Effects of irradiation in the mandibular bone loaded with dental implants. An experimental study with a canine model

Sridhar Reddy Padala; Pekka Asikainen; Timo Ruotsalainen; Jopi J. W. Mikkonen; Tuomo S. Silvast; Arto P. Koistinen; Engelbert A. J. M. Schulten; Chris M. ten Bruggenkate; Arja M. Kullaa

doi:https://doi.org/10.1080/01913123.2021.1962467

Effects of irradiation in the mandibular bone loaded with dental implants. An experimental study with a canine model

Sridhar Reddy Padala, Pekka Asikainen, Timo Ruotsalainen, Jopi J. W. Mikkonen, Tuomo S. Silvast, Arto P. Koistinen, Engelbert A. J. M. Schulten, Chris M. ten Bruggenkate, Arja M. Kullaa

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

4 Citations (Scopus)

Abstract

Radiation therapy may compromise the quality of bone around dental implants, and its ability to regenerate, remodel, and revascularize. This study aimed to describe the irradiation effect on the bone microstructure of the mandible using dental implants in a canine model. Five beagle dogs were exposed to 40 Gy fractionated radiation. In total, 20 dental implants were inserted, two in the irradiated and two in the non-irradiated side. The mandible bone blocks were subjected to 3D micro-computed tomography (µCT) imaging, later evaluated histomorphometrically by light microscopy and scanning electron microscopy. Alterations in irradiated bone were observed under µCT imaging showing an increased anisotropy, porosity, and pore volume. Bone surface-to-bone volume decreased. The bone to implant contact index was significantly reduced in the irradiated bone (75.6% ± 5.8%) as compared to the non-irradiated bone (85.1% ± 6.8%). In the irradiated mandible, osteocytes with their filopodial processes, the bone beneath the periosteum, and subperiosteal veins showed structural differences but were not significant, whereas the diameter of Haversian canals were smaller statistical significant as compared to the control side. The study highlights that radiation dosage of fractioned 40 Gy causes alterations in the alveolar bone microstructure with compatible osseointegration and clinically stable dental implants.

Original language	English
Pages (from-to)	276-285
Number of pages	10
Journal	Ultrastructural pathology
Volume	45
Issue number	4-5
Early online date	2021
DOIs	https://doi.org/10.1080/01913123.2021.1962467
Publication status	Published - 2021

Keywords

Histomorphometric
bone microstructure
implants
micro-computed tomography
scanning electron microscopy

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Padala, S. R., Asikainen, P., Ruotsalainen, T., Mikkonen, J. J. W., Silvast, T. S., Koistinen, A. P., Schulten, E. A. J. M., ten Bruggenkate, C. M., & Kullaa, A. M. (2021). Effects of irradiation in the mandibular bone loaded with dental implants. An experimental study with a canine model. Ultrastructural pathology, 45(4-5), 276-285. https://doi.org/10.1080/01913123.2021.1962467

@article{61fb02f3c9f84d75aeca69a1212c5581,

title = "Effects of irradiation in the mandibular bone loaded with dental implants. An experimental study with a canine model",

abstract = "Radiation therapy may compromise the quality of bone around dental implants, and its ability to regenerate, remodel, and revascularize. This study aimed to describe the irradiation effect on the bone microstructure of the mandible using dental implants in a canine model. Five beagle dogs were exposed to 40 Gy fractionated radiation. In total, 20 dental implants were inserted, two in the irradiated and two in the non-irradiated side. The mandible bone blocks were subjected to 3D micro-computed tomography (µCT) imaging, later evaluated histomorphometrically by light microscopy and scanning electron microscopy. Alterations in irradiated bone were observed under µCT imaging showing an increased anisotropy, porosity, and pore volume. Bone surface-to-bone volume decreased. The bone to implant contact index was significantly reduced in the irradiated bone (75.6% ± 5.8%) as compared to the non-irradiated bone (85.1% ± 6.8%). In the irradiated mandible, osteocytes with their filopodial processes, the bone beneath the periosteum, and subperiosteal veins showed structural differences but were not significant, whereas the diameter of Haversian canals were smaller statistical significant as compared to the control side. The study highlights that radiation dosage of fractioned 40 Gy causes alterations in the alveolar bone microstructure with compatible osseointegration and clinically stable dental implants.",

keywords = "Histomorphometric, bone microstructure, implants, micro-computed tomography, scanning electron microscopy",

author = "Padala, {Sridhar Reddy} and Pekka Asikainen and Timo Ruotsalainen and Mikkonen, {Jopi J. W.} and Silvast, {Tuomo S.} and Koistinen, {Arto P.} and Schulten, {Engelbert A. J. M.} and {ten Bruggenkate}, {Chris M.} and Kullaa, {Arja M.}",

note = "Funding Information: The authors would like to thank Ritva Savolainen and Virpi Miettinen, SIB Labs, University of Eastern Finland, for their kind help in the preparation of the specimens. Publisher Copyright: {\textcopyright} 2021 The Author(s). Published with license by Taylor & Francis Group, LLC.",

year = "2021",

doi = "https://doi.org/10.1080/01913123.2021.1962467",

language = "English",

volume = "45",

pages = "276--285",

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T1 - Effects of irradiation in the mandibular bone loaded with dental implants. An experimental study with a canine model

AU - Padala, Sridhar Reddy

AU - Asikainen, Pekka

AU - Ruotsalainen, Timo

AU - Mikkonen, Jopi J. W.

AU - Silvast, Tuomo S.

AU - Koistinen, Arto P.

AU - Schulten, Engelbert A. J. M.

AU - ten Bruggenkate, Chris M.

AU - Kullaa, Arja M.

N1 - Funding Information: The authors would like to thank Ritva Savolainen and Virpi Miettinen, SIB Labs, University of Eastern Finland, for their kind help in the preparation of the specimens. Publisher Copyright: © 2021 The Author(s). Published with license by Taylor & Francis Group, LLC.

PY - 2021

Y1 - 2021

N2 - Radiation therapy may compromise the quality of bone around dental implants, and its ability to regenerate, remodel, and revascularize. This study aimed to describe the irradiation effect on the bone microstructure of the mandible using dental implants in a canine model. Five beagle dogs were exposed to 40 Gy fractionated radiation. In total, 20 dental implants were inserted, two in the irradiated and two in the non-irradiated side. The mandible bone blocks were subjected to 3D micro-computed tomography (µCT) imaging, later evaluated histomorphometrically by light microscopy and scanning electron microscopy. Alterations in irradiated bone were observed under µCT imaging showing an increased anisotropy, porosity, and pore volume. Bone surface-to-bone volume decreased. The bone to implant contact index was significantly reduced in the irradiated bone (75.6% ± 5.8%) as compared to the non-irradiated bone (85.1% ± 6.8%). In the irradiated mandible, osteocytes with their filopodial processes, the bone beneath the periosteum, and subperiosteal veins showed structural differences but were not significant, whereas the diameter of Haversian canals were smaller statistical significant as compared to the control side. The study highlights that radiation dosage of fractioned 40 Gy causes alterations in the alveolar bone microstructure with compatible osseointegration and clinically stable dental implants.

AB - Radiation therapy may compromise the quality of bone around dental implants, and its ability to regenerate, remodel, and revascularize. This study aimed to describe the irradiation effect on the bone microstructure of the mandible using dental implants in a canine model. Five beagle dogs were exposed to 40 Gy fractionated radiation. In total, 20 dental implants were inserted, two in the irradiated and two in the non-irradiated side. The mandible bone blocks were subjected to 3D micro-computed tomography (µCT) imaging, later evaluated histomorphometrically by light microscopy and scanning electron microscopy. Alterations in irradiated bone were observed under µCT imaging showing an increased anisotropy, porosity, and pore volume. Bone surface-to-bone volume decreased. The bone to implant contact index was significantly reduced in the irradiated bone (75.6% ± 5.8%) as compared to the non-irradiated bone (85.1% ± 6.8%). In the irradiated mandible, osteocytes with their filopodial processes, the bone beneath the periosteum, and subperiosteal veins showed structural differences but were not significant, whereas the diameter of Haversian canals were smaller statistical significant as compared to the control side. The study highlights that radiation dosage of fractioned 40 Gy causes alterations in the alveolar bone microstructure with compatible osseointegration and clinically stable dental implants.

KW - Histomorphometric

KW - bone microstructure

KW - implants

KW - micro-computed tomography

KW - scanning electron microscopy

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UR - https://www.ncbi.nlm.nih.gov/pubmed/34423726

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C2 - 34423726

SN - 0191-3123

VL - 45

SP - 276

EP - 285

JO - Ultrastructural pathology

JF - Ultrastructural pathology

IS - 4-5

ER -

Effects of irradiation in the mandibular bone loaded with dental implants. An experimental study with a canine model

Abstract

Keywords

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