Autotemplate Microcapsules of CaCO<sub>3</sub>/Pectin and Nonstoichiometric Complexes as Sustained Tetracycline Hydrochloride Delivery Carriers

Mihai, Marcela; Racoviţă, Stefania; Vasiliu, Ana‐Lavinia; Doroftei, Florica; Barbu-Mic, Cristian; Schwarz, Simona; Steinbach, Christine; Simon, Frank

doi:10.1021/acsami.7b09333

Cited by 22 publications

(21 citation statements)

References 56 publications

(73 reference statements)

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“…The encapsulation of actual drugs instead of model fluorescent dyes or fluorescently labeled polymers has been reported. Examples of encapsulated substances include the anticancer agents cisplatin 12 and doxorubicin 13 , tetracycline hydrochloride 14 , and photodynamic dyes 15 . Most published articles dealing with vaterite particles have reported in vitro studies of the uptake efficiency, toxicity (cell viability), and the kinetic release profiles of drugs 13,16,17 .…”

Section: Introductionmentioning

confidence: 99%

High-efficiency freezing-induced loading of inorganic nanoparticles and proteins into micron- and submicron-sized porous particles

German

Новоселова

Bratashov

et al. 2018

Sci Rep

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We demonstrate a novel approach to the controlled loading of inorganic nanoparticles and proteins into submicron- and micron-sized porous particles. The approach is based on freezing/thawing cycles, which lead to high loading densities. The process was tested for the inclusion of Au, magnetite nanoparticles, and bovine serum albumin in biocompatible vaterite carriers of micron and submicron sizes. The amounts of loaded nanoparticles or substances were adjusted by the number of freezing/thawing cycles. Our method afforded at least a three times higher loading of magnetite nanoparticles and a four times higher loading of protein for micron vaterite particles, in comparison with conventional methods such as adsorption and coprecipitation. The capsules loaded with magnetite nanoparticles by the freezing-induced loading method moved faster in a magnetic field gradient than did the capsules loaded by adsorption or coprecipitation. Our approach allows the preparation of multicomponent nanocomposite materials with designed properties such as remote control (e.g. via the application of an electromagnetic or acoustic field) and cargo unloading. Such materials could be used as multimodal contrast agents, drug delivery systems, and sensors.

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Section: Introductionmentioning

confidence: 99%

High-efficiency freezing-induced loading of inorganic nanoparticles and proteins into micron- and submicron-sized porous particles

German

Новоселова

Bratashov

et al. 2018

Sci Rep

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“…When amidated pectin samples was used to produce the NPECs (PCT53_A21), for NPECs with an excess of positively charged polyelectrolyte molecules (n + /n À ¼ 1.2) the surface net charge was only slightly affected by the variation of the pH value. 20 Thus, the composites used in this study are stable at pH higher than 5 and slightly decompose at lower pH, the complete decomposition taking place around pH ¼ 3. Therefore, the studied composites are suitable for prolong drug release at pH higher than 3.5 (ophthalmic and transdermal applications) and for rapid release at pH lower than 3 (stomach).…”

Section: Composite Microcapsulesmentioning

confidence: 83%

“…Aer mixing, the formed dispersions were stirred 60 min and were characterized and used in composite preparation aer 24 h. The composite microcapsules were obtained through co-precipitation of 0.05 M Na 2 CO 3 and 0.1 M CaCl 2 solutions in the presence of pectins or NPEC dispersions for 8 hours at room temperature, as described in our previous paper. 20 The shape and surface of the new particles were examined with an Environmental Scanning Electron Microscope type Quanta 200 using secondary electron (SE2) detector and Scanning Electron Microscope type Ultra plus (Carl Zeiss NTS) using energy selective backscattered (ESB) electron detector. To avoid electrostatic charging, the samples were coated with platinum or gold.…”

Section: Microparticles Preparation and Characterizationmentioning

confidence: 99%

Complex calcium carbonate/polymer microparticles as carriers for aminoglycoside antibiotics

et al. 2018

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Composite microparticles of CaCO 3 and two pectin samples (which differ by the functional group ratio) or corresponding nonstoichiometric polyelectrolyte complexes with different molar ratios (0.5, 0.9 and 1.2) are obtained, characterized and tested for loading and release of streptomycin and kanamycin sulphate. The synthesized carriers were characterized before and after drug loading in terms of morphology (by SEM using secondary electron and energy selective backscattered electron detectors), porosity (by water sorption isotherms) and elemental composition (by elemental mapping using energy dispersive X-ray and FTIR spectroscopy). The kinetics of the release mechanism from the microparticles was investigated using Higuchi and Korsmeyer-Peppas mathematical models. Electronic supplementary information (ESI) available: Chemical structure of materials used in this study; diffusion coefficients for pectin-CaCO 3 and NPEC-CaCO 3 composite microparticles, determined from sorption-desorption experimental data; sorption/desorption isotherms as relative humidity vs. weight variation; SEM images of pectin-CaCO 3 and NPEC-CaCO 3 microparticles aer STR and KAN retention and release; STR and KAN in vitro release curves; FTIR spectra of STR and KAN loaded samples; graphical representation of Higuchi and Korsmeyer-Peppas equations. See Scheme 1 The schematically representation of (I) NPECs synthesis, (II) formation of gel microparticles, (III) calcium carbonate growth with composite microparticles formation, (IV) drug loading and (V) release.This journal is

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“…Mihai et al 36 proposed a pathway for the formation of CaCO 3 capsules in the presence of pectins and nonstoichiometric polyelectrolyte complexes. The process involves the following steps: (1) interaction of calcium ions with ionic or ionizable groups along the polymer chain or on uncomplexed nanoparticle fragments with gelforming microparticles and crystallization of calcium carbonate in calcium rich areas; (2) growth of calcium carbonate crystals with microparticle formation (in the first minute of crystallization); (3) dissolution of the less stable (amorphous and vaterite) CaCO 3 fractions mainly by dissolving the core of the microparticles; (4) secondary nucleation of the calcite crystalline polymorph on the external surface; (5) progressive increase of the thickness of the crystalline wall as the core is emptied, yielding hollow microspheres.…”

Section: Calcium Carbonate Crystalization Mechanismsmentioning

confidence: 99%

“…Even if there are numerous studies on polyanions control of CaCO 3 growth, the use of nonstoichiometric polyelectrolyte complexes (NPEC) as templates for controlling CaCO 3 crystals growth has been reported up to now only by our group. 36,76,81 Polyelectrolyte complexes (PECs) are obtained by mixing aqueous solutions of oppositely charged polymers. 82 PECs are of interest due to their facile preparation and responsiveness to environmental stimuli.…”

Section: Caco 3 /Npec Compositesmentioning

confidence: 99%

Calcium Carbonate and Poly(2-Acrylamido-2-Methylpropanesulfonic Acid-Co-Acrylic Acid). A Review

Mihai¹,

Simionescu²

2019

Rev.Roum.Chim.

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Calcium carbonate minerals are the most abundant biogenic minerals, both in terms of the amounts produced and their widespread distribution. Adapting the design concepts from nature is a promising pathway to develop advanced materials. The organisms' main strategy to control mineralization is by using organic molecules as insoluble organic matrices, able to generate the proper environment for crystallization and to influence the nucleation processes, or soluble organic additives, which can influence crystals texture and morphology. There is a significant interest in using soluble additives, which vary from small molecules to large polymers, to control crystallization and generate crystals with complex morphologies. In this context, the aims of the review was to investigate the morphogenesis of calcium carbonate tuned by a strong/weak anionic copolymer, poly(2-acrylamido-2-methylpropanesulfonic acid-co-acrylic acid) (PAMPSAA), and different parameters-polymer presence and concentration, inorganic compound concentration, pH, and polyelectrolytes complexes.

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Autotemplate Microcapsules of CaCO₃/Pectin and Nonstoichiometric Complexes as Sustained Tetracycline Hydrochloride Delivery Carriers

Cited by 22 publications

References 56 publications

High-efficiency freezing-induced loading of inorganic nanoparticles and proteins into micron- and submicron-sized porous particles

High-efficiency freezing-induced loading of inorganic nanoparticles and proteins into micron- and submicron-sized porous particles

Complex calcium carbonate/polymer microparticles as carriers for aminoglycoside antibiotics

Calcium Carbonate and Poly(2-Acrylamido-2-Methylpropanesulfonic Acid-Co-Acrylic Acid). A Review

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Autotemplate Microcapsules of CaCO3/Pectin and Nonstoichiometric Complexes as Sustained Tetracycline Hydrochloride Delivery Carriers

Cited by 22 publications

References 56 publications

High-efficiency freezing-induced loading of inorganic nanoparticles and proteins into micron- and submicron-sized porous particles

High-efficiency freezing-induced loading of inorganic nanoparticles and proteins into micron- and submicron-sized porous particles

Complex calcium carbonate/polymer microparticles as carriers for aminoglycoside antibiotics

Calcium Carbonate and Poly(2-Acrylamido-2-Methylpropanesulfonic Acid-Co-Acrylic Acid). A Review

Contact Info

Product

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Autotemplate Microcapsules of CaCO₃/Pectin and Nonstoichiometric Complexes as Sustained Tetracycline Hydrochloride Delivery Carriers