Your search keyword '"Das, Saurabh"' showing total 15 results

1. Mussel Coating Protein-Derived Complex Coacervates Mitigate Frictional Surface Damage

Author

Miller, Dusty Rose, Das, Saurabh, Huang, Kuo-Ying, Han, Songi, Israelachvili, Jacob N, and Waite, J Herbert

Subjects

Engineering, Mechanical Engineering, Bioengineering, Biotechnology, biomimetic, adhesion, wear protection, interface, Mytilus californianus foot protein 1, mcfp-1, hyaluronic acid, HA, Biomedical Engineering, Biomedical engineering

Abstract

The role of friction in the functional performance of biomaterial interfaces is widely reckoned to be critical and complicated but poorly understood. To better understand friction forces, we investigated the natural adaptation of the holdfast or byssus of mussels that live in high-energy surf habitats. As the outermost covering of the byssus, the cuticle deserves particular attention for its adaptations to frictional wear under shear. In this study, we coacervated one of three variants of a key cuticular component, mussel foot protein 1, mfp-1 [(1) Mytilus californianus mcfp-1, (2) rmfp-1, and (3) rmfp-1-Dopa], with hyaluronic acid (HA) and investigated the wear protection capabilities of these coacervates to surfaces (mica) during shear. Native mcfp-1/HA coacervates had an intermediate coefficient of friction (μ ∼0.3) but conferred excellent wear protection to mica with no damage from applied loads, F⊥, as high as 300 mN (pressure, P, > 2 MPa). Recombinant rmfp-1/HA coacervates exhibited a comparable coefficient of friction (μ ∼0.3); however, wear protection was significantly inferior (damage at F⊥ > 60 mN) compared with that of native protein coacervates. Wear protection of rmfp-1/HA coacervates increased 5-fold upon addition of the surface adhesive group 3,4-dihydroxyphenylalanine, (Dopa). We propose a Dopa-dependent wear protection mechanism to explain the differences in wear protection between coacervates. Our results reveal a significant untapped potential for coacervates in applications that require adhesion, lubrication, and wear protection. These applications include artificial joints, contact lenses, dental sealants, and hair and skin conditioners.

Published

2015

2. Peptide Length and Dopa Determine Iron‐Mediated Cohesion of Mussel Foot Proteins

Author

Das, Saurabh, Martinez Rodriguez, Nadine R, Wei, Wei, Waite, J Herbert, and Israelachvili, Jacob N

Subjects

Chemical Sciences, Dopa, Mussel Foot Protein, bio-adhesion, coating proteins, iron chelation, mfp-1 peptide, Physical Sciences, Engineering, Materials, Chemical sciences, Physical sciences

Abstract

Mussel adhesion to mineral surfaces is widely attributed to 3,4-dihydroxyphenylalanine (Dopa) functionalities in the mussel foot proteins (mfps). Several mfps, however, show a broad range (30-100%) of Tyrosine (Tyr) to Dopa conversion suggesting that Dopa is not the only desirable outcome for adhesion. Here, we used a partial recombinant construct of mussel foot protein-1 (rmfp-1) and short decapeptide dimers with and without Dopa and assessed both their cohesive and adhesive properties on mica using a surface forces apparatus (SFA). Our results demonstrate that at low pH, both the unmodified and Dopa-containing rmfp-1s show similar energies for adhesion to mica and self-self interaction. Cohesion between two Dopa-containing rmfp-1 surfaces can be doubled by Fe3+ chelation, but remains unchanged with unmodified rmfp-1. At the same low pH, the Dopa modified short decapeptide dimer did not show any change in cohesive interactions even with Fe3+. Our results suggest that the most probable intermolecular interactions are those arising from electrostatic (i.e., cation-π) and hydrophobic interactions. We also show that Dopa in a peptide sequence does not by itself mediate Fe3+ bridging interactions between peptide films: peptide length is a crucial enabling factor.

Published

2015

3. Peptide Length and Dopa Determine Iron-Mediated Cohesion of Mussel Foot Proteins.

Author

Das, Saurabh, Martinez Rodriguez, Nadine R, Wei, Wei, Waite, J Herbert, and Israelachvili, Jacob N

Subjects

Dopa, Mussel Foot Protein, bio-adhesion, coating proteins, iron chelation, mfp-1 peptide, Materials, Chemical Sciences, Engineering, Physical Sciences

Abstract

Mussel adhesion to mineral surfaces is widely attributed to 3,4-dihydroxyphenylalanine (Dopa) functionalities in the mussel foot proteins (mfps). Several mfps, however, show a broad range (30-100%) of Tyrosine (Tyr) to Dopa conversion suggesting that Dopa is not the only desirable outcome for adhesion. Here, we used a partial recombinant construct of mussel foot protein-1 (rmfp-1) and short decapeptide dimers with and without Dopa and assessed both their cohesive and adhesive properties on mica using a surface forces apparatus (SFA). Our results demonstrate that at low pH, both the unmodified and Dopa-containing rmfp-1s show similar energies for adhesion to mica and self-self interaction. Cohesion between two Dopa-containing rmfp-1 surfaces can be doubled by Fe3+ chelation, but remains unchanged with unmodified rmfp-1. At the same low pH, the Dopa modified short decapeptide dimer did not show any change in cohesive interactions even with Fe3+. Our results suggest that the most probable intermolecular interactions are those arising from electrostatic (i.e., cation-π) and hydrophobic interactions. We also show that Dopa in a peptide sequence does not by itself mediate Fe3+ bridging interactions between peptide films: peptide length is a crucial enabling factor.

Published

2015

4. Correction to "Tough Coating Proteins: Subtle Sequence Variation Modulates Cohesion".

Author

Das, Saurabh, Miller, Dusty R, Kaufman, Yair, Martinez Rodriguez, Nadine R, Pallaoro, Alessia, Harrington, Matthew J, Gylys, Maryte, Israelachvili, Jacob N, and Waite, J Herbert

Subjects

Polymers, Chemical Sciences, Biological Sciences, Engineering

Published

2015

5. Correction to "Tough Coating Proteins: Subtle Sequence Variation Modulates Cohesion".

Author

Das, Saurabh, Miller, Dusty R, Kaufman, Yair, Martinez Rodriguez, Nadine R, Pallaoro, Alessia, Harrington, Matthew J, Gylys, Maryte, Israelachvili, Jacob N, and Waite, J Herbert

Subjects

Chemical Sciences, Biological Sciences, Engineering, Polymers

Published

2015

6. Hydrophobic, Electrostatic, and Dynamic Polymer Forces at Silicone Surfaces Modified with Long‐Chain Bolaform Surfactants

Author

Rapp, Michael V, Donaldson, Stephen H, Gebbie, Matthew A, Das, Saurabh, Kaufman, Yair, Gizaw, Yonas, Koenig, Peter, Roiter, Yuri, and Israelachvili, Jacob N

Subjects

Engineering, Macromolecular and Materials Chemistry, Materials Engineering, Chemical Sciences, adhesion, nanostructures, polymers, self-assembly, surface forces apparatus, Nanoscience & Nanotechnology

Abstract

Surfactant self-assembly on surfaces is an effective way to tailor the complex forces at and between hydrophobic-water interfaces. Here, the range of structures and forces that are possible at surfactant-adsorbed hydrophobic surfaces are demonstrated: certain long-chain bolaform surfactants-containing a polydimethylsiloxane (PDMS) mid-block domain and two cationic α, ω-quarternary ammonium end-groups-readily adsorb onto thin PDMS films and form dynamically fluctuating nanostructures. Through measurements with the surface forces apparatus (SFA), it is found that these soft protruding nanostructures display polymer-like exploration behavior at the PDMS surface and give rise to a long-ranged, temperature- and rate-dependent attractive bridging force (not due to viscous forces) on approach to a hydrophilic bare mica surface. Coulombic interactions between the cationic surfactant end-groups and negatively-charged mica result in a rate-dependent polymer bridging force during separation as the hydrophobic surfactant mid-blocks are pulled out from the PDMS interface, yielding strong adhesion energies. Thus, (i) the versatile array of surfactant structures that may form at hydrophobic surfaces is highlighted, (ii) the need to consider the interaction dynamics of such self-assembled polymer layers is emphasized, and (iii) it is shown that long-chain surfactants can promote robust adhesion in aqueous solutions.

Published

2015

7. Mussel adhesive protein provides cohesive matrix for collagen type-1α

Author

Rodriguez, Nadine R Martinez, Das, Saurabh, Kaufman, Yair, Wei, Wei, Israelachvili, Jacob N, and Waite, J Herbert

Subjects

Biochemistry and Cell Biology, Engineering, Biological Sciences, Adsorption, Aluminum Silicates, Animals, Bivalvia, Collagen Type I, Hydrogen Bonding, Microscopy, Atomic Force, Oxidation-Reduction, Protein Binding, Proteins, Quartz Crystal Microbalance Techniques, Rats, Titanium, Mussel foot proteins, Collagen type-1, Mfp-3, Mylitus californiaus

Abstract

Understanding the interactions between collagen and adhesive mussel foot proteins (mfps) can lead to improved medical and dental adhesives, particularly for collagen-rich tissues. Here we investigated interactions between collagen type-1, the most abundant load-bearing animal protein, and mussel foot protein-3 (mfp-3) using a quartz crystal microbalance and surface forces apparatus (SFA). Both hydrophilic and hydrophobic variants of mfp-3 were exploited to probe the nature of the interaction between the protein and collagen. Our chief findings are: 1) mfp-3 is an effective chaperone for tropocollagen adsorption to TiO2 and mica surfaces; 2) at pH 3, collagen addition between two mfp-3 films (Wc = 5.4 ± 0.2 mJ/m(2)) increased their cohesion by nearly 35%; 3) oxidation of Dopa in mfp-3 by periodate did not abolish the adhesion between collagen and mfp-3 films, and 4) collagen bridging between both hydrophilic and hydrophobic mfp-3 variant films is equally robust, suggesting that hydrophobic interactions play a minor role. Extensive H-bonding, π-cation and electrostatic interactions are more plausible to explain the reversible bridging of mfp-3 films by collagen.

Published

2015

8. Tough Coating Proteins: Subtle Sequence Variation Modulates Cohesion

Author

Das, Saurabh, Miller, Dusty R, Kaufman, Yair, Rodriguez, Nadine R Martinez, Pallaoro, Alessia, Harrington, Matthew J, Gylys, Maryte, Israelachvili, Jacob N, and Waite, J Herbert

Subjects

Amino Acid Sequence, Animals, Hydrogen-Ion Concentration, Iron, Mytilus, Protein Binding, Proteins, Chemical Sciences, Biological Sciences, Engineering, Polymers

Abstract

Mussel foot protein-1 (mfp-1) is an essential constituent of the protective cuticle covering all exposed portions of the byssus (plaque and the thread) that marine mussels use to attach to intertidal rocks. The reversible complexation of Fe(3+) by the 3,4-dihydroxyphenylalanine (Dopa) side chains in mfp-1 in Mytilus californianus cuticle is responsible for its high extensibility (120%) as well as its stiffness (2 GPa) due to the formation of sacrificial bonds that help to dissipate energy and avoid accumulation of stresses in the material. We have investigated the interactions between Fe(3+) and mfp-1 from two mussel species, M. californianus (Mc) and M. edulis (Me), using both surface sensitive and solution phase techniques. Our results show that although mfp-1 homologues from both species bind Fe(3+), mfp-1 (Mc) contains Dopa with two distinct Fe(3+)-binding tendencies and prefers to form intramolecular complexes with Fe(3+). In contrast, mfp-1 (Me) is better adapted to intermolecular Fe(3+) binding by Dopa. Addition of Fe(3+) did not significantly increase the cohesion energy between the mfp-1 (Mc) films at pH 5.5. However, iron appears to stabilize the cohesive bridging of mfp-1 (Mc) films at the physiologically relevant pH of 7.5, where most other mfps lose their ability to adhere reversibly. Understanding the molecular mechanisms underpinning the capacity of M. californianus cuticle to withstand twice the strain of M. edulis cuticle is important for engineering of tunable strain tolerant composite coatings for biomedical applications.

Published

2015

9. Tough coating proteins: subtle sequence variation modulates cohesion.

Author

Das, Saurabh, Miller, Dusty R, Kaufman, Yair, Martinez Rodriguez, Nadine R, Pallaoro, Alessia, Harrington, Matthew J, Gylys, Maryte, Israelachvili, Jacob N, and Waite, J Herbert

Subjects

Animals, Iron, Proteins, Amino Acid Sequence, Protein Binding, Hydrogen-Ion Concentration, Mytilus, Polymers, Chemical Sciences, Biological Sciences, Engineering

Abstract

Mussel foot protein-1 (mfp-1) is an essential constituent of the protective cuticle covering all exposed portions of the byssus (plaque and the thread) that marine mussels use to attach to intertidal rocks. The reversible complexation of Fe(3+) by the 3,4-dihydroxyphenylalanine (Dopa) side chains in mfp-1 in Mytilus californianus cuticle is responsible for its high extensibility (120%) as well as its stiffness (2 GPa) due to the formation of sacrificial bonds that help to dissipate energy and avoid accumulation of stresses in the material. We have investigated the interactions between Fe(3+) and mfp-1 from two mussel species, M. californianus (Mc) and M. edulis (Me), using both surface sensitive and solution phase techniques. Our results show that although mfp-1 homologues from both species bind Fe(3+), mfp-1 (Mc) contains Dopa with two distinct Fe(3+)-binding tendencies and prefers to form intramolecular complexes with Fe(3+). In contrast, mfp-1 (Me) is better adapted to intermolecular Fe(3+) binding by Dopa. Addition of Fe(3+) did not significantly increase the cohesion energy between the mfp-1 (Mc) films at pH 5.5. However, iron appears to stabilize the cohesive bridging of mfp-1 (Mc) films at the physiologically relevant pH of 7.5, where most other mfps lose their ability to adhere reversibly. Understanding the molecular mechanisms underpinning the capacity of M. californianus cuticle to withstand twice the strain of M. edulis cuticle is important for engineering of tunable strain tolerant composite coatings for biomedical applications.

Published

2015

10. Stick–slip friction of gecko-mimetic flaps on smooth and rough surfaces

Author

Das, Saurabh, Cadirov, Nicholas, Chary, Sathya, Kaufman, Yair, Hogan, Jack, Turner, Kimberly L, and Israelachvili, Jacob N

Subjects

Earth Sciences, Engineering, Geophysics, Adhesiveness, Adhesives, Animals, Biomechanical Phenomena, Biomimetics, Dimethylpolysiloxanes, Friction, Glass, Lizards, Materials Testing, Shear Strength, Silicon Dioxide, Stress, Mechanical, Surface Properties, stick - slip friction, gecko-mimetic, rough surface friction, stick–slip friction, General Science & Technology

Abstract

The discovery and understanding of gecko 'frictional-adhesion' adhering and climbing mechanism has allowed researchers to mimic and create gecko-inspired adhesives. A few experimental and theoretical approaches have been taken to understand the effect of surface roughness on synthetic adhesive performance, and the implications of stick-slip friction during shearing. This work extends previous studies by using a modified surface forces apparatus to quantitatively measure and model frictional forces between arrays of polydimethylsiloxane gecko footpad-mimetic tilted microflaps against smooth and rough glass surfaces. Constant attachments and detachments occur between the surfaces during shearing, as described by an avalanche model. These detachments ultimately result in failure of the adhesion interface and have been characterized in this study. Stick-slip friction disappears with increasing velocity when the flaps are sheared against a smooth silica surface; however, stick-slip was always present at all velocities and loads tested when shearing the flaps against rough glass surfaces. These results demonstrate the significance of pre-load, shearing velocity, shearing distances, commensurability and shearing direction of gecko-mimetic adhesives and provide us a simple model for analysing and/or designing such systems.

Published

2015

11. Shear‐Induced Aggregation of Mammalian Synovial Fluid Components under Boundary Lubrication Conditions

Author

Banquy, Xavier, Lee, Dong Woog, Das, Saurabh, Hogan, Jack, and Israelachvili, Jacob N

Subjects

lubrication, synovial fluids, thin films, aggregation, shear, Physical Sciences, Chemical Sciences, Engineering, Materials

Abstract

The lubricating and structural properties of different mammalian synovial fluids in thin films undergoing shear between two mica surfaces are studied in detail using a surface force apparatus (SFA). A 10-13 nm thick film of synovial components (proteins, lipids, and polymers) adsorbs on the mica surfaces in less than an hour of incubation time, and induces a strong repulsion between the surfaces that prevents them from coming into contact. Upon shearing, the structure of the confined synovial fluid changes dramatically when sheared above a "critical" shear rate of about 2 s-1 (corresponding to approximately 40 nm s-1). Above this critical shear rate and up to at least 70 μm s-1, the proteins and biopolymers in the fluid gradually aggregate to form a homogenous gel layer on each mica surface. As shearing continues, the gel layer gradually breaks up into discrete/individual gel particles that can roll in the contact keeping the sheared surfaces far apart even under high compressive loads (pressure P ≈ 20 MPa). These particles eventually become elongated and finally behave as roller bearings. This mechanism is consistently observed for three mammalian synovial fluids and two types of surfaces suggesting that it actually occurs in articular joints and prostetic implants in vivo. The implications of these findings for joints and prosthetic implants structure and lubrication are discussed; in particular the formation and function of the lamina splendens. Shear-induced aggregation of synovial fluid components is observed under boundary lubrication conditions. The aggregation process starts with the formation of a gel-like layer on the surfaces, which ultimately leads to the formation of rod-like aggregates. These aggregates provide enhanced wear protection and lubrication to the surfaces using rolling friction instead of pure sliding friction. This mechanism suggests new design criteria for future bioinspired lubricants. © 2014 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim.

Published

2014

12. The Intersection of Interfacial Forces and Electrochemical Reactions

Author

Israelachvili, Jacob N, Kristiansen, Kai, Gebbie, Matthew A, Lee, Dong Woog, Donaldson, Stephen H, Das, Saurabh, Rapp, Michael V, Banquy, Xavier, Valtiner, Markus, and Yu, Jing

Subjects

Affordable and Clean Energy, Adsorption, Electricity, Electrochemistry, Ionic Liquids, Mechanical Phenomena, Oxidation-Reduction, Physical Sciences, Chemical Sciences, Engineering

Abstract

We review recent developments in experimental techniques that simultaneously combine measurements of the interaction forces or energies between two extended surfaces immersed in electrolyte solutions-primarily aqueous-with simultaneous monitoring of their (electro)chemical reactions and controlling the electrochemical surface potential of at least one of the surfaces. Combination of these complementary techniques allows for simultaneous real time monitoring of angstrom level changes in surface thickness and roughness, surface-surface interaction energies, and charge and mass transferred via electrochemical reactions, dissolution, and adsorption, and/or charging of electric double layers. These techniques employ the surface forces apparatus (SFA) combined with various "electrochemical attachments" for in situ measurements of various physical and (electro)chemical properties (e.g., cyclic voltammetry), optical imaging, and electric potentials and currents generated naturally during an interaction, as well as when electric fields (potential differences) are applied between the surfaces and/or solution-in some cases allowing for the chemical reaction equation to be unambiguously determined. We discuss how the physical interactions between two different surfaces when brought close to each other (

Published

2013

13. The intersection of interfacial forces and electrochemical reactions.

Author

Israelachvili, Jacob N, Kristiansen, Kai, Gebbie, Matthew A, Lee, Dong Woog, Donaldson, Stephen H, Das, Saurabh, Rapp, Michael V, Banquy, Xavier, Valtiner, Markus, and Yu, Jing

Subjects

Electricity, Oxidation-Reduction, Adsorption, Electrochemistry, Ionic Liquids, Mechanical Phenomena, Chemical Sciences, Engineering, Physical Sciences

Abstract

We review recent developments in experimental techniques that simultaneously combine measurements of the interaction forces or energies between two extended surfaces immersed in electrolyte solutions-primarily aqueous-with simultaneous monitoring of their (electro)chemical reactions and controlling the electrochemical surface potential of at least one of the surfaces. Combination of these complementary techniques allows for simultaneous real time monitoring of angstrom level changes in surface thickness and roughness, surface-surface interaction energies, and charge and mass transferred via electrochemical reactions, dissolution, and adsorption, and/or charging of electric double layers. These techniques employ the surface forces apparatus (SFA) combined with various "electrochemical attachments" for in situ measurements of various physical and (electro)chemical properties (e.g., cyclic voltammetry), optical imaging, and electric potentials and currents generated naturally during an interaction, as well as when electric fields (potential differences) are applied between the surfaces and/or solution-in some cases allowing for the chemical reaction equation to be unambiguously determined. We discuss how the physical interactions between two different surfaces when brought close to each other (

Published

2013

14. Antioxidant efficacy and adhesion rescue by a recombinant mussel foot protein-6.

Author

Nicklisch, Sascha CT, Das, Saurabh, Martinez Rodriguez, Nadine R, Waite, J Herbert, and Israelachvili, Jacob N

Subjects

Animals, Muscle Proteins, Recombinant Proteins, Antioxidants, Amino Acid Sequence, Oxidation-Reduction, Mytilus, DOPA oxidation, adhesion rescue, antioxidant, recombinant mussel protein, thiol, Biotechnology, Biological Sciences, Engineering, Technology

Abstract

Mytilus foot protein type 6 (mfp-6) is crucial for maintaining the reducing conditions needed for optimal wet adhesion in marine mussels. In this report, we describe the expression and production of a recombinant Mytilus californianus foot protein type 6 variant 1 (rmfp-6.1) fused with a hexahistidine affinity tag in Escherichia coli and its purification by affinity chromatography. Recombinant mfp-6 showed high purification yields of 5-6 mg L(-1) cell culture and excellent solubility in low pH buffers that retard oxidation of its many thiol groups. Purified rmfp-6.1 protein showed high 2,2-diphenyl-1-picrylhydrazyl radical scavenging activity when compared with vitamin C. Using the highly sensitive surface forces apparatus (SFA) technique to measure interfacial surface forces in the nano-Newton range, we show that rmfp-6.1 is also able to rescue the oxidation-dependent adhesion loss of mussel foot protein 3 (mfp-3) at pH 3. The adhesion rescue is related to a reduction of dopaquinone back to 3,4-dihydroxyphenyl-l-alanine in mfp-3, which is the reverse reaction observed during the detrimental enzymatic browning process in fruits and vegetables. Broadly viewed, rmfp-6.1 has potential as a versatile antioxidant for applications ranging from personal products to antispoilants for perishable foods during processing and storage. © 2013 American Institute of Chemical Engineers Biotechnol. Prog., 29:1587-1593, 2013.

Published

2013

15. Antioxidant efficacy and adhesion rescue by a recombinant mussel foot protein‐6

Author

Nicklisch, Sascha CT, Das, Saurabh, Rodriguez, Nadine R Martinez, Waite, J Herbert, and Israelachvili, Jacob N

Subjects

Biotechnology, Amino Acid Sequence, Animals, Antioxidants, Muscle Proteins, Mytilus, Oxidation-Reduction, Recombinant Proteins, adhesion rescue, antioxidant, DOPA oxidation, recombinant mussel protein, thiol, Biological Sciences, Engineering, Technology

Abstract

Mytilus foot protein type 6 (mfp-6) is crucial for maintaining the reducing conditions needed for optimal wet adhesion in marine mussels. In this report, we describe the expression and production of a recombinant Mytilus californianus foot protein type 6 variant 1 (rmfp-6.1) fused with a hexahistidine affinity tag in Escherichia coli and its purification by affinity chromatography. Recombinant mfp-6 showed high purification yields of 5-6 mg L(-1) cell culture and excellent solubility in low pH buffers that retard oxidation of its many thiol groups. Purified rmfp-6.1 protein showed high 2,2-diphenyl-1-picrylhydrazyl radical scavenging activity when compared with vitamin C. Using the highly sensitive surface forces apparatus (SFA) technique to measure interfacial surface forces in the nano-Newton range, we show that rmfp-6.1 is also able to rescue the oxidation-dependent adhesion loss of mussel foot protein 3 (mfp-3) at pH 3. The adhesion rescue is related to a reduction of dopaquinone back to 3,4-dihydroxyphenyl-l-alanine in mfp-3, which is the reverse reaction observed during the detrimental enzymatic browning process in fruits and vegetables. Broadly viewed, rmfp-6.1 has potential as a versatile antioxidant for applications ranging from personal products to antispoilants for perishable foods during processing and storage. © 2013 American Institute of Chemical Engineers Biotechnol. Prog., 29:1587-1593, 2013.

Published

2013