Review



multibody software md adams  (MSC Software Corporation)

 
  • Logo
  • About
  • News
  • Press Release
  • Team
  • Advisors
  • Partners
  • Contact
  • Bioz Stars
  • Bioz vStars
    • 90
      Buy from Supplier

    Structured Review

    MSC Software Corporation multibody software md adams
    Workflow used to build a simplified equine carpus model ( A – E ). The radial carpal bone (Cr) was fractured into two main pieces ( A ). The fractured volumes of the Cr were segmented ( B ). The Cr was virtually reconstructed by aligning the bone fragments and applying a wrapping function to reproduce the non-fractured bone surface ( C ). All the articulating bones of the carpal joint were segmented, and the respective three-dimensional (3D) solid geometries were created using software for 3D image processing. The 3D model was imported in <t>multibody</t> software and the gravity, and the weight forces were introduced ( D ). The collateral ligaments and the dorsal retinaculum were modelled ( E ). The short and long medial collateral ligaments (s-MCL and l-MCL), and the short and long lateral collateral ligaments (s-LCL and l-LCL) were introduced in the model. The short and long medial retinaculum (s-MR and l-MR) blended with the dorsal joint capsule and fascia were modelled. The intercarpal ligaments were modelled as bushing elements, acting between two bones proportionally to their relative linear and angular displacements and velocities.
    Multibody Software Md Adams, supplied by MSC Software Corporation, used in various techniques. Bioz Stars score: 90/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
    https://www.bioz.com/result/multibody software md adams/product/MSC Software Corporation
    Average 90 stars, based on 1 article reviews
    multibody software md adams - by Bioz Stars, 2026-05
    90/100 stars

    Images

    1) Product Images from "Multibody Computer Model of the Entire Equine Forelimb Simulates Forces Causing Catastrophic Fractures of the Carpus during a Traditional Race"

    Article Title: Multibody Computer Model of the Entire Equine Forelimb Simulates Forces Causing Catastrophic Fractures of the Carpus during a Traditional Race

    Journal: Animals : an Open Access Journal from MDPI

    doi: 10.3390/ani12060737

    Workflow used to build a simplified equine carpus model ( A – E ). The radial carpal bone (Cr) was fractured into two main pieces ( A ). The fractured volumes of the Cr were segmented ( B ). The Cr was virtually reconstructed by aligning the bone fragments and applying a wrapping function to reproduce the non-fractured bone surface ( C ). All the articulating bones of the carpal joint were segmented, and the respective three-dimensional (3D) solid geometries were created using software for 3D image processing. The 3D model was imported in multibody software and the gravity, and the weight forces were introduced ( D ). The collateral ligaments and the dorsal retinaculum were modelled ( E ). The short and long medial collateral ligaments (s-MCL and l-MCL), and the short and long lateral collateral ligaments (s-LCL and l-LCL) were introduced in the model. The short and long medial retinaculum (s-MR and l-MR) blended with the dorsal joint capsule and fascia were modelled. The intercarpal ligaments were modelled as bushing elements, acting between two bones proportionally to their relative linear and angular displacements and velocities.
    Figure Legend Snippet: Workflow used to build a simplified equine carpus model ( A – E ). The radial carpal bone (Cr) was fractured into two main pieces ( A ). The fractured volumes of the Cr were segmented ( B ). The Cr was virtually reconstructed by aligning the bone fragments and applying a wrapping function to reproduce the non-fractured bone surface ( C ). All the articulating bones of the carpal joint were segmented, and the respective three-dimensional (3D) solid geometries were created using software for 3D image processing. The 3D model was imported in multibody software and the gravity, and the weight forces were introduced ( D ). The collateral ligaments and the dorsal retinaculum were modelled ( E ). The short and long medial collateral ligaments (s-MCL and l-MCL), and the short and long lateral collateral ligaments (s-LCL and l-LCL) were introduced in the model. The short and long medial retinaculum (s-MR and l-MR) blended with the dorsal joint capsule and fascia were modelled. The intercarpal ligaments were modelled as bushing elements, acting between two bones proportionally to their relative linear and angular displacements and velocities.

    Techniques Used: Software



    Similar Products

    multibody software md adams  (MSC Software Corporation)
    90
    MSC Software Corporation multibody software md adams
    Workflow used to build a simplified equine carpus model ( A – E ). The radial carpal bone (Cr) was fractured into two main pieces ( A ). The fractured volumes of the Cr were segmented ( B ). The Cr was virtually reconstructed by aligning the bone fragments and applying a wrapping function to reproduce the non-fractured bone surface ( C ). All the articulating bones of the carpal joint were segmented, and the respective three-dimensional (3D) solid geometries were created using software for 3D image processing. The 3D model was imported in <t>multibody</t> software and the gravity, and the weight forces were introduced ( D ). The collateral ligaments and the dorsal retinaculum were modelled ( E ). The short and long medial collateral ligaments (s-MCL and l-MCL), and the short and long lateral collateral ligaments (s-LCL and l-LCL) were introduced in the model. The short and long medial retinaculum (s-MR and l-MR) blended with the dorsal joint capsule and fascia were modelled. The intercarpal ligaments were modelled as bushing elements, acting between two bones proportionally to their relative linear and angular displacements and velocities.
    Multibody Software Md Adams, supplied by MSC Software Corporation, used in various techniques. Bioz Stars score: 90/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
    https://www.bioz.com/result/multibody software md adams/product/MSC Software Corporation
    Average 90 stars, based on 1 article reviews
    multibody software md adams - by Bioz Stars, 2026-05
    90/100 stars
    		  Buy from Supplier

    Image Search Results


    Workflow used to build a simplified equine carpus model ( A – E ). The radial carpal bone (Cr) was fractured into two main pieces ( A ). The fractured volumes of the Cr were segmented ( B ). The Cr was virtually reconstructed by aligning the bone fragments and applying a wrapping function to reproduce the non-fractured bone surface ( C ). All the articulating bones of the carpal joint were segmented, and the respective three-dimensional (3D) solid geometries were created using software for 3D image processing. The 3D model was imported in multibody software and the gravity, and the weight forces were introduced ( D ). The collateral ligaments and the dorsal retinaculum were modelled ( E ). The short and long medial collateral ligaments (s-MCL and l-MCL), and the short and long lateral collateral ligaments (s-LCL and l-LCL) were introduced in the model. The short and long medial retinaculum (s-MR and l-MR) blended with the dorsal joint capsule and fascia were modelled. The intercarpal ligaments were modelled as bushing elements, acting between two bones proportionally to their relative linear and angular displacements and velocities.

    Journal: Animals : an Open Access Journal from MDPI

    Article Title: Multibody Computer Model of the Entire Equine Forelimb Simulates Forces Causing Catastrophic Fractures of the Carpus during a Traditional Race

    doi: 10.3390/ani12060737

    Figure Lengend Snippet: Workflow used to build a simplified equine carpus model ( A – E ). The radial carpal bone (Cr) was fractured into two main pieces ( A ). The fractured volumes of the Cr were segmented ( B ). The Cr was virtually reconstructed by aligning the bone fragments and applying a wrapping function to reproduce the non-fractured bone surface ( C ). All the articulating bones of the carpal joint were segmented, and the respective three-dimensional (3D) solid geometries were created using software for 3D image processing. The 3D model was imported in multibody software and the gravity, and the weight forces were introduced ( D ). The collateral ligaments and the dorsal retinaculum were modelled ( E ). The short and long medial collateral ligaments (s-MCL and l-MCL), and the short and long lateral collateral ligaments (s-LCL and l-LCL) were introduced in the model. The short and long medial retinaculum (s-MR and l-MR) blended with the dorsal joint capsule and fascia were modelled. The intercarpal ligaments were modelled as bushing elements, acting between two bones proportionally to their relative linear and angular displacements and velocities.

    Article Snippet: Thus, the obtained 3D geometries were imported into multibody software (v.2017, MD Adams, MSC Software Corporation GmbH, Munich, Germany), where a dynamic model was implemented.

    Techniques: Software