Targeted In Situ Biosynthetic Transcriptional Activation in Native Surface-Level Human Articular Chondrocytes during Lesion Stabilization

OBJECTIVE: Safe articular cartilage lesion stabilization is an important early surgical intervention advance toward mitigating articular cartilage disease burden. While short-term chondrocyte viability and chondrosupportive matrix modification have been demonstrated within tissue contiguous to targe...

Descripción completa

Detalles Bibliográficos
Autores principales: Ganguly, Kumkum, McRury, Ian D., Goodwin, Peter M., Morgan, Roy E., Augé, Wayne K.
Formato: Online Artículo Texto
Lenguaje:English
Publicado: SAGE Publications 2012
Materias:
Original Articles
Acceso en línea:https://www.ncbi.nlm.nih.gov/pmc/articles/PMC4297128/
https://www.ncbi.nlm.nih.gov/pubmed/26069627
http://dx.doi.org/10.1177/1947603511426881
_version_ 1782353108668514304
author Ganguly, Kumkum
McRury, Ian D.
Goodwin, Peter M.
Morgan, Roy E.
Augé, Wayne K.
author_facet Ganguly, Kumkum
McRury, Ian D.
Goodwin, Peter M.
Morgan, Roy E.
Augé, Wayne K.
author_sort Ganguly, Kumkum
collection PubMed
description OBJECTIVE: Safe articular cartilage lesion stabilization is an important early surgical intervention advance toward mitigating articular cartilage disease burden. While short-term chondrocyte viability and chondrosupportive matrix modification have been demonstrated within tissue contiguous to targeted removal of damaged articular cartilage, longer term tissue responses require evaluation to further clarify treatment efficacy. The purpose of this study was to examine surface chondrocyte responses within contiguous tissue after lesion stabilization. METHODS: Nonablation radiofrequency lesion stabilization of human cartilage explants obtained during knee replacement was performed for surface fibrillation. Time-dependent chondrocyte viability, nuclear morphology and cell distribution, and temporal response kinetics of matrix and chaperone gene transcription indicative of differentiated chondrocyte function were evaluated in samples at intervals to 96 hours after treatment. RESULTS: Subadjacent surface articular cartilage chondrocytes demonstrated continued viability for 96 hours after treatment, a lack of increased nuclear fragmentation or condensation, persistent nucleic acid production during incubation reflecting cellular assembly behavior, and transcriptional up-regulation of matrix and chaperone genes indicative of retained biosynthetic differentiated cell function. CONCLUSIONS: The results of this study provide further evidence of treatment efficacy and suggest the possibility to manipulate or induce cellular function, thereby recruiting local chondrocytes to aid lesion recovery. Early surgical intervention may be viewed as a tissue rescue, allowing articular cartilage to continue displaying biological responses appropriate to its function rather than converting to a tissue ultimately governed by the degenerative material property responses of matrix failure. Early intervention may positively impact the late changes and reduce disease burden of damaged articular cartilage.
format Online
Article
Text
id pubmed-4297128
institution National Center for Biotechnology Information
language English
publishDate 2012
publisher SAGE Publications
record_format MEDLINE/PubMed
spelling pubmed-42971282015-06-11 Targeted In Situ Biosynthetic Transcriptional Activation in Native Surface-Level Human Articular Chondrocytes during Lesion Stabilization Ganguly, Kumkum McRury, Ian D. Goodwin, Peter M. Morgan, Roy E. Augé, Wayne K. Cartilage Original Articles OBJECTIVE: Safe articular cartilage lesion stabilization is an important early surgical intervention advance toward mitigating articular cartilage disease burden. While short-term chondrocyte viability and chondrosupportive matrix modification have been demonstrated within tissue contiguous to targeted removal of damaged articular cartilage, longer term tissue responses require evaluation to further clarify treatment efficacy. The purpose of this study was to examine surface chondrocyte responses within contiguous tissue after lesion stabilization. METHODS: Nonablation radiofrequency lesion stabilization of human cartilage explants obtained during knee replacement was performed for surface fibrillation. Time-dependent chondrocyte viability, nuclear morphology and cell distribution, and temporal response kinetics of matrix and chaperone gene transcription indicative of differentiated chondrocyte function were evaluated in samples at intervals to 96 hours after treatment. RESULTS: Subadjacent surface articular cartilage chondrocytes demonstrated continued viability for 96 hours after treatment, a lack of increased nuclear fragmentation or condensation, persistent nucleic acid production during incubation reflecting cellular assembly behavior, and transcriptional up-regulation of matrix and chaperone genes indicative of retained biosynthetic differentiated cell function. CONCLUSIONS: The results of this study provide further evidence of treatment efficacy and suggest the possibility to manipulate or induce cellular function, thereby recruiting local chondrocytes to aid lesion recovery. Early surgical intervention may be viewed as a tissue rescue, allowing articular cartilage to continue displaying biological responses appropriate to its function rather than converting to a tissue ultimately governed by the degenerative material property responses of matrix failure. Early intervention may positively impact the late changes and reduce disease burden of damaged articular cartilage. SAGE Publications 2012-04 /pmc/articles/PMC4297128/ /pubmed/26069627 http://dx.doi.org/10.1177/1947603511426881 Text en © The Author(s) 2012
spellingShingle Original Articles
Ganguly, Kumkum
McRury, Ian D.
Goodwin, Peter M.
Morgan, Roy E.
Augé, Wayne K.
Targeted In Situ Biosynthetic Transcriptional Activation in Native Surface-Level Human Articular Chondrocytes during Lesion Stabilization
title Targeted In Situ Biosynthetic Transcriptional Activation in Native Surface-Level Human Articular Chondrocytes during Lesion Stabilization
title_full Targeted In Situ Biosynthetic Transcriptional Activation in Native Surface-Level Human Articular Chondrocytes during Lesion Stabilization
title_fullStr Targeted In Situ Biosynthetic Transcriptional Activation in Native Surface-Level Human Articular Chondrocytes during Lesion Stabilization
title_full_unstemmed Targeted In Situ Biosynthetic Transcriptional Activation in Native Surface-Level Human Articular Chondrocytes during Lesion Stabilization
title_short Targeted In Situ Biosynthetic Transcriptional Activation in Native Surface-Level Human Articular Chondrocytes during Lesion Stabilization
title_sort targeted in situ biosynthetic transcriptional activation in native surface-level human articular chondrocytes during lesion stabilization
topic Original Articles
url https://www.ncbi.nlm.nih.gov/pmc/articles/PMC4297128/
https://www.ncbi.nlm.nih.gov/pubmed/26069627
http://dx.doi.org/10.1177/1947603511426881
work_keys_str_mv AT gangulykumkum targetedinsitubiosynthetictranscriptionalactivationinnativesurfacelevelhumanarticularchondrocytesduringlesionstabilization
AT mcruryiand targetedinsitubiosynthetictranscriptionalactivationinnativesurfacelevelhumanarticularchondrocytesduringlesionstabilization
AT goodwinpeterm targetedinsitubiosynthetictranscriptionalactivationinnativesurfacelevelhumanarticularchondrocytesduringlesionstabilization
AT morganroye targetedinsitubiosynthetictranscriptionalactivationinnativesurfacelevelhumanarticularchondrocytesduringlesionstabilization
AT augewaynek targetedinsitubiosynthetictranscriptionalactivationinnativesurfacelevelhumanarticularchondrocytesduringlesionstabilization

Ejemplares similares