Polycaprolactone/starch composite: Fabrication, structure, properties, and applications

Ghavimi, Soheila Ali Akbari; Ebrahimzadeh, Mohammad Ali; Solati‐Hashjin, Mehran; Osman, Noor Azuan Abu

doi:10.1002/jbm.a.35371

Cited by 107 publications

(49 citation statements)

References 199 publications

(262 reference statements)

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“…The polymer/solvent miscibility has been shown to have a direct bearing on the final fiber diameter and morphology. For instance, fibers made from PLA in dichloromethane have been shown to have a broader range of fiber diameters [32][33][34]. Results reported by Wei et al [35] on the electrospinning of Polyvinylidene fluoride (PVdF) nanofibers showed that the concentrations of solvent Methyl ethyl ketone (MEK) in DMF greatly influenced the dimensions and morphology of PVdF nanofibers.…”

Section: Introductionmentioning

confidence: 92%

Effect of Polymer Concentration, Rotational Speed, and Solvent Mixture on Fiber Formation Using Forcespinning®

Obregon

Agubra

Pokhrel

et al. 2016

Fibers

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Polycaprolactone (PCL) fibers were produced using Forcespinning ® (FS). The effects of PCL concentration, solvent mixture, and the spinneret rotational speed on fiber formation were evaluated. The concentration of the polymer in the solvents was a critical determinant of the solution viscosity. Lower PCL concentrations resulted in low solution viscosities with a correspondingly low fiber production rate with many beads. Bead-free fibers with high production rate and uniform fiber diameter distribution were obtained from the optimum PCL concentration (i.e., 12.5 wt%) with tetrahydrofuran (THF) as the solvent. The addition of N, N-dimethylformamide (DMF) to the THF solvent promoted the gradual formation of beads, split fibers, and generally affected the distribution of fiber diameters. The crystallinity of PCL fibers was also affected by the processing conditions, spinning speed, and solvent mixture.

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Section: Introductionmentioning

confidence: 92%

Effect of Polymer Concentration, Rotational Speed, and Solvent Mixture on Fiber Formation Using Forcespinning®

Obregon

Agubra

Pokhrel

et al. 2016

Fibers

View full text Add to dashboard Cite

show abstract

“…The most studied synthetic polymers in bone tissue regeneration are aliphatic polyesters like poly(lactic acid) (PLA), poly(ε‐caprolactone) and poly(glycolic acid), as well as their copolymers and derivatives. These polymers are degraded by hydrolysis in vivo and have the advantage of being easily tailored in different shapes, according to the mechanical demands in the particular bone treated (Yan et al., ; Ali Akbari Ghavimi, Ebrahimzadeh, Solati‐Hashjin, & Abu Osman, ; Pilipchuk et al., ). However, synthetic polymers still show some concerns about osteoconductivity, absorption timing and local pH alterations.…”

Section: Review Of Current Literaturementioning

confidence: 99%

Bone grafts: which is the ideal biomaterial?

Haugen

Lyngstadaas

Rossi

et al. 2019

J Clinic Periodontology

418

353

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Bovine xenograft materials, followed by synthetic biomaterials, which unfortunately still lack documented predictability and clinical performance, dominate the market for the cranio‐maxillofacial area. In Europe, new stringent regulations are expected to further limit the allograft market in the future. Aim Within this narrative review, we discuss possible future biomaterials for bone replacement. Scientific Rationale for Study Although the bone graft (BG) literature is overflooded, only a handful of new BG substitutes are clinically available. Laboratory studies tend to focus on advanced production methods and novel biomaterial features, which can be costly to produce. Practical Implications In this review, we ask why such a limited number of BGs are clinically available when compared to extensive laboratory studies. We also discuss what features are needed for an ideal BG. Results We have identified the key properties of current bone substitutes and have provided important information to guide clinical decision‐making and generate new perspectives on bone substitutes. Our results indicated that different mechanical and biological properties are needed despite each having a broad spectrum of variations. Conclusions We foresee bone replacement composite materials with higher levels of bioactivity, providing an appropriate balance between bioabsorption and volume maintenance for achieving ideal bone remodelling.

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“…Therefore, PCL has been blended with other polymers (i.e., starch, PLA, etc.) to reduce costs while preserving or improving the biodegradability of the resulting materials …”

Section: Biodegradable Polymersmentioning

confidence: 99%

Biodegradable compatibilized polymer blends for packaging applications: A literature review

Muthuraj

Misra

Mohanty

2017

J of Applied Polymer Sci

307

183

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The majority of materials used for short-term and disposable packaging application are non-biodegradable which are not satisfying the demands in environmental safety and sustainability. Biodegradable polymers are an alternative for these nonbiodegradable materials. The biodegradable polymeric materials can degrade in a reasonable time period without causing environmental problems. However, biodegradable polymers possess some limitations such as comparatively high cost, insufficient mechanical performances, and inferior thermal stability to extend their widespread application in packaging industry. To overcome these limitations, one of the most commonly used strategies is melt blending of dissimilar biodegradable polymers. Unfortunately, most of the biodegradable polymer blends exhibit insufficient performance because they are thermodynamically immiscible as well as exhibit poor compatibility between the blended components. It has been established that the compatibilization is a well-known strategy to improve the performances of the immiscible biodegradable polymer blends by enhancing the adhesion between the phases. As a result, recent studies focus on various compatibilizers to enhance the performances of the resulting biodegradable polymer blends. This review summarizes the recent developments on a variety of biodegradable polymer blends compatibilized by melt processing with a main focus of ex situ and in situ compatibilization strategies.

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Polycaprolactone/starch composite: Fabrication, structure, properties, and applications

Cited by 107 publications

References 199 publications

Effect of Polymer Concentration, Rotational Speed, and Solvent Mixture on Fiber Formation Using Forcespinning®

Effect of Polymer Concentration, Rotational Speed, and Solvent Mixture on Fiber Formation Using Forcespinning®

Bone grafts: which is the ideal biomaterial?

Biodegradable compatibilized polymer blends for packaging applications: A literature review

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