Local and Systemic In Vivo Responses to Osseointegrative Titanium Nanotube Surfaces

Local and Systemic In Vivo Responses to Osseointegrative Titanium Nanotube Surfaces

Orthopedic implants requiring osseointegration are often surface modified; however, implants may shed these coatings and generate wear debris leading to complications. Titanium nanotubes (TiNT), a new surface treatment, may promote osseointegration. In this study, in vitro (rat marrow-derived bone m...

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Main Authors: Erin A. Baker, Mackenzie M. Fleischer, Alexander D. Vara, Meagan R. Salisbury, Kevin C. Baker, Paul T. Fortin, Craig R. Friedrich
Format: Article
Language:English
Published: MDPI AG 2021-02-01
Series:Nanomaterials
Subjects:
orthopedic
nanomedicine
nanomodified surfaces
animal model
immune response
Online Access:https://www.mdpi.com/2079-4991/11/3/583
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spelling doaj-28520d7484ea4731967ffc84b1907d032021-02-27T00:03:28ZengMDPI AGNanomaterials2079-49912021-02-011158358310.3390/nano11030583Local and Systemic In Vivo Responses to Osseointegrative Titanium Nanotube SurfacesErin A. Baker0Mackenzie M. Fleischer1Alexander D. Vara2Meagan R. Salisbury3Kevin C. Baker4Paul T. Fortin5Craig R. Friedrich6Departments of Orthopaedic Research and Surgery, Beaumont Health, Royal Oak, MI 48073, USADepartments of Orthopaedic Research and Surgery, Beaumont Health, Royal Oak, MI 48073, USADepartments of Orthopaedic Research and Surgery, Beaumont Health, Royal Oak, MI 48073, USADepartments of Orthopaedic Research and Surgery, Beaumont Health, Royal Oak, MI 48073, USADepartments of Orthopaedic Research and Surgery, Beaumont Health, Royal Oak, MI 48073, USADepartments of Orthopaedic Research and Surgery, Beaumont Health, Royal Oak, MI 48073, USADepartment of Mechanical Engineering-Engineering Mechanics, Michigan Technological University, Houghton, MI 49931, USAOrthopedic implants requiring osseointegration are often surface modified; however, implants may shed these coatings and generate wear debris leading to complications. Titanium nanotubes (TiNT), a new surface treatment, may promote osseointegration. In this study, in vitro (rat marrow-derived bone marrow cell attachment and morphology) and in vivo (rat model of intramedullary fixation) experiments characterized local and systemic responses of two TiNT surface morphologies, aligned and trabecular, via animal and remote organ weight, metal ion, hematologic, and nondecalcified histologic analyses. In vitro experiments showed total adherent cells on trabecular and aligned TiNT surfaces were greater than control at 30 min and 4 h, and cells were smaller in diameter and more eccentric. Control animals gained more weight, on average; however, no animals met the institutional trigger for weight loss. No hematologic parameters (complete blood count with differential) were significantly different for TiNT groups vs. control. Inductively coupled plasma mass spectrometry (ICP-MS) showed greater aluminum levels in the lungs of the trabecular TiNT group than in those of the controls. Histologic analysis demonstrated no inflammatory infiltrate, cytotoxic, or necrotic conditions in proximity of K-wires. There were significantly fewer eosinophils/basophils and neutrophils in the distal region of trabecular TiNT-implanted femora; and, in the midshaft of aligned TiNT-implanted femora, there were significantly fewer foreign body giant/multinucleated cells and neutrophils, indicating a decreased immune response in aligned TiNT-implanted femora compared to controls.https://www.mdpi.com/2079-4991/11/3/583orthopedicnanomedicinenanomodified surfacesanimal modelimmune response
collection DOAJ
language English
format Article
sources DOAJ
author Erin A. Baker
Mackenzie M. Fleischer
Alexander D. Vara
Meagan R. Salisbury
Kevin C. Baker
Paul T. Fortin
Craig R. Friedrich
spellingShingle Erin A. Baker
Mackenzie M. Fleischer
Alexander D. Vara
Meagan R. Salisbury
Kevin C. Baker
Paul T. Fortin
Craig R. Friedrich
Local and Systemic In Vivo Responses to Osseointegrative Titanium Nanotube Surfaces
Nanomaterials
orthopedic
nanomedicine
nanomodified surfaces
animal model
immune response
author_facet Erin A. Baker
Mackenzie M. Fleischer
Alexander D. Vara
Meagan R. Salisbury
Kevin C. Baker
Paul T. Fortin
Craig R. Friedrich
author_sort Erin A. Baker
title Local and Systemic In Vivo Responses to Osseointegrative Titanium Nanotube Surfaces
title_short Local and Systemic In Vivo Responses to Osseointegrative Titanium Nanotube Surfaces
title_full Local and Systemic In Vivo Responses to Osseointegrative Titanium Nanotube Surfaces
title_fullStr Local and Systemic In Vivo Responses to Osseointegrative Titanium Nanotube Surfaces
title_full_unstemmed Local and Systemic In Vivo Responses to Osseointegrative Titanium Nanotube Surfaces
title_sort local and systemic in vivo responses to osseointegrative titanium nanotube surfaces
publisher MDPI AG
series Nanomaterials
issn 2079-4991
publishDate 2021-02-01
description Orthopedic implants requiring osseointegration are often surface modified; however, implants may shed these coatings and generate wear debris leading to complications. Titanium nanotubes (TiNT), a new surface treatment, may promote osseointegration. In this study, in vitro (rat marrow-derived bone marrow cell attachment and morphology) and in vivo (rat model of intramedullary fixation) experiments characterized local and systemic responses of two TiNT surface morphologies, aligned and trabecular, via animal and remote organ weight, metal ion, hematologic, and nondecalcified histologic analyses. In vitro experiments showed total adherent cells on trabecular and aligned TiNT surfaces were greater than control at 30 min and 4 h, and cells were smaller in diameter and more eccentric. Control animals gained more weight, on average; however, no animals met the institutional trigger for weight loss. No hematologic parameters (complete blood count with differential) were significantly different for TiNT groups vs. control. Inductively coupled plasma mass spectrometry (ICP-MS) showed greater aluminum levels in the lungs of the trabecular TiNT group than in those of the controls. Histologic analysis demonstrated no inflammatory infiltrate, cytotoxic, or necrotic conditions in proximity of K-wires. There were significantly fewer eosinophils/basophils and neutrophils in the distal region of trabecular TiNT-implanted femora; and, in the midshaft of aligned TiNT-implanted femora, there were significantly fewer foreign body giant/multinucleated cells and neutrophils, indicating a decreased immune response in aligned TiNT-implanted femora compared to controls.
topic orthopedic
nanomedicine
nanomodified surfaces
animal model
immune response
url https://www.mdpi.com/2079-4991/11/3/583
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