Swellable Hydrogel-based Systems for Controlled Drug Delivery

Caccavo, Diego; Cascone, Sara; Lamberti, Gaetano; Barba, Anna Angela; Larsson, Anette

doi:10.5772/61792

Cited by 42 publications

(38 citation statements)

References 125 publications

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“…Of the different systems, hydrogels that form nanofiber networks are promising in vivo carriers. Hydrogels offer dynamic and novel applications due to their unique properties, including: swelling with water, housing drugs and ligands, and being made into a multitude of mechanical and morphological configurations that provide multiple means of controlling release [4][5][6][7][8]. However, developing exact and tuneable release mechanisms and morphological features can be extremely complicated, needing additional chemical synthesis involving toxic co-solvents, chemical triggers, or full transplantation to provide a fully formed network in vivo [9].…”

Section: Introductionmentioning

confidence: 99%

Towards Developing Bioresponsive, Self-Assembled Peptide Materials: Dynamic Morphology and Fractal Nature of Nanostructured Matrices

Koss

Unsworth

2018

Preprint

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Abstract(RADA)4 nanoscaffolds are excellent candidates for use as peptide delivery vehicles: they are relatively easy to synthesize with custom bio-functionality, and assemble in situ to allow a focal point of release. This enables (RADA)4 to be utilized in multiple release strategies by embedding a variety of bioactive molecules in an all-in-one 'construct'. One novel strategy focuses on the local, on-demand release of peptides triggered via proteolysis of tethered peptide sequences. However, the spatial-temporal morphology of self-assembling nanoscaffolds may greatly influence the ability for enzymes to both diffuse into as well as actively cleave substrates. Fine structure and its impact on overall affect on peptide release is poorly understood. In addition, fractal networks observed in nanoscaffolds are linked to the fractal nature of diffusion in these systems. Therefore, matrix morphology and fractal dimension of virgin (RADA)4 and mixtures of (RADA)4 and matrix metalloproteinase 2 (MMP-2) cleavable substrate modified (RADA)4 were characterized over time. Sites of high (GPQG+IASQ, CP1) and low (GPQG+PAGQ, CP2) cleavage activity were chosen. Fine structure was visualized using established according to established methods. After 2 hrs of incubation, nanofiber networks showed an established fractal nature, however nanofibers continued to bundle in all cases as incubation times increased. It was observed that despite extensive nanofiber bundling after 24 hrs of incubation time, the CP1 and CP2 nanoscaffolds were susceptible to MMP-2 cleavage. The properties of these engineered nanoscaffolds characterized herein illustrate that they are an excellent candidate as an enzymatically initiated peptide delivery platform. Preprints (www.preprints.org) | NOT PEER-REVIEWED | Posted: 23 July 2018doi:10.20944/preprints201807.0435.v1Peer-reviewed version available at Materials 2018, 11, 1539; doi:10.3390/ma11091539 3 Keywords: Self-assembling peptides, RADA16, (RADA)4, MMP-2, Nanoscaffold, Hausdorff dimension, Fractal Statement of SignificanceThe (RADA)4 peptide sequence boasts major benefits over other drug delivery systems: it is capable of forming a focal point of diffusion that houses and releases a variety of ligands in physiological conditions, and it is simple to add other functionally degradable peptide motifs during a one-step synthesis. As such, we added protease cleavable sites cued to injury to create a novel delivery system. However, the addition of peptides may inhibit the desired self-assembly of these nanoscaffolds. In our study we addressed this concern by observing nanoscale architecture and fractal features during self-assembly, which have been linked to diffusion in similar scaffolds. We also demonstrated that these materials can degrade with the hypothesized proteolytic cues.Preprints (www.preprints.org) | NOT PEER-REVIEWED | Posted:

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Section: Introductionmentioning

confidence: 99%

Towards Developing Bioresponsive, Self-Assembled Peptide Materials: Dynamic Morphology and Fractal Nature of Nanostructured Matrices

Koss

Unsworth

2018

Preprint

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“…Moreover, the maximum protein content is considerably smaller in the artificial gastric fluid (0.18 mg/L) than in the intestinal environment (1.97 mg/L). The protein release into the intestinal environment is affected by swelling of the hydrogel [23]. Its high swelling ability causes the trapped bromelain to easily diffuse out through the pores.…”

Section: Dissolution Test For Bromelain Encapsulated In Alg-gg Hydrogelmentioning

confidence: 99%

Dissolution Kinetics of Partially Purified Bromelain From Pineapple Cores (Ananas Comosus [L.] Merr.) Encapsulated in Glutaraldehyde-Crosslinked Alginate-Guar Gum

Juliano

Prabowo

Budianto

et al. 2020

Asian J Pharm Clin Res

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Objective: Bromelain is susceptible to low pH and thus must be encapsulated in glutaraldehyde-crosslinked alginate-guar gum (Alg-GG) hydrogels to avoid bromelain activity degradation in the stomach. Methods: Isolated crude bromelain was purified through ammonium sulfate precipitation, sodium benzoate precipitation, and dialysis. Bromelain-loaded Alg-GG was dissolved in artificial gastric fluid and intestinal environment. Results: The bromelain fractions showed a higher specific activity (U/mg) than the crude enzyme (51.32), as follows ammonium sulfate fraction (267.70±4.67), sodium benzoate fraction (115.63±3.35), and dialysis fraction (332.22). The dialysis fraction was encapsulated in Alg-GG hydrogel containing 0.75% (v/v) glutaraldehyde through the post-loading method. The swelling ratios of the hydrogel are 188.43% at pH 1.2 and 563.83% at pH 7.4. The highest encapsulation efficiency is 72.2%. The maximum bromelain concentration released during dissolution is higher in artificial intestinal environment (1.97 mg/L) than in artificial gastric fluid (0.18 mg/L), and the maximum proteolytic activities are 1.3 and 0.15 U/mL, respectively. Data were incorporated into the zero-order, first-order, Higuchi, and Korsmeyer–Peppas models to determine the kinetics and mechanism of bromelain dissolution. All bromelain concentrations (70, 140, and 210 ppm) follow the Korsmeyer–Peppas model. The dissolution mechanism is a combination of diffusion and erosion. Both the dialysis fraction (56.59%) and the dissolution product (47.45%) showed a good in vitro antiplatelet activity. Conclusion: The present data show the promise of Alg-GG encapsulation as a vehicle for orally administered therapeutic enzymes.

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“…The water uptake depending on pH can be a key parameter to determine the swelling phenomenon and, as a consequence, the drug release from a matrix. [45] Release kinetics is faster at the beginning and tends to decrease with time, till all of the drug contained in the matrix reaches the dissolution medium. [45] Release kinetics is faster at the beginning and tends to decrease with time, till all of the drug contained in the matrix reaches the dissolution medium.…”

Section: Drug Deliverymentioning

confidence: 99%

“…A typical drug release profile via diffusion from PEs is shown in Figure 5, red circles on the right axis. [45] Release kinetics is faster at the beginning and tends to decrease with time, till all of the drug contained in the matrix reaches the dissolution medium. Release kinetics for pH sensitive sys tems is strongly dependent from the pH: either capsule being in open or closed state.…”

Section: Drug Deliverymentioning

confidence: 99%

How Can One Controllably Use of Natural ΔpH in Polyelectrolyte Multilayers?

Skorb

Möhwald

Andreeva

2016

Adv Materials Inter

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Most natural and synthetic polyelectrolytes (PEs) possess dissociable groups, and therefore the corresponding structures depend on pH. This enables manipulation of their properties, in special permeability, elasticity and swelling, and this can be made use of in many applications. The effect of individual polymer composition on the dissociation equilibrium is discussed. Different concentrations and pH values during the PE assembly affect concentration of charged groups per molecule on the dissociation equilibrium. Ionic strength also influences the protonation/deprotonation behavior of PE, that can be changed by adding different salt concentration but also varies with the concentration of charged groups in the polymer molecules. Electrostatic interactions of the polymer molecules strongly affect the dissociation equilibrium of weak PEs and, thus, layers architecture and properties that can be regulated by natural pH changes in such processes as self-healing, corrosion and antifouling, drug storage and delivery, etc

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Swellable Hydrogel-based Systems for Controlled Drug Delivery

Cited by 42 publications

References 125 publications

Towards Developing Bioresponsive, Self-Assembled Peptide Materials: Dynamic Morphology and Fractal Nature of Nanostructured Matrices

Towards Developing Bioresponsive, Self-Assembled Peptide Materials: Dynamic Morphology and Fractal Nature of Nanostructured Matrices

Dissolution Kinetics of Partially Purified Bromelain From Pineapple Cores (Ananas Comosus [L.] Merr.) Encapsulated in Glutaraldehyde-Crosslinked Alginate-Guar Gum

How Can One Controllably Use of Natural ΔpH in Polyelectrolyte Multilayers?

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