Papers by Bernard Staniec
Genus. International Journal of Invertebrate Taxonomy, 2010
The pupae of Philonthus politus (Linne, 1758), Gabrius astutus (Erichson, 1840) and Quedius cinct... more The pupae of Philonthus politus (Linne, 1758), Gabrius astutus (Erichson, 1840) and Quedius cinctus (PaykuLL, 1790)
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FIGURES 1–12. G. splendidulus (1–3, 7–10), N. lentus (4–6, 11, 12), mature larva. 1–6, habitus in... more FIGURES 1–12. G. splendidulus (1–3, 7–10), N. lentus (4–6, 11, 12), mature larva. 1–6, habitus in dorsal (1, 4), lateral (2, 5) and ventral (3, 6) aspect; 7–12, seta on pronotum (7), abdominal tergite I (8), abdominal tergite VIII (9), mid femur (10) and abdominal tergite II (11, 12).
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Zootaxa, 2011
The egg of Paederidus ruficollis (Fabricius, 1781) and larvae of that and P. rubrothoracicus carp... more The egg of Paederidus ruficollis (Fabricius, 1781) and larvae of that and P. rubrothoracicus carpathicola Scheerpeltz, 1957 are described and illustrated. This is the first thorough description of immature stages for the genus Paederidus Mulsant & Rey (1878). The immature stages were obtained by rearing adults. Morphological differences between instars of the same species and also between the studied species are found in the detailed structure of the antenna, nasale, maxillary palp, labial palp, tarsungulus and urogomphus; chaetotaxy of pronotum, profemur and protibia; proportions of same body parts; microstructure of urogomphus and body colour. Comparative characters of larvae of two subtribes Paederina and Stilicina are presented.
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ABSTRACT. The pupae of Philonthus umbriatilis (GRAV.), Ph. lepidus (GRAV.) and Bisnius nitidulus ... more ABSTRACT. The pupae of Philonthus umbriatilis (GRAV.), Ph. lepidus (GRAV.) and Bisnius nitidulus (GRAV.) are described and illustrated for the first time. The differences in morphological structure between the examined pupae are presented. A modification of an identification key to known pupae of Central European Staphylininae is also proposed.
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ZooKeys, 2019
This paper is the first comprehensive work on the pupae of Staphylinidae. It is the first-ever at... more This paper is the first comprehensive work on the pupae of Staphylinidae. It is the first-ever attempt to employ the morphological characters of these pupae in phylogenetic analysis. The study shows that the external structures of Staphylinini pupae could be a useful, alternative source for assessing the relationships of certain taxa within a tribe. The paper also includes an illustrated key to the identification of pupae at the subtribe and generic levels (Abemus, Acylophorus, Astrapaeus, Atanygnathus, Bisnius, Creophilus, Emus, Erichsonius, Gabrius, Hesperus, Heterothops, Neobisnius, Ocypus, Ontholestes, Philonthus, Quedius, Quedionuchus, Rabigus, Staphylinus, and Tasgius) of the tribe Staphylinini, found in Europe. Based on current knowledge of the morphology of pupal stages of Staphylinini species, eight morphological pupal types are presented: Acylophorus, Astrapaeus, Atanygnathus, Erichsonius, Heterothops, Philonthus, Quedius and Staphylinus. The paper also comments on pupal h...
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International Journal of Molecular Sciences, 2021
Six new water extracts (E1–E6) were obtained from nest carton produced by jet black ants Lasius f... more Six new water extracts (E1–E6) were obtained from nest carton produced by jet black ants Lasius fuliginosus and tested for their biochemical and bioactive properties, including antioxidative and anticancer effects. The present study demonstrated significant qualitative and quantitative differences in the content of individual biochemical constituents, as well as bioactive properties between the investigated samples. All tested extracts demonstrated antioxidant properties (determined using 2,2-diphenyl-1-picrylhydrazyl (DPPH) and 2,2’-azino-bis(3-ethylbenzothiazoline-6-sulfonic acid (ABTS) methods), and the highest antioxidative potential was recorded in extracts E1 and E2 (188.96 and 313.67 μg/mL of ascorbic acid equivalent for ABTS and 176.42 and 202.66 μg/mL for DPPH reagent). Furthermore the six extracts exhibited strong inhibitory activity towards human melanoma cells of the A-375 CRL-1619 line in a dose-dependent manner. The most interesting chemopreventive activity was exhibit...
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Table S1. Detailed taxonomic analyses at different ranks with the data obtained for the samples t... more Table S1. Detailed taxonomic analyses at different ranks with the data obtained for the samples tested.Figure S1. Detailed taxonomic analyses at different ranks. Sunburst charts show the relative abundance of microbial 16S rDNA sequences at different taxonomic levels. The first level represents the kingdom; the second level represents all phyla present in a particular sample; subsequent next levels represent the class, order, family and genus.<br>
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FIGURES 56–60. Pupa of S. erythropterus. (56) Ventral aspect; (57) lateral aspect with proturbera... more FIGURES 56–60. Pupa of S. erythropterus. (56) Ventral aspect; (57) lateral aspect with proturberances on middle femur (57A) and setiform projection on pronotum (57B); (58) dorsal aspect with atrophied spiracle (58A) and marginal projection (58B); (59, 60) terminal sternite of male (59) and female (60) with terminal prolongation (60A).
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FIGURES 86–95. G. splendidulus (86–90, 92–94), N. lentus (91, 95). 86, gland on epicranial suture... more FIGURES 86–95. G. splendidulus (86–90, 92–94), N. lentus (91, 95). 86, gland on epicranial suture; 87, sensillum of fore region of tergite V; 88, microstructure of region on thoracic stigma; 89, microstructure of hind region of mesonotum; 90, 91, microstructure of abdominal tergite II; 92, microstructure of abdominal tergite IX; 93, microstructure of first article of urogom- phus; 94, 95, microstructure of abdominal sternite X.
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FIGURES 19–24. Thiasophila angulata (Erichson, 1837), mature larva. (19) Labrum with a pair of pe... more FIGURES 19–24. Thiasophila angulata (Erichson, 1837), mature larva. (19) Labrum with a pair of peg-shaped setae (A) and microstructure of membrane area (B); (20) epipharynx with anterior pores (20A), central pores and microtrichia (20B) and cuticular processes (20C); (21, 23) left mandibles in dorsal aspect (21) and ventral aspect (23); (22, 24) right mandible in dorsal aspect (22) and ventral aspect (24). Abbreviations: Ld—labral dorsal setae; Ll—labral lateral setae; Lm—labral marginal setae.
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FIGURES 41–45. Thiasophila angulata (Erichson, 1837), abdomen, first larval instar (41, 43), matu... more FIGURES 41–45. Thiasophila angulata (Erichson, 1837), abdomen, first larval instar (41, 43), mature larva (42, 44, 45). (41) Tergite I and II with egg-busters (41A); (42) tergite I with microstructure (42A); (43) sternite I and II with microstructure (43A); (44) sternite I; (45) seternite II with microstructure (45A) and olfactory organs probably (45B). Abbreviations: setae: A—anterior, D—discal, L—lateral, P—posterior; C—campaniform sensilla; Sp—spiracle.
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FIGURES 50–57. Thiasophila angulata (Erichson, 1837), abdomen in lateral aspect, first larval ins... more FIGURES 50–57. Thiasophila angulata (Erichson, 1837), abdomen in lateral aspect, first larval instar (52, 54, 57), mature larva (50, 51, 53, 55, 56). (50, 51, 52) I and II segment with structure of spiracles (50A, 51A); (53, 54, 56) VIII, IX and X segment with microstructure of segment X (54A, 56A); (55, 57) right urogomphus. Abbreviations: I, II—segments of urogomphus; Sp—spiracle; Ug—urogomphus.
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Figure 6. Chromatograph of the defensive secretion of T. angulata adults. The numbers in the chro... more Figure 6. Chromatograph of the defensive secretion of T. angulata adults. The numbers in the chromatogram refer to the number of the chemicals in Table 3.
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Figure 2. Seasonal dynamics of T. angulata adult forms in nests of F. polyctena and F. rufa and o... more Figure 2. Seasonal dynamics of T. angulata adult forms in nests of F. polyctena and F. rufa and of T. szujeckii in nests of F. truncorum. Leżajsk Forest Division, Sandomierz Basin, Poland.
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FIGURES 52 – 70. Pupa of Bisnius fimentarius (52, 61, 62), Gabrius osseticus (53, 58, 63, 64), Ph... more FIGURES 52 – 70. Pupa of Bisnius fimentarius (52, 61, 62), Gabrius osseticus (53, 58, 63, 64), Philonthus atratus (54, 59, 65), P. carbonarius (55, 66), P. debilis (56, 60, 68 – 70) and P. d e c o r u s (57, 67). (52 – 60) The first pair of functional spiracles; (61 – 70) atrophied spiracles.
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FIGURES 26–34. Dorcatoma sp., mature larva. 26–27, 33, thorax in lateral (26) and ventral (27) as... more FIGURES 26–34. Dorcatoma sp., mature larva. 26–27, 33, thorax in lateral (26) and ventral (27) aspects, 33, spiracle of ThI; 28, fore leg; 29–30, 31–32, 34, abdomen in lateral (29) and ventral (30) aspect, abdominal setae (31), spiracle of III abdominal segment; 32, terminal segments of abdomen. Abbreviations: III–X, abdominal segments; A, alar area; Cx, coxa; D, dorsal lobe; D1–2, dorsal sclerites I–II; Ep, epipleuron; Fe, femur; L, lateral lobe; Lst, laterosternum; Msv, mesoventrite; Mtv, metaventrite; Pd, postdorsum; Pl, pleuron; Pr, prodorsum; Prn, pronotum; Prv, proventrite; S, spiracle; St, sternum; T, terminal lobes; Tb, tibia; Tg, tarsungulus; ThI–III, thoracic segments I–III; Tr, trochanter.
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FIGURES 10–16. Dorcatoma sp., mature larva. 10–11, right antenna in dorsal (10) and lateral (11) ... more FIGURES 10–16. Dorcatoma sp., mature larva. 10–11, right antenna in dorsal (10) and lateral (11) aspects; 12–13, labrum in frontal aspect; 14, labrum, anteroventral part with digitate setae; 15–16, epipharynx. Abbreviations: Cl, clypeus; Ep, epipharynx; Lr, labrum; S1–3, setae of antenna; Se, sensorium of antenna.
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FIGURES 30–39. G. splendidulus (30, 32, 36, 38), N. lentus (31, 33–35, 37, 39), mature larva. 30,... more FIGURES 30–39. G. splendidulus (30, 32, 36, 38), N. lentus (31, 33–35, 37, 39), mature larva. 30, 31, right antenna in dorsal aspect; 32, 33, terminal portion of antenna in dorsal aspect; 34, region of sensory appendage (Sa) of antennal article III; 35, apex of antennal article IV; 36, 37, labrum; 38, 39, epipharynx. Abbreviations: At antennae, Lt lateral tooth, Mt median tooth, Pmt paramedian tooth, S solenidia, Sa sensory appendage.
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FIGURES 13–18. G. splendidulus (13, 15, 17), N. lentus (14, 16, 18), mature larva. 13–18, head in... more FIGURES 13–18. G. splendidulus (13, 15, 17), N. lentus (14, 16, 18), mature larva. 13–18, head in dorsal (13, 14), lateral (15, 16) and ventral (17, 18) aspect. Abbreviations: Ap apotome, E epicranial region of head, Es dorsal ecdysial lines, Gl gland, Na nasale, P posterior region of head, Tp tentorial pits.
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FIGURE 9. Q. brevis (A – G) mature larvae, thorax and abdomen. A – C, pro- (A), meso- (B), metano... more FIGURE 9. Q. brevis (A – G) mature larvae, thorax and abdomen. A – C, pro- (A), meso- (B), metanotum (C) in dorsal aspect; D, setae on mesonotum; E – F, apex of setae on mesonotum; G, abdominal segment I and II in dorsal aspect. Abbreviations: I – III, segments; Te, tergite.
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Papers by Bernard Staniec