Osteogenic Potential and Long-Term Enzymatic Biodegradation of PHB-based Scaffolds with Composite Magnetic Nanofillers in a Magnetic Field

Lada E. Shlapakova; Artyom S. Pryadko; Irina I. Zharkova; Alexey Volkov; Maria Kozadaeva; Roman V. Chernozem; Yulia R. Mukhortova; Dariana Chesnokova; Vsevolod A. Zhuikov; Angelina Zeltser; Andrey A. Dudun; Tatiana Makhina; Garina A. Bonartseva; Vera V. Voinova; Konstantin V. Shaitan; Konstantin Romanyuk; Andrei L. Kholkin; Anton P. Bonartsev; Maria A. Surmeneva; Roman A. Surmenev

doi:10.1021/acsami.4c06835

Osteogenic Potential and Long-Term Enzymatic Biodegradation of PHB-based Scaffolds with Composite Magnetic Nanofillers in a Magnetic Field

Lada E. Shlapakova
, Artyom S. Pryadko
, Irina I. Zharkova
, Alexey Volkov
, Maria Kozadaeva
, Roman V. Chernozem
, Yulia R. Mukhortova
, Dariana Chesnokova
, Vsevolod A. Zhuikov
, Angelina Zeltser
, Andrey A. Dudun
, Tatiana Makhina
, Garina A. Bonartseva
, Vera V. Voinova
, Konstantin V. Shaitan
, Konstantin Romanyuk
, Andrei L. Kholkin
, Anton P. Bonartsev
, Maria A. Surmeneva^*
, Roman A. Surmenev^*

^*Corresponding author for this work

Tomsk Polytechnic University
Lomonosov Moscow State University
People's Friendship University of Russia
Petrovsky National Research Centre of Surgery
Russian Academy of Sciences
University of Aveiro

Research output: Contribution to journal › Article › peer-review

10 Citations (Scopus)

Abstract

Millions of people worldwide suffer from musculoskeletal damage, thus using the largest proportion of rehabilitation services. The limited self-regenerative capacity of bone and cartilage tissues necessitates the development of functional biomaterials. Magnetoactive materials are a promising solution due to clinical safety and deep tissue penetration of magnetic fields (MFs) without attenuation and tissue heating. Herein, electrospun microfibrous scaffolds were developed based on piezoelectric poly(3-hydroxybutyrate) (PHB) and composite magnetic nanofillers [magnetite with graphene oxide (GO) or reduced GO]. The scaffolds’ morphology, structure, mechanical properties, surface potential, and piezoelectric response were systematically investigated. Furthermore, a complex mechanism of enzymatic biodegradation of these scaffolds is proposed that involves (i) a release of polymer crystallites, (ii) crystallization of the amorphous phase, and (iii) dissolution of the amorphous phase. Incorporation of Fe₃O₄, Fe₃O₄-GO, or Fe₃O₄-rGO accelerated the biodegradation of PHB scaffolds owing to pores on the surface of composite fibers and the enlarged content of polymer amorphous phase in the composite scaffolds. Six-month biodegradation caused a reduction in surface potential (1.5-fold) and in a vertical piezoresponse (3.5-fold) of the Fe₃O₄-GO scaffold because of a decrease in the PHB β-phase content. In vitro assays in the absence of an MF showed a significantly more pronounced mesenchymal stem cell proliferation on composite magnetic scaffolds compared to the neat scaffold, whereas in an MF (68 mT, 0.67 Hz), cell proliferation was not statistically significantly different when all the studied scaffolds were compared. The PHB/Fe₃O₄-GO scaffold was implanted into femur bone defects in rats, resulting in successful bone repair after nonperiodic magnetic stimulation (200 mT, 0.04 Hz) owing to a synergetic influence of increased surface roughness, the presence of hydrophilic groups near the surface, and magnetoelectric and magnetomechanical effects of the material.

Original language	English
Pages (from-to)	56555-56579
Number of pages	25
Journal	ACS Applied Materials and Interfaces
Volume	16
Issue number	42
DOIs	https://doi.org/10.1021/acsami.4c06835
Publication status	Published - 23 Oct 2024
Externally published	Yes

Keywords

bone regeneration
electrospun scaffold
enzymatic biodegradation
graphene oxide
magnetite
piezoelectricity

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10.1021/acsami.4c06835

Cite this

Shlapakova, L. E., Pryadko, A. S., Zharkova, I. I., Volkov, A., Kozadaeva, M., Chernozem, R. V., Mukhortova, Y. R., Chesnokova, D., Zhuikov, V. A., Zeltser, A., Dudun, A. A., Makhina, T., Bonartseva, G. A., Voinova, V. V., Shaitan, K. V., Romanyuk, K., Kholkin, A. L., Bonartsev, A. P., Surmeneva, M. A., & Surmenev, R. A. (2024). Osteogenic Potential and Long-Term Enzymatic Biodegradation of PHB-based Scaffolds with Composite Magnetic Nanofillers in a Magnetic Field. ACS Applied Materials and Interfaces, 16(42), 56555-56579. https://doi.org/10.1021/acsami.4c06835

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title = "Osteogenic Potential and Long-Term Enzymatic Biodegradation of PHB-based Scaffolds with Composite Magnetic Nanofillers in a Magnetic Field",

abstract = "Millions of people worldwide suffer from musculoskeletal damage, thus using the largest proportion of rehabilitation services. The limited self-regenerative capacity of bone and cartilage tissues necessitates the development of functional biomaterials. Magnetoactive materials are a promising solution due to clinical safety and deep tissue penetration of magnetic fields (MFs) without attenuation and tissue heating. Herein, electrospun microfibrous scaffolds were developed based on piezoelectric poly(3-hydroxybutyrate) (PHB) and composite magnetic nanofillers [magnetite with graphene oxide (GO) or reduced GO]. The scaffolds{\textquoteright} morphology, structure, mechanical properties, surface potential, and piezoelectric response were systematically investigated. Furthermore, a complex mechanism of enzymatic biodegradation of these scaffolds is proposed that involves (i) a release of polymer crystallites, (ii) crystallization of the amorphous phase, and (iii) dissolution of the amorphous phase. Incorporation of Fe3O4, Fe3O4-GO, or Fe3O4-rGO accelerated the biodegradation of PHB scaffolds owing to pores on the surface of composite fibers and the enlarged content of polymer amorphous phase in the composite scaffolds. Six-month biodegradation caused a reduction in surface potential (1.5-fold) and in a vertical piezoresponse (3.5-fold) of the Fe3O4-GO scaffold because of a decrease in the PHB β-phase content. In vitro assays in the absence of an MF showed a significantly more pronounced mesenchymal stem cell proliferation on composite magnetic scaffolds compared to the neat scaffold, whereas in an MF (68 mT, 0.67 Hz), cell proliferation was not statistically significantly different when all the studied scaffolds were compared. The PHB/Fe3O4-GO scaffold was implanted into femur bone defects in rats, resulting in successful bone repair after nonperiodic magnetic stimulation (200 mT, 0.04 Hz) owing to a synergetic influence of increased surface roughness, the presence of hydrophilic groups near the surface, and magnetoelectric and magnetomechanical effects of the material.",

keywords = "bone regeneration, electrospun scaffold, enzymatic biodegradation, graphene oxide, magnetite, piezoelectricity",

author = "Shlapakova, \{Lada E.\} and Pryadko, \{Artyom S.\} and Zharkova, \{Irina I.\} and Alexey Volkov and Maria Kozadaeva and Chernozem, \{Roman V.\} and Mukhortova, \{Yulia R.\} and Dariana Chesnokova and Zhuikov, \{Vsevolod A.\} and Angelina Zeltser and Dudun, \{Andrey A.\} and Tatiana Makhina and Bonartseva, \{Garina A.\} and Voinova, \{Vera V.\} and Shaitan, \{Konstantin V.\} and Konstantin Romanyuk and Kholkin, \{Andrei L.\} and Bonartsev, \{Anton P.\} and Surmeneva, \{Maria A.\} and Surmenev, \{Roman A.\}",

note = "Publisher Copyright: {\textcopyright} 2024 American Chemical Society.",

year = "2024",

month = oct,

day = "23",

doi = "10.1021/acsami.4c06835",

language = "English",

volume = "16",

pages = "56555--56579",

journal = "ACS Applied Materials and Interfaces",

issn = "1944-8244",

publisher = "American Chemical Society",

number = "42",

}

Shlapakova, LE, Pryadko, AS, Zharkova, II, Volkov, A, Kozadaeva, M, Chernozem, RV, Mukhortova, YR, Chesnokova, D, Zhuikov, VA, Zeltser, A, Dudun, AA, Makhina, T, Bonartseva, GA, Voinova, VV, Shaitan, KV, Romanyuk, K, Kholkin, AL, Bonartsev, AP, Surmeneva, MA & Surmenev, RA 2024, 'Osteogenic Potential and Long-Term Enzymatic Biodegradation of PHB-based Scaffolds with Composite Magnetic Nanofillers in a Magnetic Field', ACS Applied Materials and Interfaces, vol. 16, no. 42, pp. 56555-56579. https://doi.org/10.1021/acsami.4c06835

TY - JOUR

T1 - Osteogenic Potential and Long-Term Enzymatic Biodegradation of PHB-based Scaffolds with Composite Magnetic Nanofillers in a Magnetic Field

AU - Shlapakova, Lada E.

AU - Pryadko, Artyom S.

AU - Zharkova, Irina I.

AU - Volkov, Alexey

AU - Kozadaeva, Maria

AU - Chernozem, Roman V.

AU - Mukhortova, Yulia R.

AU - Chesnokova, Dariana

AU - Zhuikov, Vsevolod A.

AU - Zeltser, Angelina

AU - Dudun, Andrey A.

AU - Makhina, Tatiana

AU - Bonartseva, Garina A.

AU - Voinova, Vera V.

AU - Shaitan, Konstantin V.

AU - Romanyuk, Konstantin

AU - Kholkin, Andrei L.

AU - Bonartsev, Anton P.

AU - Surmeneva, Maria A.

AU - Surmenev, Roman A.

PY - 2024/10/23

Y1 - 2024/10/23

N2 - Millions of people worldwide suffer from musculoskeletal damage, thus using the largest proportion of rehabilitation services. The limited self-regenerative capacity of bone and cartilage tissues necessitates the development of functional biomaterials. Magnetoactive materials are a promising solution due to clinical safety and deep tissue penetration of magnetic fields (MFs) without attenuation and tissue heating. Herein, electrospun microfibrous scaffolds were developed based on piezoelectric poly(3-hydroxybutyrate) (PHB) and composite magnetic nanofillers [magnetite with graphene oxide (GO) or reduced GO]. The scaffolds’ morphology, structure, mechanical properties, surface potential, and piezoelectric response were systematically investigated. Furthermore, a complex mechanism of enzymatic biodegradation of these scaffolds is proposed that involves (i) a release of polymer crystallites, (ii) crystallization of the amorphous phase, and (iii) dissolution of the amorphous phase. Incorporation of Fe3O4, Fe3O4-GO, or Fe3O4-rGO accelerated the biodegradation of PHB scaffolds owing to pores on the surface of composite fibers and the enlarged content of polymer amorphous phase in the composite scaffolds. Six-month biodegradation caused a reduction in surface potential (1.5-fold) and in a vertical piezoresponse (3.5-fold) of the Fe3O4-GO scaffold because of a decrease in the PHB β-phase content. In vitro assays in the absence of an MF showed a significantly more pronounced mesenchymal stem cell proliferation on composite magnetic scaffolds compared to the neat scaffold, whereas in an MF (68 mT, 0.67 Hz), cell proliferation was not statistically significantly different when all the studied scaffolds were compared. The PHB/Fe3O4-GO scaffold was implanted into femur bone defects in rats, resulting in successful bone repair after nonperiodic magnetic stimulation (200 mT, 0.04 Hz) owing to a synergetic influence of increased surface roughness, the presence of hydrophilic groups near the surface, and magnetoelectric and magnetomechanical effects of the material.

AB - Millions of people worldwide suffer from musculoskeletal damage, thus using the largest proportion of rehabilitation services. The limited self-regenerative capacity of bone and cartilage tissues necessitates the development of functional biomaterials. Magnetoactive materials are a promising solution due to clinical safety and deep tissue penetration of magnetic fields (MFs) without attenuation and tissue heating. Herein, electrospun microfibrous scaffolds were developed based on piezoelectric poly(3-hydroxybutyrate) (PHB) and composite magnetic nanofillers [magnetite with graphene oxide (GO) or reduced GO]. The scaffolds’ morphology, structure, mechanical properties, surface potential, and piezoelectric response were systematically investigated. Furthermore, a complex mechanism of enzymatic biodegradation of these scaffolds is proposed that involves (i) a release of polymer crystallites, (ii) crystallization of the amorphous phase, and (iii) dissolution of the amorphous phase. Incorporation of Fe3O4, Fe3O4-GO, or Fe3O4-rGO accelerated the biodegradation of PHB scaffolds owing to pores on the surface of composite fibers and the enlarged content of polymer amorphous phase in the composite scaffolds. Six-month biodegradation caused a reduction in surface potential (1.5-fold) and in a vertical piezoresponse (3.5-fold) of the Fe3O4-GO scaffold because of a decrease in the PHB β-phase content. In vitro assays in the absence of an MF showed a significantly more pronounced mesenchymal stem cell proliferation on composite magnetic scaffolds compared to the neat scaffold, whereas in an MF (68 mT, 0.67 Hz), cell proliferation was not statistically significantly different when all the studied scaffolds were compared. The PHB/Fe3O4-GO scaffold was implanted into femur bone defects in rats, resulting in successful bone repair after nonperiodic magnetic stimulation (200 mT, 0.04 Hz) owing to a synergetic influence of increased surface roughness, the presence of hydrophilic groups near the surface, and magnetoelectric and magnetomechanical effects of the material.

KW - bone regeneration

KW - electrospun scaffold

KW - enzymatic biodegradation

KW - graphene oxide

KW - magnetite

KW - piezoelectricity

UR - https://www.scopus.com/pages/publications/85206456976

U2 - 10.1021/acsami.4c06835

DO - 10.1021/acsami.4c06835

M3 - Article

C2 - 39377758

AN - SCOPUS:85206456976

SN - 1944-8244

VL - 16

SP - 56555

EP - 56579

JO - ACS Applied Materials and Interfaces

JF - ACS Applied Materials and Interfaces

IS - 42

ER -

Osteogenic Potential and Long-Term Enzymatic Biodegradation of PHB-based Scaffolds with Composite Magnetic Nanofillers in a Magnetic Field

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Keywords

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