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1. The order of disorder: Deconstructing visual disorder and its effect on rule-breaking.

   https://doi.org/10.1037/xge0000240  

   Kotabe, Hiroki P.; Kardan, Omid; Berman, Marc G. (January 2016, Journal of Experimental Psychology: General)
2. DEPICTER2: a comprehensive webserver for intrinsic disorder and disorder function prediction

   https://doi.org/10.1093/nar/gkad330  

   Basu, Sushmita; Gsponer, Jörg; Kurgan, Lukasz (May 2023, Nucleic Acids Research)

   Abstract Intrinsic disorder in proteins is relatively abundant in nature and essential for a broad spectrum of cellular functions. While disorder can be accurately predicted from protein sequences, as it was empirically demonstrated in recent community-organized assessments, it is rather challenging to collect and compile a comprehensive prediction that covers multiple disorder functions. To this end, we introduce the DEPICTER2 (DisorderEd PredictIon CenTER) webserver that offers convenient access to a curated collection of fast and accurate disorder and disorder function predictors. This server includes a state-of-the-art disorder predictor, flDPnn, and five modern methods that cover all currently predictable disorder functions: disordered linkers and protein, peptide, DNA, RNA and lipid binding. DEPICTER2 allows selection of any combination of the six methods, batch predictions of up to 25 proteins per request and provides interactive visualization of the resulting predictions. The webserver is freely available at http://biomine.cs.vcu.edu/servers/DEPICTER2/ 

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3. Anisotropic Disorder and Thermal Stability of Silicane

   https://doi.org/10.1021/acsnano.1c04230  

   Ryan, Bradley J.; Roling, Luke T.; Panthani, Matthew G. (September 2021, ACS Nano)
4. Disorder and the Neural Representation of Complex Odors

   https://doi.org/10.3389/fncom.2022.917786  

   Krishnamurthy, Kamesh; Hermundstad, Ann M.; Mora, Thierry; Walczak, Aleksandra M.; Balasubramanian, Vijay (August 2022, Frontiers in Computational Neuroscience)

   Animals smelling in the real world use a small number of receptors to sense a vast number of natural molecular mixtures, and proceed to learn arbitrary associations between odors and valences. Here, we propose how the architecture of olfactory circuits leverages disorder, diffuse sensing and redundancy in representation to meet these immense complementary challenges. First, the diffuse and disordered binding of receptors to many molecules compresses a vast but sparsely-structured odor space into a small receptor space, yielding an odor code that preserves similarity in a precise sense. Introducing any order/structure in the sensing degrades similarity preservation. Next, lateral interactions further reduce the correlation present in the low-dimensional receptor code. Finally, expansive disordered projections from the periphery to the central brain reconfigure the densely packed information into a high-dimensional representation, which contains multiple redundant subsets from which downstream neurons can learn flexible associations and valences. Moreover, introducing any order in the expansive projections degrades the ability to recall the learned associations in the presence of noise. We test our theory empirically using data from Drosophila . Our theory suggests that the neural processing of sparse but high-dimensional olfactory information differs from the other senses in its fundamental use of disorder. 

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5. Rejuvenation of Disorder-Containing Materials

   https://doi.org/10.1007/978-3-319-91989-8_85  

   Balbus, G.H.; Echlin, M.P.; Grigorian, C.M.; Rupert, T.J.; Pollock, T.M.; Gianola, D.S. (May 2018, Proceedings of the First International Conference on Theoretical, Applied and Experimental Mechanics. ICTAEM 2018. Structural Integrity, vol 5. Springer, Cham)