Maya software

Manufactured by Autodesk

Sourced in United States

Maya is a 3D computer graphics software application that is widely used for creating animated films, visual effects, and interactive 3D applications. It provides a comprehensive set of tools for modeling, animation, rendering, and compositing.

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Lab products found in correlation

Omnic, by Thermo Fisher Scientific (1 mentions) Digital micrography software, by Ametek (1 mentions) Fireworks software, by Adobe (1 mentions) Peakfit software, by Grafiti LLC (1 mentions) Originpro software, by OriginLab (1 mentions) Labspec software, by Horiba (1 mentions)

5 protocols using maya software

Subarachnoid Space Anatomy Segmentation

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Based on the T2-weighted MRI images, the 3D anatomy of the subarachnoid space near the CMJ was manually segmented from the foramen magnum (FM) to the caudal end of the second cervical vertebrae (C2) (Figure 1-a) using the freely available Segment software (Medviso, Sweden). The cranial and caudal ends of the model were extended five hydraulic diameters to minimize the impact of inlet and outlet boundary conditions on the domain of interest. Maya software (Autodesk Inc. CA, USA) was used to extract and define the surface of the cerebellar tonsils and spinal cord from the overall geometry so that the displacement profiles could be imposed at each structure separately.

Pahlavian S.H., Loth F., Luciano M., Oshinski J, & Martin B.A. (2015). Neural tissue motion impacts cerebrospinal fluid dynamics at the cervical medullary junction: a patient-specific moving-boundary computational model. Annals of biomedical engineering, 43(12), 2911-2923.

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Materials Characterization Protocol

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The illustration models were constructed on a Maya software (Autodesk, San Rafael, CA, USA). The images were processed on a Fireworks software (Adobe, San Jose, CA, USA). The XRD, XPS, HRTEM, Raman, FTIR, and EIS spectra were analyzed on Jade software (Materials Data, Livermore, CA, USA), Peak Fit software (Systat software, Inc, San Jose, CA, USA), Digital Micrography software (Gatan Inc, Pleasanton, CA, USA), Labspec software (Horiba, Kyoto, JP), OMNIC (Thermo Fisher Scientific Inc, Waltham, MA, USA), and ZView (Scribner Associates, Inc, Charlottesville, VA, USA), respectively. Results were analyzed on an OriginPro software (Origin Lab, Northampton, MA, USA).

Liu J., Long J., Shen Z., Jin X., Han T., Si T, & Zhang H. (2021). A Self‐Healing Flexible Quasi‐Solid Zinc‐Ion Battery Using All‐In‐One Electrodes. Advanced Science, 8(8), 2004689.

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Structural Modeling of Mic60 and Mic19

Cited 1 time

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The model of Mic60 and Mic19 in CJs was created and prepared by E. Werner, RNS Berlin (www.rns.berlin), who granted copyrights. The model comprises the crystal structures of the CC region of Mic60 from L. thermotolerans (ltMic60_CC, residues 235 to 382), the LBS 1 and mitofilin domain of ctMic60, and the CHCH domain of ctMic19 (Mito2_CHCH). In this, the sequence of ltMic60 was used as template. All other parts of Mic60 were modeled as unstructured regions. A CJ diameter of 17.5 nm was used (13 (link)). The model was generated using the Maya software from Autodesk Inc. (www.autodesk.com/products/maya/) and Modeling kit and Rigging kit of the plugin Molecular Maya (mMaya) from Digizyme Inc. (https://clarafi.com/tools/mmaya/).

Bock-Bierbaum T., Funck K., Wollweber F., Lisicki E., von der Malsburg K., von der Malsburg A., Laborenz J., Noel J.K., Hessenberger M., Jungbluth S., Bernert C., Kunz S., Riedel D., Lilie H., Jakobs S., van der Laan M, & Daumke O. (2022). Structural insights into crista junction formation by the Mic60-Mic19 complex. Science Advances, 8(35), eabo4946.

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Digital Models for Cephalic Index Analysis

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Digital models for each of the 5 hypothetical patients were created using Maya software (version 2018.5, 2019; Autodesk Inc. San Rafael, Calif.) (Fig. 1). These were designed based on a typical patient presentation for each cephalic index severity. The renderings, rather than actual patient photographs, were used to reduce distractors (ie, hair, lighting) and potential confounders (ie, facial features or expressions, ethnic or racial background). Models were refined based on iterative feedback provided by the craniofacial surgeons at our institution.

Hughes C.D., Langa O., Nuzzi L., Staffa S.J., Proctor M., Meara J.G, & Ganske I.M. (2021). Evaluating Surgical Decision-making in Nonsyndromic Sagittal Craniosynostosis Using a Digital 3D Model. Plastic and Reconstructive Surgery Global Open, 9(5), e3493.

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Cartoon Facial Expression Database Protocol

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In the second condition, we used colored pictures showing cartoon faces of six females and six males. These images were included in the Facial Expression Research Group Database (FERG-DB) [58 ]. They were digitally generated using Maya software (version 1, Autodesk, Mill Valley, CA, USA) and the images were created using a 2D renderer (version 7.1.8, Unity, San Francisco, CA, USA) [58 ].

Greco C., Romani M., Berardi A., De Vita G., Galeoto G., Giovannone F., Vigliante M, & Sogos C. (2021). Morphing Task: The Emotion Recognition Process in Children with Attention Deficit Hyperactivity Disorder and Autism Spectrum Disorder. International Journal of Environmental Research and Public Health, 18(24), 13273.

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