Mesoporous One-Component Gold Microshells as 3D SERS Substrates

Vikulina, Anna S.; Stetsyura, Inna Y.; Önses, M. Serdar; Yılmaz, Erkan; Skirtach, André G.; Volodkin, Dmitry

doi:10.3390/bios11100380

Cited by 5 publications

(5 citation statements)

References 41 publications

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“…Nanoparticle arrays hold promising applications across diverse fields. They can serve as sophisticated photonic structures, finding utility in structural coloration and advanced optical biosensing [ 70 , 74 , 75 ]. Furthermore, they offer the potential to develop electronic nano-devices and chemical/biological sensors.…”

Section: Static Assembly Methodsmentioning

confidence: 99%

“…Table 1 provides the advantages and disadvantages of each assembly technique studied in this review. Static methods like layer-by-layer assembly [ 51 , 52 , 53 , 58 , 59 , 60 , 61 , 62 ] and template-assisted assembly [ 2 , 10 , 16 , 29 , 70 , 72 , 73 , 74 , 75 ] may need specific substrates. Polymer brushes [ 83 , 84 , 85 , 86 ] offer adjustability but risk aggregation.…”

Section: Comparative Analysis Of Static and Dynamic Methods: Challeng...mentioning

confidence: 99%

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Advances in Nanoarchitectonics: A Review of “Static” and “Dynamic” Particle Assembly Methods

Eftekhari,

Parakhonskiy,

Grigoriev

et al. 2024

Materials

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Particle assembly is a promising technique to create functional materials and devices from nanoscale building blocks. However, the control of particle arrangement and orientation is challenging and requires careful design of the assembly methods and conditions. In this study, the static and dynamic methods of particle assembly are reviewed, focusing on their applications in biomaterial sciences. Static methods rely on the equilibrium interactions between particles and substrates, such as electrostatic, magnetic, or capillary forces. Dynamic methods can be associated with the application of external stimuli, such as electric fields, magnetic fields, light, or sound, to manipulate the particles in a non-equilibrium state. This study discusses the advantages and limitations of such methods as well as nanoarchitectonic principles that guide the formation of desired structures and functions. It also highlights some examples of biomaterials and devices that have been fabricated by particle assembly, such as biosensors, drug delivery systems, tissue engineering scaffolds, and artificial organs. It concludes by outlining the future challenges and opportunities of particle assembly for biomaterial sciences. This review stands as a crucial guide for scholars and professionals in the field, fostering further investigation and innovation. It also highlights the necessity for continuous research to refine these methodologies and devise more efficient techniques for nanomaterial synthesis. The potential ramifications on healthcare and technology are substantial, with implications for drug delivery systems, diagnostic tools, disease treatments, energy storage, environmental science, and electronics.

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Section: Static Assembly Methodsmentioning

confidence: 99%

Section: Comparative Analysis Of Static and Dynamic Methods: Challeng...mentioning

confidence: 99%

Advances in Nanoarchitectonics: A Review of “Static” and “Dynamic” Particle Assembly Methods

Eftekhari,

Parakhonskiy,

Grigoriev

et al. 2024

Materials

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“…In general, vaterite-based hard templating has attracted significant scientific attention in the past due to the biocompatible conditions used to decompose the templates, offering an option to work with fragile (bio)molecules to form micro-sized particles loaded with sensitive proteins and enzymes as well as other biologically active small and large molecules of different natures [ 18 , 19 , 20 , 21 , 22 , 23 , 24 , 25 ]. Moreover, the internal structure of the vaterite crystals allows for the forming of an inverted replica of the solid crystals made of soft polymers [ 26 ] or hard nanoparticles [ 27 , 28 , 29 , 30 , 31 , 32 ].…”

Section: Introductionmentioning

confidence: 99%

Formulation and Biodegradation of Surface-Supported Biopolymer-Based Microgels Formed via Hard Templating onto Vaterite CaCO3 Crystals

Mammen,

Hogg,

Craske

et al. 2023

Materials

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In recent decades, there has been increased attention to the role of layer-by-layer assembled bio-polymer 3D structures (capsules, beads, and microgels) for biomedical applications. Such free-standing multilayer structures are formed via hard templating onto sacrificial cores such as vaterite CaCO3 crystals. Immobilization of these structures onto solid surfaces (e.g., implants and catheters) opens the way for the formulation of advanced bio-coating with a patterned surface. However, the immobilization step is challenging. Multiple approaches based mainly on covalent binding have been developed to localize these multilayer 3D structures at the surface. This work reports a novel strategy to formulate multilayer surface-supported microgels (ss-MG) directly on the surface via hard templating onto ss-CaCO3 pre-grown onto the surface via the direct mixing of Na2CO3 and CaCl2 precursor solutions. ss-MGs were fabricated using biopolymers: polylysine (PLL) as polycation and three polyanions—hyaluronic acid (HA), heparin sulfate (HS), and alginate (ALG). ss-MG biodegradation was examined by employing the enzyme trypsin. Our studies indicate that the adhesion of the ss-MG to the surface and its formation yield directly correlate with the mobility of biopolymers in the ss-MG, which decreases in the sequence of ALG > HA > HS-based ss-MGs. The adhesion of HS-based ss-MGs is only possible via heating during their formation. Dextran-loading increases ss-MG formation yield while reducing ss-MG shrinking. ss-MGs with higher polymer mobility possess slower biodegradation rates, which is likely due to diffusion limitations for the enzyme in more compact annealed ss-MGs. These findings provide valuable insights into the mechanisms underlying the formation and biodegradation of surface-supported biopolymer structures.

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“…[21,[26][27][28][29] One of the main drawbacks of vaterite crystals are their inherent metastability and rather quick degradation/recrystallization in aqueous environments. [30] Degradation/decomposition of vaterite is required for hard templating of polymer, protein, inorganic or hybrid structures [22,[31][32][33][34] by means of loading the vaterite pores, followed by vaterite solubilisation. Although such properties may be beneficial for some medical applications, for example, pH-triggered release in tumor sites, [35][36][37] many other applications require the stabilization of vaterite and the suppression of its recrystallization.…”

Section: Introductionmentioning

confidence: 99%

Dextran and Its Derivatives: Biopolymer Additives for the Modulation of Vaterite CaCO₃ Crystal Morphology and Adhesion to Cells

Campbell

Ferreira

Bowker

et al. 2022

Adv Materials Inter

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Nowadays, a great demand for the development of novel drug delivery systems with high potential for bench‐to‐market transition attracts scientific attention toward materials that are already approved for biomedical use. Here, controlled fabrication of hybrid organic inorganic mesoporous crystals is realized in physiologically relevant conditions by co‐synthesis of vaterite CaCO3 in the presence of dextran (DEX) or its functional derivatives. The effects of DEX molecular weight and chemical structure on morphology, porosity, and stability of the hybrids are investigated. Molecular weight of DEX does not affect the crystal growth but leads to the partial blocking of crystal pores. Co‐synthesis of DEX functionalized with either carboxymethyl (CM) or diethylaminoethyl (DEAE) groups drastically increased crystal porosity without influencing crystal size. pH‐dependent vaterite‐to‐calcite recrystallization is significantly suppressed by inclusion of carboxymethyl‐dextran (CM‐DEX), making vaterite crystals stable in acidic medium, whereas the incorporation of diethylaminoethyl‐dextran (DEAE‐DEX) has no effect. The hybrids prepared with charged DEX derivatives possess stronger adhesion to normal human dermal fibroblasts: three times higher crystal adherence compared to pristine crystals. These results provide fundamental physical–chemical insights into the crystallization of DEX/vaterite hybrids and are discussed in view of the potential of these functional delivery carriers for biomedical and other applications.

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Mesoporous One-Component Gold Microshells as 3D SERS Substrates

Cited by 5 publications

References 41 publications

Advances in Nanoarchitectonics: A Review of “Static” and “Dynamic” Particle Assembly Methods

Advances in Nanoarchitectonics: A Review of “Static” and “Dynamic” Particle Assembly Methods

Formulation and Biodegradation of Surface-Supported Biopolymer-Based Microgels Formed via Hard Templating onto Vaterite CaCO3 Crystals

Dextran and Its Derivatives: Biopolymer Additives for the Modulation of Vaterite CaCO₃ Crystal Morphology and Adhesion to Cells

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Mesoporous One-Component Gold Microshells as 3D SERS Substrates

Cited by 5 publications

References 41 publications

Advances in Nanoarchitectonics: A Review of “Static” and “Dynamic” Particle Assembly Methods

Advances in Nanoarchitectonics: A Review of “Static” and “Dynamic” Particle Assembly Methods

Formulation and Biodegradation of Surface-Supported Biopolymer-Based Microgels Formed via Hard Templating onto Vaterite CaCO3 Crystals

Dextran and Its Derivatives: Biopolymer Additives for the Modulation of Vaterite CaCO3 Crystal Morphology and Adhesion to Cells

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Product

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Dextran and Its Derivatives: Biopolymer Additives for the Modulation of Vaterite CaCO₃ Crystal Morphology and Adhesion to Cells