TOKINA ATX-i 100mm Macro Ranking TOP2 F2.8 for Mount Nikon F $300 TOKINA ATX-i 100mm Macro F2.8 for Nikon F Mount Electronics Camera Photo Lenses /eliquate351599.html,ATX-i,angelorayer.com,F2.8,F,$300,Nikon,for,TOKINA,Macro,100mm,Electronics , Camera Photo , Lenses,Mount $300 TOKINA ATX-i 100mm Macro F2.8 for Nikon F Mount Electronics Camera Photo Lenses /eliquate351599.html,ATX-i,angelorayer.com,F2.8,F,$300,Nikon,for,TOKINA,Macro,100mm,Electronics , Camera Photo , Lenses,Mount TOKINA ATX-i 100mm Macro Ranking TOP2 F2.8 for Mount Nikon F
The Tokina atx-i 100mm F2.8 FF MACRO is a compact medium tele macro lens for full frame format film and digital SLR cameras. Being light-weight, compact, performing high resolution, fast aperture, low distortion, low falloff and beautiful soft bokeh this lens is extremely attractive tool for macro, portraits, landscapes, street art, commercial and general purpose shooting. The optical design of Tokina atx-i 100mm F2.8 FF MACRO features zero curvature of field and extremely low distortion while maintaining super high resolution across the entire image along with low falloff and perfectly controlled chromatic aberration. Multi-coating applied to optical elements effectively control flare and ghosting. The front of the lens has a 55mm filter threads which extends during the focusing but does not rotate. This allows different filters including polarizers to be used for landscape or product photography. The direction of the manual focusing ring matches the proprietary direction of Nikon and Canon lenses. The front of the lens has a 55mm filter threads which extends during the focusing but does not rotate. This allows different filters including polarizers to be used for landscape or product photography. The Tokina atx-i 100mm F2.8 FF MACRO Nikon F mount is equipped with manual aperture ring based on Ai AF Nikkor D-Type* lens standard that allows to use this lens with wide variety of cameras including old Nikon film cameras. *When used with Nikon DSLRs that do not have a focus motor in the camera body like D3000 and D5000 series only MF mode is available. Highly valued One-touch focus Clutch mechanism allows to switch between autofocus and manual focus easy.
Focal Distance :100mm
Minimum Aperture :F2.8
Maximum Aperture :F32
Lens Configuration: 9-8 (elements/groups)
Angle of View: 24Â°
Minimum FocusDistance: 0.3m
Macro Ratio: 1:1
Focus Method: Extending barrel
Diaphragm blades: 9
Filter size: 55mm
Nikon F mount: 95.2mm
Canon EF mount: 97.7mm
Maximum diameter: 73mm
Nikon F mount: 515g
Canon EF mount: 525g
The zebrafish is a small tropical fish that has become one of the favoured animal model systems for research in many areas including embryonic development, genetic analyses of disease, neural circuit function and behaviour. One reason for this popularity is that zebrafish embryos are optically transparent and genetically tractable making them ideally suited for studies of cell and tissue behaviour and function. Zebrafish also exhibit sleep, social, hunting and other complex behaviours and progress in understanding the neuroanatomy of the brain is facilitating studies of the neural circuits mediating these behaviours.
On this site, you can learn about the wide range of research projects at UCL that use zebrafish and see many beautiful images and movies from these projects. We appreciate that not all our visitors are trained scientists and so we have public outreach pages that help to explain what we do.
There are many research groups using zebrafish for research at UCL and you can find out about some of them here, or continue reading about Zebrafish at UCL.
Zebrafish research at UCL is supported by a team of core staff, who you can read about here.
COVID 19 UPDATE: Due to the current situation ZebrafishUCL are unable to offer any work-experience placements or lab visits this or next academic year(2020/2021). For more information about the programme click button below.
Many of our images are available for download from Wellcome Images.
Simply search the collection for 'Zebrafish'. All images and movies are copyright of UCL Zebrafish Group please request permission before using.
In the fish labs we love doing experiments, but we also love sharing our enthusiasm for science and for zebrafish with others. That is why we take our outreach activities very seriously.
We are committed to promoting science, critical thinking and education of young people via our Outreach Activities. Our aim is to reach students from all backgrounds, help them to engage with STEM and to gain an insight into the opportunities available in higher education and STEM research.
COVID 19 UPDATE: Due to the current situation ZebrafishUCL are unable to offer any workexperience placements or lab visits this or next academic year(2020/2021).
We offer a range of outreach activities, both ‘in classroom’ workshops, as well as ‘on-campus’ at UCL. Please choose an option below to explore our outreach programs. Please note that only teachers may request school visits from zebrafish researchers(LAB2SCHOOL) and visits to the zebrafish lab for school students(SCHOOL2LAB).
NB: As we are a research lab, we can only offer the outreach activities mentioned above to a limited number of students and school groups. We hope, that we can expand our programme in the future to offer these opportunities to more and more students!
Read about what the Zebrafish Lab have been doing to spread our love of science.
ZebrafishUCL are focussing on 3 key areas to make our research more sustainable. Please follow the links below to read more about how we are reducing single-use plastics, energy consumption and other cultural changes to improve sustainability in our lab.
CULTURE OF CHANGE
For a full list of Zebrafish UCL publications by year click here, or choose a year below. You can also visit our publication summaries page to find summaries of papers that need less scientific knowledge to understand.
Kroll F, Powell GT, Ghosh M, Antinucci P, Hearn TJ, Tunbak H, Lim S, Dennis HW, Fernandez JM, Hoffman EJ, Whitmore D, Dreosti E, Wilson SW and Rihel J (2021).
A simple and effective F0 knockout method for rapid screening of behaviour and other complex phenotypes.
Barlow IL, Mackay E, Wheater E, Goel A, Lim S, Zimmerman S, Woods I, Prober DA, Rihel J (preprint).
A genetic screen identifies dreammist as a regulator of sleep.
bioRxiv 2020.11.18.388736; doi: https://doi.org/10.1101/2020.11.18.388736
Rihel J (2020).
Sleep Across the Animal Kingdom. in Sleep Science
Oxford University Press, pages 15-31
Ozcan GG, Lim S, Leighton PLA, Allison WT, Rihel J (2020).
Sleep is bi-directionally modified by amyloid beta oligomers.
Elife Jul 14;9:e53995. doi: 10.7554/eLife.53995
Haas AJ, Zhini C, Ruppel A, Hartmann C, Ebnet K, Tada M, Balda M, Matter K (2020)
Interplay between extracellular matrix stiffness and JAM-A regulates mechanical load on ZO-1 and tight junction assembly.
Cell Reports 32, 107924.
Takeuchi Y, Narumi R, Akiyama R, Vitiello E, Shirai T, Tanimura N, Kuromiya K, Ishikawa S, Kajita M, Tada M, Haraoka Y, Akieda Y, Ishitani T, Fujioka Y, Ohba Y, Yamada S, Hosokawa Y, Toyama Y, Matsui T, Fujita Y (2020)
MagnetRXÃÂ® Ultra Strength Magnetic Anklet for Women - Arthriti
Curr. Biol. 30, 670-681.
Griffiths VA, Valera AM, Lau JYN, Ros H, Marin B, Baragli C, Coyle D, Evans GJ, Konstantinou G, Younts TJ, Koimtzis T, Srinivas Nadella KMN, Kirkby PA, Bianco IH and Silver RA.
Real-time 3D movement correction for two-photon imaging in behaving animals.
Nat Methods (2020). doi.org/10.1038/s41592-020-0851-7
Hande Tunbak, Mireya Vazquez-Prada, Thomas Ryan, Adam R. Kampff and Elena Dreosti
Whole-brain mapping of socially isolated zebrafish reveals that lonely fish are
eLife (2020);9:e55863 DOI: 10.7554/eLife.55863
Mione MC, Blader P, Del Bene F, Trompouki E and Bianco IH.
Flexzion Digital Electronic Roll Up Drum Pad Set Kit - Portable
Frontiers in Cell and Developmental Biology (2020)
Ghosh M and Rihel J
Hierarchical compression reveals sub-second to day-long structure in larval zebrafish behaviour.
Dreosti E, Hoffman EJ, and Rihel J
Modelling autism spectrum disorders in zebrafish.
In: Gerlai RT (ed). Behavioral and Neural Genetics of Zebrafish(2020). San Diego: Elsevier Inc./Academic Press: pp-pp. 451-471
Lyons DG and Rihel J
Sleep circuits and physiology in non-mammalian systems.
Current Opinion in Physiology (2020).https://doi.org/10.1016/j.cophys.2020.03.006
Antinucci P*, Dumitrescu AS*, Deleuze C, Morley HJ, Leung K, Hagley T, Kubo F, Baier H, Bianco IH*, Wyart C*.
A calibrated optogenetic toolbox of stable zebrafish opsin lines.
eLife (2020) 9:e54937 10.7554/eLife.54937
Folgueira M, Riva-Mendoza S, Ferreño-Galmán N, Castro A, Bianco IH, Anadón R and Yáñez J. Anatomy and Connectivity of the Torus Longitudinalis of the Adult Zebrafish.
Front. Neural Circuits (2020) 14:8. ZOUSHUAIDEDIAN Electronic Feet Callus Remover, Electric Foot Fil
Schwayer C, Shamipour S, Pranjic-Ferscha K, Schauer A, Balda M, Tada M, Matter K, Heisenberg CP (2019)
Mechanosensation of tight junctions depends on ZO-1 phase separation and flow.
Cell 179, 937-952.
Gebhardt C, Auer TO, Henriques PM, Rajan G, Duroure K, Bianco IH*, Del Bene F*.
An interhemispheric neural circuit allowing binocular integration in the optic tectum.
Nature Communications (2019) 10, 5471.
Shibata-Germanos, S., Goodman, J.R., Grieg, A. et al.
Structural and functional conservation of non-lumenized lymphatic endothelial cells in the mammalian leptomeninges.
Acta Neuropathol (2019). https://doi.org/10.1007/s00401-019-02091-z
Sabine Reichert, Oriol Pavón Arocas, Jason Rihel
The Neuropeptide Galanin Is Required for Homeostatic Rebound Sleep following Increased Neuronal Activity
Neuron (2019) DOI:https://doi.org/10.1016/j.neuron.2019.08.010
Ingrid Lekk , Véronique Duboc, Ana Faro, Stephanos Nicolaou, Patrick Blader, Stephen W Wilson.
Sox1a mediates the ability of the parapineal to impart habenular left-right asymmetry.
eLife 2019;8:e47376 DOI: 10.7554/eLife.47376
Henriques PM, Rahman N, Jackson SE, Bianco IH.
Nucleus Isthmi is required to sustain target pursuit during visually guided prey-catching.
Current Biology (2019) 29:1771-1786. doi.org/10.1016/j.cub.2019.04.064
Lau JYN, Bianco IH, Severi KE.
Cellular-level understanding of supraspinal control: what can be learned from zebrafish?
Curr Opin Physiol (2019) 8:141 doi.org/10.1016/j.cophys.2019.01.013
Young RM, Hawkins TA, Cavodeassi F, Stickney HL, Schwarz Q, Lawrence LM, Wierzbicki C, Cheng BY, Luo J, Ambrosio EM, Klosner A, Sealy IM, Rowell J, Trivedi CA, Bianco IH, Allende ML, Busch-Nentwich EM, Gestri G, Wilson SW.
Compensatory growth renders Tcf7l1a dispensable for eye formation despite its requirement in eye field specification.
Elife. (2019) 8. doi: 10.7554/eLife.40093
Turner KJ, Hoyle J, Valdivia LE, Cerveny KL, Hart W, Mangoli M, Geisler R, Rees M, Houart C, Poole RJ, Wilson SW, Gestri G.
Abrogation of Stem Loop Binding Protein (Slbp) function leads to a failure of cells to transition from proliferation to differentiation, retinal coloboma and midline axon guidance deficits.
PLoS One. 2019 Jan 29;14(1):e0211073. doi: 10.1371/journal.pone.0211073. eCollection 2019.
Tube The nearest underground stations are Euston Square, Euston and Warren Street. We are only a few blocks away from any of these stations.
Buses Southbound routes 10, 24, 29, and 73 pass by UCL’s main gate; northbound routes stop at Warren Street station.
1st Floor, Anatomy Building
tel: 020 3549 5652
General & technical enquiries
Outreach/ Work experience/Academic Enquiries
For information specific to a research group...
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