Kinetic effect of hydroxyapatite types on the polymerization of acrylic bone cements

Morejón, L.; Delgado, José Ángel García; Davidenko, Natalia; Mendizábal, Eduardo; Barbosa, E. H.; Jasso, C. F.

doi:10.1080/00914030304903

Cited by 24 publications

(27 citation statements)

References 24 publications

(13 reference statements)

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“…A decrease in peak temperature and slower reaction has also been reported when using HA as a filler. [8] Because a lower temperature peak may cause less damage to surrounding tissues, lower reaction rates are convenient for long term fixation of an implant. The slower reactions and peak temperatures can be explained in terms of filler higher thermal conductivity (2.4 $ 3.0 W/m Á K) compared to that of PMMA (0.46 W/mK).…”

Section: Resultsmentioning

confidence: 99%

“…[1] Because almost 98 wt% of the total calcium in human organisms is present in the osseous structure as hydroxyapatite crystals C 10 (PO 4 ) 6 (OH) 2 , calcium phosphate Ca 3 (PO 4 ) 2 , and calcium carbonate CaCO 3 , [5] in an attempt to increase biocompatibility and to promote bone growth around an implant, several studies incorporating hydroxyapatite (HA) and calcium phosphate have been reported. [1,[6][7][8] The presence of bioactive particles, besides modifying mechanical properties of the bone cement, [8,9] also affects curing characteristics. Morejó n et al, reported that when using HA as filler in a poly (methyl methacrylate-co-styrene) bone cement, lower curing temperature peaks than for the unfilled cement were obtained.…”

Section: Introductionmentioning

confidence: 99%

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Acrylic Bone Cements Modified With Bioactive Filler

Jasso-Gastinel

García-Enriquez

Flores

et al. 2009

Macromolecular Symposia

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Summary: Bioactive cuttlebone Sepia officinalis particles that contain collagen were used to fill poly (methyl methacrylate-co-styrene) bone cements, varying size and concentration of filler particles. Cuttlebone was characterized by X-ray diffraction and plasma atomic emission spectrophotometer. Maximum reaction temperature and cement setting time were determined for composites and reference (copolymer without filler), along with NMR determination of residual monomer concentration. Mechanical properties characterization included stress-strain, bending, compression, fracture toughness and storage modulus tests. Mechanical results for composites filled with 10 and 30% weight of cuttlebone, complied with norm requirements which opens the possibility for using cuttlebone particles as bioactive filler.

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Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Acrylic Bone Cements Modified With Bioactive Filler

Jasso-Gastinel

García-Enriquez

Flores

et al. 2009

Macromolecular Symposia

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“…The significance of each of these properties has been discussed in the literature. Thus, (1) FL is important in terms of the fact that fatigue of the cement mantle has been implicated in aseptic loosening of cemented TJRs, which is the leading cause of their failure [17] (thus, high FL is desirable); (2) K IC is an index of the damage tolerance of the cement (that is, its ability to resist brittle fracture in the presence of crack(s) in it) [18] (thus, high K IC is desirable); (3) k 0 is related to the long-term in vivo stability of a cemented arthroplasty [19] (low k 0 is desirable); and (4) D is an index of the potential for the plasticizing influence of PBS on the cement's properties; thus, there are reports of this influence in the case of, for example, ultimate tensile strength [20], glass transition temperature [21], and elastic modulus [22]. There is disagreement on whether such reductions are detrimental to the in situ life of a cemented TJR; for example, Lewis et al [22] suggested that high D adversely affects the dimensional stability of the cement whereas Kuhn et al [21] suggested that lowered modulus may be beneficial.…”

Section: Discussionmentioning

confidence: 99%

Not all approved antibiotic-loaded PMMA bone cement brands are the same: ranking using the utility materials selection concept

Lewis

2015

J Mater Sci: Mater Med

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In the literature on in vitro characterization of approved antibiotic-loaded poly(methyl methacrylate) bone cement brands, there is no information on the basis for selection of a given brand for use in cemented arthroplasties. This shortcoming is addressed in the present study. It involved determining four key properties (fatigue limit, fracture toughness, polymerization rate, and phosphate buffered saline diffusion coefficient) for six brands and then using the mean property values, in conjunction with a materials selection methodology, called the utility concept, to rank the brands. It is emphasized that the present work is an illustration of a rational approach to selection of a cement brand and, as such, the study findings are not intended to be recommendations regarding clinical use or otherwise of a brand.

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“…[8] Se conoce que los altos calores de polimerización pueden causar necrosis del tejido en los alrededores de la prótesis y además puede afectar severamente la durabilidad del implante debido a que induce la reabsorción del tejido óseo y produce aflojamiento de la prótesis. [9] El estudio de la bioactividad in vitro es un ensayo importante a valorar en este tipo de biomateriales. [8] Su determinación se fundamentan en el hecho de que en los materiales cerámicos que se enlazan directamente al hueso se ha podido demostrar que las primeras etapas del mecanismo de enlace pueden simularse en un medio inorgánico, sin presencia de células, siempre y cuando dicho medio contenga los iones necesarios para que el material pueda desarrollar una nueva fase tipo carbonato-hidroxiapatita (CHA) en su superficie.…”

Section: Caracterización Mecánicaunclassified

Cementos óseos acrílicos modificados con hidroxiapatita/acetato de vinilo: caracterización mecánica, termoanálitica y bioactividad in vitro

2010

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Resumen: Los cementos óseos se han convertido en los últimos años en biomateriales de gran utilidad en la fijación de prótesis y en la reconstrucción del hueso. El objetivo de este trabajo es evaluar las propiedades termoanalíticas tales como temperatura máxima de polimerización y tiempo de fraguado en cementos óseos acrílicos modificados con hidroxiapatita/ acetato de vinilo, determinar la resistencia a la compresión axial y realizar ensayos de bioactividad in vitro. Diferentes contenidos de acetato de vinilo fueron incorporados en cementos óseos acrílicos cargados todos con un 30 % de hidroxiapatita CORALINA ® HAP-200. Las propiedades mecánicas y los parámetros de curado fueron evaluados cumpliendo lo establecido en la Norma ISO 5833 descrita para cementos óseos acrílicos. Se determinaron los parámetros termoanalíticos, obteniéndose tiempos de fraguados entre 3 y 6 minutos y los valores de temperaturas máximas de polimerización oscilan entre 66 y 88 °C. Se obtuvo formulaciones con valores de resistencia a la compresión superiores a lo establecido en la Norma ISO 5833. Se demostró la bioactividad de las formulaciones mediante la inmersión de las muestras en fluido biológico simulado, observándose en la superficie de las mismas la nucleación y el crecimiento de cristales con morfología similar a las apatitas biológicas. Palabras-clave: Cementos óseos acrílicos, hidroxiapatita, tiempo de fraguado, resistencia a la compresión. Acrylic Bone Cement Modified whit Hydroxiapatyte/Vinyl Acetate. Mechanical, Thermoanalytical Characterization and In Vitro BioactivityAbstract: Bone cements have become biomaterials of great utility in the prosthesis fixation and as substitutes to the bone. The objective of this study is to evaluate the thermo analytical properties such as setting time and peak temperature of polymerization of acrylic bone cement modified with hydroxyapatite/vinyl acetate, to determine the compression strengths and perform in vitro bioactivity tests. Amounts of vinyl acetate component were incorporated in different percentages in acrylic bone cements, all loaded with 30 % of hydroxyapatite CORALINA ® HAP-200. Curing parameters and mechanical properties were determined finding formulations that comply with the ISO 5833 norm. In vitro bioactivity tests were performed in two cement formulations. The setting time obtained ranged between 3 and 6 minutes and the peak temperature varied between 66 and 88 °C. Compression strengths were higher than established in the ISO 5833 regulation for mechanical properties evaluation of acrylic bone cements. The bioactivity was demonstrated by immersion of the samples in simulated body fluid, in which nucleation and crystal growth were observed on the sample surface with similar morphology and composition to biological apatite.

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Kinetic effect of hydroxyapatite types on the polymerization of acrylic bone cements

Cited by 24 publications

References 24 publications

Acrylic Bone Cements Modified With Bioactive Filler

Acrylic Bone Cements Modified With Bioactive Filler

Not all approved antibiotic-loaded PMMA bone cement brands are the same: ranking using the utility materials selection concept

Cementos óseos acrílicos modificados con hidroxiapatita/acetato de vinilo: caracterización mecánica, termoanálitica y bioactividad in vitro

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