about
Mussel adhesion is dictated by time-regulated secretion and molecular conformation of mussel adhesive proteins.The role of water on the structure and mechanical properties of a thermoplastic natural block co-polymer from squid sucker ring teeth.Layer-by-layer polyelectrolyte deposition: a mechanism for forming biocomposite materials.Four-stranded coiled-coil elastic protein in the byssus of the giant clam, Tridacna maxima.Cross-linking chemistry of squid beak.Jumbo squid beaks: inspiration for design of robust organic composites.Multi-scale thermal stability of a hard thermoplastic protein-based material.An Underwater Surface-Drying Peptide Inspired by a Mussel Adhesive Protein.Structural proteins from whelk egg capsule with long range elasticity associated with a solid-state phase transition.Phase transition-induced elasticity of α-helical bioelastomeric fibres and networks.Engineering bioinspired bacteria-adhesive clay nanoparticles with a membrane-disruptive property for the treatment of Helicobacter pylori infection.Self-Assembly of Recombinant Hagfish Thread Keratins Amenable to a Strain-Induced α-Helix to β-Sheet Transition.Infiltration of chitin by protein coacervates defines the squid beak mechanical gradient.The transition from stiff to compliant materials in squid beaks.Accelerating the design of biomimetic materials by integrating RNA-seq with proteomics and materials science.Wear and abrasion resistance selection maps of biological materials.Nanoconfined β-sheets mechanically reinforce the supra-biomolecular network of robust squid Sucker Ring Teeth.Fabrication of a 3D hair follicle-like hydrogel by soft lithography.Supramolecular β-Sheets Stabilized Protein Nanocarriers for Drug Delivery and Gene Transfection.Parrotfish Teeth: Stiff Biominerals Whose Microstructure Makes Them Tough and Abrasion-Resistant To Bite Stony Corals.Modular peptides from the thermoplastic squid sucker ring teeth form amyloid-like cross-β supramolecular networks.Squid Suckerin Biomimetic Peptides Form Amyloid-like Crystals with Robust Mechanical Properties.Self-coacervation of modular squid beak proteins - a comparative study.Artificial hagfish protein fibers with ultra-high and tunable stiffness.Preventing mussel adhesion using lubricant-infused materials.Hierarchical Assembly of Tough Bioelastomeric Egg Capsules is Mediated by a Bundling Protein.Orientational Coupling Locally Orchestrates a Cell Migration Pattern for Re-Epithelialization.Textured fluorapatite bonded to calcium sulphate strengthen stomatopod raptorial appendages.Bio-Inspired Mechanotactic Hybrids for Orchestrating Traction-Mediated Epithelial Migration.Properties and architecture of the sperm whale skull amphitheatre.Bioinspired pH and magnetic responsive catechol-functionalized chitosan hydrogels with tunable elastic properties.Non-entropic and reversible long-range deformation of an encapsulating bioelastomer.Stable Formation of Gold Nanoparticles onto Redox-Active Solid Biosubstrates Made of Squid Suckerin Proteins.The role of quasi-plasticity in the extreme contact damage tolerance of the stomatopod dactyl club.Biomimetic production of silk-like recombinant squid sucker ring teeth proteins.Unifying Design Strategies in Demosponge and Hexactinellid Skeletal SystemsEffects of Laminate Architecture on Fracture Resistance of Sponge Biosilica: Lessons from NatureWhite Light-Emitting Multistimuli-Responsive Hydrogels with Lanthanides and Carbon DotsPressure Sensitive Adhesion of an Elastomeric Protein Complex Extracted From Squid Ring TeethStructural, Nanomechanical, and Computational Characterization of d,l-Cyclic Peptide Assemblies
P50
Q27319580-BBD0F69A-AAFE-4401-B227-6416FF3BA052Q30392520-756A81E7-ED42-475D-B6CA-ADE8312AB1EFQ33925314-68DE2FB0-DB98-4658-856C-4DB1645404F0Q34105405-486B887E-C546-4B8E-9453-0EFDDCD758FAQ34352094-F4AC3856-E861-4C66-9477-FF0135C4879CQ34582709-A8B32C8C-48F9-40C0-8F81-AB39579010DFQ36128719-DEE975D5-4CFC-46E7-A73A-3E24B83A2E02Q37404107-E573930F-3B54-46A7-8C43-A68B7FFCEFD3Q37641159-BE3AF9B9-667A-49C6-88CE-A4A0737745EDQ38066383-52DC4CA3-6F4B-4E88-88DA-64500188D7A9Q40548402-184A11EB-577F-4468-886F-6156A2CDFE04Q40808757-27AA6B3C-763A-4EEA-9C79-4F590A563BC9Q40859483-DB5BA5BD-2527-433B-9105-C75E90D87AE1Q41954287-9E7A35D5-4E73-4CA4-8B38-3CCF0B43CEECQ42774104-945152DE-511A-4A2C-A14F-515C9D6CC3DAQ43543348-9B696FE3-F576-4881-9E01-4795CE344F41Q43622490-5E59B675-4D39-4B97-947D-2665253F8B41Q44380538-6C97F207-1125-41DB-95D2-932ADF3EDEA1Q45866843-63C7E1C1-B60D-4099-ADF8-850B0688A8E5Q46038490-A226257F-69CA-4286-B784-B2BC4894E81AQ46483369-16752909-41E0-4204-A60E-8C2D41D02B77Q47372580-3292D01A-64D0-4DF7-AB0D-83175CA43148Q47434611-223DBBC4-46E4-4E3C-9E11-16B504A0A3CFQ47764981-02D6B7C7-000D-471A-8A3F-45E95804CDF4Q47782631-8E7816E6-C80A-496F-8C47-49E53B378D78Q48238366-AE0D8B48-20F6-49C5-A50E-5B9F55795BAFQ50851199-866A70E0-D84C-4173-8DBC-82ACBF12A461Q51118211-D82EA00D-47C2-4E53-9A35-A088CD229D0BQ51495458-7689B48F-A3DD-4520-912F-4B48AAB2598BQ51556412-DFE15CC1-134D-4F94-9E17-FE3292485E78Q51649656-52159DCB-CDA1-4C02-8A97-4A99D0116F48Q51889677-9288C827-E25D-49C7-A357-199D0B0FD0BDQ53183133-9DA0EA72-40E9-4F71-95AC-01B4FC5C44BBQ53475496-E4614942-C2CA-4967-8AB5-D53D628A81D7Q53489538-E8DBA19C-F857-4909-BEBD-0FD2A7EF1B57Q53528773-45F32BFB-C4B0-4435-984C-E71B7B8D7E83Q53528803-03A3FD79-28F5-4224-96CB-6646B0970882Q57359022-C44D3868-A0A3-4517-AFDF-3DA0575BC888Q60125826-7571A547-6611-4E08-A937-4F6DFF6F73FDQ62576003-5F1518BA-3265-4A98-B271-CC136BAD7527
P50
description
hulumtues
@sq
onderzoeker
@nl
researcher
@en
հետազոտող
@hy
name
Ali Miserez
@ast
Ali Miserez
@en
Ali Miserez
@es
type
label
Ali Miserez
@ast
Ali Miserez
@en
Ali Miserez
@es
prefLabel
Ali Miserez
@ast
Ali Miserez
@en
Ali Miserez
@es
P1053
D-1074-2010
P106
P1153
7005010783
P21
P2798
P31
P3829
P496
0000-0003-0864-8170