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MacroModel is a computer program for molecular modelling of organic compounds and biopolymers. It features various chemistry force fields, plus energy minimizing algorithms, to predict geometry and relative conformational energies of molecules.[1] MacroModel is maintained by Schrödinger, LLC.

MacroModel
Developer(s)Schrödinger, LLC
Initial release1990; 34 years ago (1990)
Stable release
2021-3
Operating systemLinux, Windows, macOS
Platformx64, GPGPU
Available inEnglish
TypeComputational chemistry
LicenseProprietary, Commercial software
Websitewww.schrodinger.com/products/macromodel

It performs simulations in the framework of classical mechanics, also termed molecular mechanics, and can perform molecular dynamics simulations to model systems at finite temperatures using stochastic dynamics and mixed Monte Carlo algorithms. MacroModel supports Windows, Linux, macOS, Silicon Graphics (SGI) IRIX, and IBM AIX.

The Macromodel software package was first been described in the scientific literature in 1990,[2] and has been subsequently acquired by Schrödinger, Inc. in 2000.[3]

Key features

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Known version history

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  • 2013: version 10.0
  • 2012: version 9.9.2
  • 2011: version 9.9.1
  • 2010: version 9.8
  • 2009: version 9.7
  • 2008: version 9.6
  • 2007: version 9.5
  • 2006: version 9.1
  • 2005: version 9.0
  • 2004: version 8.5
  • 2003: version 8.1

See also

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References

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  1. ^ Mohamadi F, Richard NG, Guida WC, Liskamp R, Lipton M, Caufield C, Chang G, Hendrickson T, Still WC (May 1990). "MacroModel - an Integrated Software System for Modeling Organic and Bioorganic Molecules Using Molecular Mechanics". J. Comput. Chem. 11 (4): 440–467. doi:10.1002/jcc.540110405.
  2. ^ Mohamadi, Fariborz; Richards, Nigel G. J.; Guida, Wayne C.; Liskamp, Rob; Lipton, Mark; Caufield, Craig; Chang, George; Hendrickson, Thomas; Still, W. Clark (1990-05-01). "Macromodel—an integrated software system for modeling organic and bioorganic molecules using molecular mechanics". Journal of Computational Chemistry. 11 (4): 440–467. doi:10.1002/jcc.540110405. ISSN 1096-987X.
  3. ^ "Overview | Schrödinger". www.schrodinger.com. Retrieved 2017-11-30.
  4. ^ Still WC, Tempczyk A, Hawley RC, Hendrickson T (1990). "Semianalytical treatment of solvation for molecular mechanics and dynamics". J Am Chem Soc. 112 (16): 6127–6129. doi:10.1021/ja00172a038.
  5. ^ Guimarães CR, Cardozo M (May 2008). "MM-GB/SA rescoring of docking poses in structure-based lead optimization". J Chem Inf Model. 48 (5): 958–70. doi:10.1021/ci800004w. PMID 18422307.
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