomarius Simon, 1880, O. attractus Petrunkevitch, 1911, O. auranticus Mello-Leitão, 1918, O. benitensis (Pocock, 1900c), O. berlandi Roewer, 1951, O. biarmatus Lessert, 1925, O. canalae Berland, 1924, O. caprinus Mello-Leitão, 1918, O. chelifer Lawrence, 1937, O. chubbi Lessert, 1923, O. clarus (Keyserling, 1880), O. coccineiventris (Simon, 1880), O. corallinus Schmidt, 1971, O. crassus Banks, 1909, O. debilipes Mello-Leitão, 1945, O. discolorichelis Caporiacco, 1947a, O. erroneus O. Pickard-Cambridge, 1890, O. extensus Berland, 1924, O. fasciiventris Simon, 1880 , O. feldmanni Strand, 1915, O. fimbriatus Chrysanthus, 1965, O. flavens Nicolet, 1849, O. fonticola (Pocock, 1902), O. formosus Banks, 1929, O. francoisi (Simon, 1898a), O. fulvithorax Berland, 1924, O. galapagoensis Banks, 1902, O. gaujoni (Simon, 1897b) comb. nov., O. giganteus Keyserling, 1884, O. hoplites Caporiacco, 1941, O. humboldtianus Berland, 1924, O. insignifer Chrysanthus, 1965, O. insulanus (Thorell, 1881), O. keyserlingi (Simon, 1880), O. lacticolor Lawrence, 1952, O. lepidus Vellard, 1924, O. longipedatus Roewer, 1951, O. machadoi Lawrence, 1952, O. macroepigynus Soares, 1944, O. maculatus Blackwall, 1862, O. marshalli (Pocock, 1898a), O. mathani (Simon, 1880), O. minensis Mello-Leitão, 1917, O. monticola Berland, 1924, O. mutabilis Mello-Leitão, 1917, O. mygalinus Doleschall, 1857, O. mygalinus cinctipes Merian, 1911, O. mygalinus nirgripalpis Merian, 1911, O. neocaledonicus Berland, 1924, O. nigristernis (Simon, 1880), O. nigriventris Taczanowski, 1872, O. oberzelleri Kritscher, 1966, O. obscurus (Keyserling, 1880), O. obtusus F.O. Pickard-Cambridge, 1900, O. orchiticus Mello-Leitão, 1930, O. oubatchensis Berland, 1924, O. paraensis (Keyserling, 1880), O. pellucidus (Keyserling, 1880), O. peruvianus Roewer, 1951, O. pictitarsis Simon, 1880, O. plumipes Mello-Leitão, 1937, O. princeps Hogg, 1914, O. pulchripes (Thorell, 1899), O. puniceus (Simon, 1880), O. roeweri Caporiacco, 1955a, O. rubripes Taczanowski, 1872, O. rubriventris (Thorell, 1881), O. rufus Keyserling, 1880, O. sanctivincenti (Simon, 1898b), O. similis (O. Pickard-Cambridge, 1890), O. simoni (O. Pickard-Cambridge, 1890), O. skwarrae Roewer, 1933, O. spinipalpis (Pocock, 1901a), O. stictopus (Pocock, 1898a), O. strandi Kolosváry, 1934, O. subadultus Mello-Leitão, 1930, O. sulphuratus (Thorell, 1899), O. sylvaticus (Blackwall, 1862), O. tamerlani Roewer, 1951, O. tigrinus (Keyserling, 1880), O. trifurcatus (Pocock, 1900c), O. trinitatis Strand, 1916a, O. velox (Simon, 1880), O. ventrosus Nicolet, 1849, O. vitiosus Vellard, 1924 and O. yucatanus Chamberlin, 1925. Seventeen taxa are transferred from Olios to other genera within Sparassidae, eight of them are illustrated: Adcatomus luteus (Keyserling, 1880) comb. nov., Eusparassus flavidus (O. Pickard-Cambridge, 1885) comb. nov., Palystes derasus (C.L. Koch, 1845) comb. nov., Heteropoda similaris (Rainbow, 1898) comb. rev., Remmius variatus (Thorell, 1899) comb. nov., Nolavia audax (Banks, 1909) comb. nov., Nolavia antiguensis (Keyserling, 1880) comb. nov., Nolavia antiguensis columbiensis (Schmidt, 1971) comb. nov., Nolavia fuhrmanni (Strand, 1914) comb. nov., Nolavia helva (Keyserling, 1880) comb. nov., Nolavia stylifer (F.O. Pickard-Cambridge, 1900) comb. nov., Nolavia valenciae (Strand, 1916a) comb. nov., Nungara cayana (Taczanowski, 1872) comb. nov., Polybetes bombilius (F.O. Pickard-Cambridge, 1899) comb. nov., Polybetes fasciatus (Keyserling, 1880) comb. nov., Polybetes hyeroglyphicus (Mello-Leitão, 1918) comb. nov. and Prychia paalonga (Barrion Litsinger, 1995) comb. nov. One species is transferred from Olios to the family Clubionidae Wagner, 1887: Clubiona paenuliformis (Strand, 1916a) comb. nov.
Leptin, an adipocyte-derived hormone, serves numerous physiological functions in the body, particularly during puberty and reproduction. The exact mechanism by which leptin activates the gonadotropin-releasing hormone (GnRH) neurons to trigger puberty and reproduction remains unclear. Given the widespread distribution of leptin receptors in the body, both central and peripheral mechanisms involving the hypothalamic-pituitary-gonadal axis have been hypothesized. Leptin is necessary for normal reproductive function, but when present in excess, it can have detrimental effects on the male reproductive system. Human and animal studies point to leptin as a link between infertility and obesity, a suggestion that is corroborated by findings of low sperm count, increased sperm abnormalities, oxidative stress, and increased leptin levels in obese men. In addition, daily leptin administration to normal-weight rats has been shown to result in similar abnormalities in sperm parameters. The major pathways causing these abnormalities remain unidentified; however, these adverse effects have been attributed to leptin-induced increased oxidative stress because they are prevented by concurrently administering melatonin. Studies on leptin and its impact on sperm function are highly relevant in understanding and managing male infertility, particularly in overweight and obese men.
Matched MeSH terms: Infertility, Male/etiology; Infertility, Male/physiopathology*; Male
This study aims to explore the impact of the Covid-19 pandemic on tourists' travel risk and management perceptions. Driven on the effect of the pandemic, we investigate tourists' travel risk and management perceptions and its effect on society using a sample of 716 respondents. The data was collected through social media platforms using a representative sampling method and analyzed applying the PLS-SEM tool. The findings reveal that Covid-19 pandemic has greatly affected travel risk and management perceptions. Travel risk and management perception had a significant association with risk management, service delivery, transportation patterns, distribution channels, avoidance of overpopulated destinations, and hygiene and safety. The results also identified the mediating effect of travel risk and management perceptions. The finding of this study contributes to tourism crises and provides future research insights in the travel and tourism sector and response to change tourists' travel risk and management perceptions in the post-covid recovery period.
Older adults, especially men and/or those with diabetes, hypertension, and/or obesity, are prone to severe COVID-19. In some countries, older adults, particularly those residing in nursing homes, have been prioritized to receive COVID-19 vaccines due to high risk of death. In very rare instances, the COVID-19 vaccines can induce anaphylaxis, and the management of anaphylaxis in older people should be considered carefully. An ARIA-EAACI-EuGMS (Allergic Rhinitis and its Impact on Asthma, European Academy of Allergy and Clinical Immunology, and European Geriatric Medicine Society) Working Group has proposed some recommendations for older adults receiving the COVID-19 vaccines. Anaphylaxis to COVID-19 vaccines is extremely rare (from 1 per 100,000 to 5 per million injections). Symptoms are similar in younger and older adults but they tend to be more severe in the older patients. Adrenaline is the mainstay treatment and should be readily available. A flowchart is proposed to manage anaphylaxis in the older patients.
Three urban public primary schools in the district of Petaling, Selangor were surveyed for obesity amongst the schoolchildren and factors related to it. The prevalence of obesity amongst primary schoolchildren, with the mean age of 8.91 years was 9.5%. In addition, it was more prevalent among the boys (p
We consider an optimal quantum key distribution setup based on minimal number of measurement bases with binary yields used by parties against an eavesdropper limited only by the no-signaling principle. We note that in general, the maximal key rate can be achieved by determining the optimal tradeoff between measurements that attain the maximal Bell violation and those that maximise the bit correlation between the parties. We show that higher correlation between shared raw keys at the expense of maximal Bell violation provide for better key rates for low channel disturbance.