Intravenous SPION-labeled adipocyte-derived stem cells targeted to the brain by magnetic attraction in a rat stroke model: An ultrastructural insight into cell fate within the brain

Mesenchymal stem cell therapy after stroke is a promising option investigated in animal models and clinical trials. The intravenous route is commonly used in clinical settings guaranteeing an adequate safety profile although low yields of engraftment. In this report, rats subjected to ischemic strok...

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Published inNanomedicine Vol. 39; p. 102464
Main Authors García-Belda, Paula, Prima-García, Helena, Aliena-Valero, Alicia, Castelló-Ruiz, María, Ulloa-Navas, María José, Ten-Esteve, Amadeo, Martí-Bonmatí, Luis, Salom, Juan B., García-Verdugo, José Manuel, Gil-Perotín, Sara
Format Journal Article
LanguageEnglish
Published United States Elsevier Inc 01.01.2022
Subjects
Adipocytes
Animals
Brain
Correlative microscopy
Electron microscopy
Magnetic Fields
Magnetic Resonance Imaging - methods
Magnetite Nanoparticles - chemistry
Rats
SPION
Stem cell therapy
Stem Cells
Stroke
Stroke - therapy
BBB
PLA
Correlative microscopy
CNS
EtOH
DLS
Stem cell therapy
GFP
PLL
FBS
SPION
MSC
tMCAo
PBS
CD
Stroke
MR
SQUID
SSG
Electron microscopy
ADSC
CP
ROS
Magnetic fields
TEM
Online AccessGet full text
ISSN1549-9634
1549-9642
1549-9642
DOI10.1016/j.nano.2021.102464

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Abstract Mesenchymal stem cell therapy after stroke is a promising option investigated in animal models and clinical trials. The intravenous route is commonly used in clinical settings guaranteeing an adequate safety profile although low yields of engraftment. In this report, rats subjected to ischemic stroke were injected with adipose-derived stem cells (ADSCs) labeled with superparamagnetic iron oxide nanoparticles (SPIONs) applying an external magnetic field in the skull to retain the cells. Although most published studies demonstrate viability of ADSCs, only a few have used ultrastructural techniques. In our study, the application of a local magnetic force resulted in a tendency for higher yields of SPION-ADSCs targeting the brain. However, grafted cells displayed morphological signs of death, one day after administration, and correlative microscopy showed active microglia and astrocytes associated in the process of scavenging. Thus, we conclude that, although successfully targeted within the brain, SPION-ADSCs viability was rapidly compromised. Rats subjected to ischemic stroke by transient middle cerebral occlusion (tMCAo) were injected with adipose-derived stem cells (ADSCs) labeled with superparamagnetic iron oxide nanoparticles (SPIONs) applying an external magnetic field in the skull to retain the cells. The application of a local magnetic force resulted in a tendency for higher yields of SPION-ADSCs targeting the brain. However, grafted cells displayed morphological signs of death, one day after administration, and correlative microscopy showed active microglia and astrocytes associated in the process of scavenging. [Display omitted] •SPION-labeled ADSCs preserve viability, morphology and mesenchymal stem cell features.•SPION-ADSCs behave as superparamagnetic cells.•Local magnetic force retains intravenous SPION-ADSCs in the stroke damaged brain.•Grafted SPION-ADSCs are subject of precocious cell death and phagocytosis by glia.
AbstractList Mesenchymal stem cell therapy after stroke is a promising option investigated in animal models and clinical trials. The intravenous route is commonly used in clinical settings guaranteeing an adequate safety profile although low yields of engraftment. In this report, rats subjected to ischemic stroke were injected with adipose-derived stem cells (ADSCs) labeled with superparamagnetic iron oxide nanoparticles (SPIONs) applying an external magnetic field in the skull to retain the cells. Although most published studies demonstrate viability of ADSCs, only a few have used ultrastructural techniques. In our study, the application of a local magnetic force resulted in a tendency for higher yields of SPION-ADSCs targeting the brain. However, grafted cells displayed morphological signs of death, one day after administration, and correlative microscopy showed active microglia and astrocytes associated in the process of scavenging. Thus, we conclude that, although successfully targeted within the brain, SPION-ADSCs viability was rapidly compromised. Rats subjected to ischemic stroke by transient middle cerebral occlusion (tMCAo) were injected with adipose-derived stem cells (ADSCs) labeled with superparamagnetic iron oxide nanoparticles (SPIONs) applying an external magnetic field in the skull to retain the cells. The application of a local magnetic force resulted in a tendency for higher yields of SPION-ADSCs targeting the brain. However, grafted cells displayed morphological signs of death, one day after administration, and correlative microscopy showed active microglia and astrocytes associated in the process of scavenging. [Display omitted] •SPION-labeled ADSCs preserve viability, morphology and mesenchymal stem cell features.•SPION-ADSCs behave as superparamagnetic cells.•Local magnetic force retains intravenous SPION-ADSCs in the stroke damaged brain.•Grafted SPION-ADSCs are subject of precocious cell death and phagocytosis by glia.
Mesenchymal stem cell therapy after stroke is a promising option investigated in animal models and clinical trials. The intravenous route is commonly used in clinical settings guaranteeing an adequate safety profile although low yields of engraftment. In this report, rats subjected to ischemic stroke were injected with adipose-derived stem cells (ADSCs) labeled with superparamagnetic iron oxide nanoparticles (SPIONs) applying an external magnetic field in the skull to retain the cells. Although most published studies demonstrate viability of ADSCs, only a few have used ultrastructural techniques. In our study, the application of a local magnetic force resulted in a tendency for higher yields of SPION-ADSCs targeting the brain. However, grafted cells displayed morphological signs of death, one day after administration, and correlative microscopy showed active microglia and astrocytes associated in the process of scavenging. Thus, we conclude that, although successfully targeted within the brain, SPION-ADSCs viability was rapidly compromised.Mesenchymal stem cell therapy after stroke is a promising option investigated in animal models and clinical trials. The intravenous route is commonly used in clinical settings guaranteeing an adequate safety profile although low yields of engraftment. In this report, rats subjected to ischemic stroke were injected with adipose-derived stem cells (ADSCs) labeled with superparamagnetic iron oxide nanoparticles (SPIONs) applying an external magnetic field in the skull to retain the cells. Although most published studies demonstrate viability of ADSCs, only a few have used ultrastructural techniques. In our study, the application of a local magnetic force resulted in a tendency for higher yields of SPION-ADSCs targeting the brain. However, grafted cells displayed morphological signs of death, one day after administration, and correlative microscopy showed active microglia and astrocytes associated in the process of scavenging. Thus, we conclude that, although successfully targeted within the brain, SPION-ADSCs viability was rapidly compromised.
Mesenchymal stem cell therapy after stroke is a promising option investigated in animal models and clinical trials. The intravenous route is commonly used in clinical settings guaranteeing an adequate safety profile although low yields of engraftment. In this report, rats subjected to ischemic stroke were injected with adipose-derived stem cells (ADSCs) labeled with superparamagnetic iron oxide nanoparticles (SPIONs) applying an external magnetic field in the skull to retain the cells. Although most published studies demonstrate viability of ADSCs, only a few have used ultrastructural techniques. In our study, the application of a local magnetic force resulted in a tendency for higher yields of SPION-ADSCs targeting the brain. However, grafted cells displayed morphological signs of death, one day after administration, and correlative microscopy showed active microglia and astrocytes associated in the process of scavenging. Thus, we conclude that, although successfully targeted within the brain, SPION-ADSCs viability was rapidly compromised.
ArticleNumber 102464
Author Salom, Juan B.
Prima-García, Helena
Castelló-Ruiz, María
García-Belda, Paula
García-Verdugo, José Manuel
Ten-Esteve, Amadeo
Gil-Perotín, Sara
Aliena-Valero, Alicia
Martí-Bonmatí, Luis
Ulloa-Navas, María José
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  givenname: Paula
  surname: García-Belda
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  givenname: Helena
  surname: Prima-García
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  surname: Aliena-Valero
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  email: sara.garcia@uv.es
  organization: Laboratory of Central Neuroimmunology, IIS Hospital La Fe, Valencia, Spain
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Keywords BBB
PLA
Correlative microscopy
CNS
EtOH
DLS
Stem cell therapy
GFP
PLL
FBS
SPION
MSC
tMCAo
PBS
CD
Stroke
MR
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TEM
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Snippet Mesenchymal stem cell therapy after stroke is a promising option investigated in animal models and clinical trials. The intravenous route is commonly used in...
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SubjectTerms Adipocytes
Animals
Brain
Correlative microscopy
Electron microscopy
Magnetic Fields
Magnetic Resonance Imaging - methods
Magnetite Nanoparticles - chemistry
Rats
SPION
Stem cell therapy
Stem Cells
Stroke
Stroke - therapy
Title Intravenous SPION-labeled adipocyte-derived stem cells targeted to the brain by magnetic attraction in a rat stroke model: An ultrastructural insight into cell fate within the brain
URI https://www.clinicalkey.com/#!/content/1-s2.0-S1549963421001076
https://dx.doi.org/10.1016/j.nano.2021.102464
https://www.ncbi.nlm.nih.gov/pubmed/34583057
https://www.proquest.com/docview/2577733639
Volume 39
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