Development of Halloysite Loaded Polypropylene Sutures with Enhanced Mechanical and Thermal Properties

Fadime Nülüfer Kıvılcım

doi:10.17776/csj.1228170

Research Article

Year 2023, , 106 - 111, 26.03.2023

Fadime Nülüfer Kıvılcım

https://doi.org/10.17776/csj.1228170

Abstract

Keywords

Polypropylene, halloysite, polypropylene composites, suture mechanic properties

References

[1] Dennis C., Sethu S., Nayak S., Mohan L., Morsi Y., & Manivasagam G., Suture materials—Current and emerging trends, Journal of Biomedical Materials Research, Part A, 104 (6) (2016) 1544-1559.
[2] Abhari R. E., Martins J. A., Morris H., Mouthuy P. A., Carr A., Synthetic sutures: Clinical evaluation and future developments, Journal of Biomaterials Applications, 32 (3) (2017) 410-421.
[3] Chu C. C., Mechanical properties of suture materials: an important characterization, Annals of Surgery, 193 (3) (1981) 365.
[4] Zhukovskii V. A., Problems and prospects for development and production of surgical suture materials, Fibre Chemistry, 40 (3) (2008) 208-216.
[5] Srinivasulu K., Kumar N. D., A review on properties of surgical sutures and applications in medical field, Int. J. Res. Eng. Technol., 2 (2) (2014) 85-96.
[6] Najibi S., Banglmeier R., Matta J. M., Tannast M., Material properties of common suture materials in orthopaedic surgery, The Iowa Orthopaedic Journal, 30 (2010) 84-88.
[7] Naleway S. E., Lear W., Kruzic J. J., Maughan C. B., Mechanical properties of suture materials in general and cutaneous surgery, Journal of Biomedical Materials Research Part B: Applied Biomaterials, 103 (4) (2015) 735-742.
[8] Byrne M., Aly A., The surgical suture, Aesthetic Surgery Journal, 39 (2) (2019) 67-72.
[9] Bloom B. S., Goldberg D J., Suture material in cosmetic cutaneous surgery, Journal of Cosmetic and Laser Therapy, 9 (1) (2007) 41-45.
[10] Saxena S., Ray A. R., Kapil A., Pavon‐Djavid G., Letourneur D., Gupta B., Meddahi‐Pellé A., Development of a new polypropylene‐based suture: plasma grafting, surface treatment, characterization, and biocompatibility studies, Macromolecular Bioscience, 11(3) (2011) 373-382.
[11] Sun J., Yao L., Zhao Q. L., Huang J., Song R., Ma Z., Hao Y. M., Modification on crystallization of poly (vinylidene fluoride)(PVDF) by solvent extraction of poly (methyl methacrylate)(PMMA) in PVDF/PMMA blends, Frontiers of Materials Science, 5 (4) (2011) 388-400.
[12] Boland E. D., Coleman B. D., Barnes C. P., Simpson D. G., Wnek G. E., Bowlin G. L., Electrospinning polydioxanone for biomedical applications, Acta Biomaterialia, 1 (1) (2005) 115-123.
[13] Chen Y., Geever L. M., Killion J. A., Lyons J. G., Higginbotham C. L., Devine D. M., Review of multifarious applications of poly (lactic acid), Polymer-Plastics Technology and Engineering, 55 (10) (2016) 1057-1075.
[14] Singhvi M. S., Zinjarde S. S., Gokhale D. V., Polylactic acid: synthesis and biomedical applications, Journal of Applied Microbiology, 127 (6) (2019) 1612-1626.
[15] Budak K., Sogut O., Aydemir Sezer U., A review on synthesis and biomedical applications of polyglycolic acid, Journal of Polymer Research, 27 (8) (2020):1-19.
[16] Chu C. C., Materials for absorbable and nonabsorbable surgical sutures, In Biotextiles as Medical Implants, Woodhead Publishing Series in Textiles, (2013) 275-334.
[17] Linderman S. W., Kormpakis I., Gelberman R. H., Birman V., Wegst U. G., Genin G. M., Thomopoulos S., Shear lag sutures: Improved suture repair through the use of adhesives, Acta Biomaterialia, 23 (2015) 229-239.
[18] Wang B., Yang W., Sherman V. R., Meyers M. A., Pangolin armor: overlapping, structure, and mechanical properties of the keratinous scales, Acta Biomaterialia, 41 (2016) 60-74.
[19] Javed F., Al-Askar M., Almas K., Romanos G. E., Al-Hezaimi K., Tissue reactions to various suture materials used in oral surgical interventions, International Scholarly Research Notices, (2012) 762095
[20] Acosta S., Björck M., Wanhainen A., Negative-pressure wound therapy for prevention and treatment of surgical-site infections after vascular surgery, Journal of British Surgery, 104 (2) (2017) 75-84.
[21] Joussein E., Petit S., Churchman J., Theng B., Righi D., Delvaux B., Halloysite clay minerals—a review, Clay Minerals, 40 (4) (2005) 383-426.
[22] Yuan P., Tan D., Annabi-Bergaya F., Properties and applications of halloysite nanotubes: recent research advances and future prospects, Applied Clay Science, 112 (2015) 75-93.
[23] Danyliuk N., Tomaszewska J., Tatarchuk T., Halloysite nanotubes and halloysite-based composites for environmental and biomedical applications, Journal of Molecular Liquids, 309 (2020) 113077.

Development of Halloysite Loaded Polypropylene Sutures with Enhanced Mechanical and Thermal Properties

Year 2023, , 106 - 111, 26.03.2023

Fadime Nülüfer Kıvılcım

https://doi.org/10.17776/csj.1228170

Abstract

Polypropylene is a crucial polymeric material in modern life, especially in the packaging and food industry, as well as the biomedical field. This study aimed to enhance the mechanical properties of polypropylene structures used as surgical suture material by preparing polypropylene-halloysite (PP-halloysite) composites. Halloysite was added in varying amounts (1%, 3%, 5%, and 10%) to polypropylene, and the resulting composites were passed through a double heated extruder. Structural characterization of the PP-halloysite composites was carried out using Fourier Transform Infrared Spectroscopy (FTIR), elemental analysis, Scanning Electron Microscopy-Energy Dispersive X-Ray Analysis (SEM-EDX), Differential Thermal Analysis (DTA), Thermogravimetric Analysis (TGA) ), and Differential Scanning Calorimetry (DSC) techniques to determine their thermal properties and softening temperatures. Mechanical tests were conducted to examine the composite suture structures obtained and determine the effect of halloysite doping on their mechanical properties. The results of the mechanical tests showed that the mechanical strength of the fiber structure increased with the amount of halloysite added. Therefore, the PP-halloysite suture structures could be used as non-melting suture material, especially in surgeries that require high strength compared to pure polypropylene structures.

Keywords

Polypropylene, Halloysite, Polypropylene composites, Suture mechanic properties.

References

[1] Dennis C., Sethu S., Nayak S., Mohan L., Morsi Y., & Manivasagam G., Suture materials—Current and emerging trends, Journal of Biomedical Materials Research, Part A, 104 (6) (2016) 1544-1559.
[2] Abhari R. E., Martins J. A., Morris H., Mouthuy P. A., Carr A., Synthetic sutures: Clinical evaluation and future developments, Journal of Biomaterials Applications, 32 (3) (2017) 410-421.
[3] Chu C. C., Mechanical properties of suture materials: an important characterization, Annals of Surgery, 193 (3) (1981) 365.
[4] Zhukovskii V. A., Problems and prospects for development and production of surgical suture materials, Fibre Chemistry, 40 (3) (2008) 208-216.
[5] Srinivasulu K., Kumar N. D., A review on properties of surgical sutures and applications in medical field, Int. J. Res. Eng. Technol., 2 (2) (2014) 85-96.
[6] Najibi S., Banglmeier R., Matta J. M., Tannast M., Material properties of common suture materials in orthopaedic surgery, The Iowa Orthopaedic Journal, 30 (2010) 84-88.
[7] Naleway S. E., Lear W., Kruzic J. J., Maughan C. B., Mechanical properties of suture materials in general and cutaneous surgery, Journal of Biomedical Materials Research Part B: Applied Biomaterials, 103 (4) (2015) 735-742.
[8] Byrne M., Aly A., The surgical suture, Aesthetic Surgery Journal, 39 (2) (2019) 67-72.
[9] Bloom B. S., Goldberg D J., Suture material in cosmetic cutaneous surgery, Journal of Cosmetic and Laser Therapy, 9 (1) (2007) 41-45.
[10] Saxena S., Ray A. R., Kapil A., Pavon‐Djavid G., Letourneur D., Gupta B., Meddahi‐Pellé A., Development of a new polypropylene‐based suture: plasma grafting, surface treatment, characterization, and biocompatibility studies, Macromolecular Bioscience, 11(3) (2011) 373-382.
[11] Sun J., Yao L., Zhao Q. L., Huang J., Song R., Ma Z., Hao Y. M., Modification on crystallization of poly (vinylidene fluoride)(PVDF) by solvent extraction of poly (methyl methacrylate)(PMMA) in PVDF/PMMA blends, Frontiers of Materials Science, 5 (4) (2011) 388-400.
[12] Boland E. D., Coleman B. D., Barnes C. P., Simpson D. G., Wnek G. E., Bowlin G. L., Electrospinning polydioxanone for biomedical applications, Acta Biomaterialia, 1 (1) (2005) 115-123.
[13] Chen Y., Geever L. M., Killion J. A., Lyons J. G., Higginbotham C. L., Devine D. M., Review of multifarious applications of poly (lactic acid), Polymer-Plastics Technology and Engineering, 55 (10) (2016) 1057-1075.
[14] Singhvi M. S., Zinjarde S. S., Gokhale D. V., Polylactic acid: synthesis and biomedical applications, Journal of Applied Microbiology, 127 (6) (2019) 1612-1626.
[15] Budak K., Sogut O., Aydemir Sezer U., A review on synthesis and biomedical applications of polyglycolic acid, Journal of Polymer Research, 27 (8) (2020):1-19.
[16] Chu C. C., Materials for absorbable and nonabsorbable surgical sutures, In Biotextiles as Medical Implants, Woodhead Publishing Series in Textiles, (2013) 275-334.
[17] Linderman S. W., Kormpakis I., Gelberman R. H., Birman V., Wegst U. G., Genin G. M., Thomopoulos S., Shear lag sutures: Improved suture repair through the use of adhesives, Acta Biomaterialia, 23 (2015) 229-239.
[18] Wang B., Yang W., Sherman V. R., Meyers M. A., Pangolin armor: overlapping, structure, and mechanical properties of the keratinous scales, Acta Biomaterialia, 41 (2016) 60-74.
[19] Javed F., Al-Askar M., Almas K., Romanos G. E., Al-Hezaimi K., Tissue reactions to various suture materials used in oral surgical interventions, International Scholarly Research Notices, (2012) 762095
[20] Acosta S., Björck M., Wanhainen A., Negative-pressure wound therapy for prevention and treatment of surgical-site infections after vascular surgery, Journal of British Surgery, 104 (2) (2017) 75-84.
[21] Joussein E., Petit S., Churchman J., Theng B., Righi D., Delvaux B., Halloysite clay minerals—a review, Clay Minerals, 40 (4) (2005) 383-426.
[22] Yuan P., Tan D., Annabi-Bergaya F., Properties and applications of halloysite nanotubes: recent research advances and future prospects, Applied Clay Science, 112 (2015) 75-93.
[23] Danyliuk N., Tomaszewska J., Tatarchuk T., Halloysite nanotubes and halloysite-based composites for environmental and biomedical applications, Journal of Molecular Liquids, 309 (2020) 113077.

There are 23 citations in total.

Details

Primary Language	English
Subjects	Composite and Hybrid Materials
Journal Section	Natural Sciences
Authors	Fadime Nülüfer Kıvılcım 0000-0002-6017-5326
Publication Date	March 26, 2023
Submission Date	January 2, 2023
Acceptance Date	March 16, 2023
Published in Issue	Year 2023

Cite

APA	Kıvılcım, F. N. (2023). Development of Halloysite Loaded Polypropylene Sutures with Enhanced Mechanical and Thermal Properties. Cumhuriyet Science Journal, 44(1), 106-111. https://doi.org/10.17776/csj.1228170

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