Remnant tissue enhances early postoperative biomechanical strength and infiltration of Scleraxis-positive cells within the grafted tendon in a rat anterior cruciate ligament reconstruction model

When ruptured, ligaments and tendons have limited self-repair capacity and rarely heal spontaneously. In the knee, the Anterior Cruciate Ligament (ACL) often ruptures during sports activities, causing functional impairment and requiring surgery using tendon grafts. Patients with insufficient time to...

Descripción completa

Detalles Bibliográficos
Autores principales: Kawakami, Junki, Hisanaga, Satoshi, Yoshimoto, Yuki, Mashimo, Tomoji, Kaneko, Takehito, Yoshimura, Naoto, Shimada, Masaki, Tateyama, Makoto, Matsunaga, Hideto, Shibata, Yuto, Tanimura, Shuntaro, Takata, Kosei, Arima, Takahiro, Maeda, Kazuya, Fukuma, Yuko, Uragami, Masaru, Ideo, Katsumasa, Sugimoto, Kazuki, Yonemitsu, Ryuji, Matsushita, Kozo, Yugami, Masaki, Uehara, Yusuke, Nakamura, Takayuki, Tokunaga, Takuya, Karasugi, Tatsuki, Sueyoshi, Takanao, Shukunami, Chisa, Okamoto, Nobukazu, Masuda, Tetsuro, Miyamoto, Takeshi
Formato: Online Artículo Texto
Lenguaje:English
Publicado: Public Library of Science 2023
Materias:
Research Article
Acceso en línea:https://www.ncbi.nlm.nih.gov/pmc/articles/PMC10631660/
https://www.ncbi.nlm.nih.gov/pubmed/37939095
http://dx.doi.org/10.1371/journal.pone.0293944
_version_ 1785132408352276480
author Kawakami, Junki
Hisanaga, Satoshi
Yoshimoto, Yuki
Mashimo, Tomoji
Kaneko, Takehito
Yoshimura, Naoto
Shimada, Masaki
Tateyama, Makoto
Matsunaga, Hideto
Shibata, Yuto
Tanimura, Shuntaro
Takata, Kosei
Arima, Takahiro
Maeda, Kazuya
Fukuma, Yuko
Uragami, Masaru
Ideo, Katsumasa
Sugimoto, Kazuki
Yonemitsu, Ryuji
Matsushita, Kozo
Yugami, Masaki
Uehara, Yusuke
Nakamura, Takayuki
Tokunaga, Takuya
Karasugi, Tatsuki
Sueyoshi, Takanao
Shukunami, Chisa
Okamoto, Nobukazu
Masuda, Tetsuro
Miyamoto, Takeshi
author_facet Kawakami, Junki
Hisanaga, Satoshi
Yoshimoto, Yuki
Mashimo, Tomoji
Kaneko, Takehito
Yoshimura, Naoto
Shimada, Masaki
Tateyama, Makoto
Matsunaga, Hideto
Shibata, Yuto
Tanimura, Shuntaro
Takata, Kosei
Arima, Takahiro
Maeda, Kazuya
Fukuma, Yuko
Uragami, Masaru
Ideo, Katsumasa
Sugimoto, Kazuki
Yonemitsu, Ryuji
Matsushita, Kozo
Yugami, Masaki
Uehara, Yusuke
Nakamura, Takayuki
Tokunaga, Takuya
Karasugi, Tatsuki
Sueyoshi, Takanao
Shukunami, Chisa
Okamoto, Nobukazu
Masuda, Tetsuro
Miyamoto, Takeshi
author_sort Kawakami, Junki
collection PubMed
description When ruptured, ligaments and tendons have limited self-repair capacity and rarely heal spontaneously. In the knee, the Anterior Cruciate Ligament (ACL) often ruptures during sports activities, causing functional impairment and requiring surgery using tendon grafts. Patients with insufficient time to recover before resuming sports risk re-injury. To develop more effective treatment, it is necessary to define mechanisms underlying ligament repair. For this, animal models can be useful, but mice are too small to create an ACL reconstruction model. Thus, we developed a transgenic rat model using control elements of Scleraxis (Scx), a transcription factor essential for ligament and tendon development, to drive GFP expression in order to localize Scx-expressing cells. As anticipated, Tg rats exhibited Scx-GFP in ACL during developmental but not adult stages. Interestingly, when we transplanted the flexor digitorum longus (FDP) tendon derived from adult Scx-GFP+ rats into WT adults, Scx-GFP was not expressed in transplanted tendons. However, tendons transplanted from adult WT rats into Scx-GFP rats showed upregulated Scx expression in tendon, suggesting that Scx-GFP+ cells are mobilized from tissues outside the tendon. Importantly, at 4 weeks post-surgery, Scx-GFP-expressing cells were more frequent within the grafted tendon when an ACL remnant was preserved (P group) relative to when it was not (R group) (P vs R groups (both n = 5), p<0.05), and by 6 weeks, biomechanical strength of the transplanted tendon was significantly increased if the remnant was preserved (P vsR groups (both n = 14), p<0.05). Scx-GFP+ cells increased in remnant tissue after surgery, suggesting remnant tissue is a source of Scx+ cells in grafted tendons. We conclude that the novel Scx-GFP Tg rat is useful to monitor emergence of Scx-positive cells, which likely contribute to increased graft strength after ACL reconstruction.
format Online
Article
Text
id pubmed-10631660
institution National Center for Biotechnology Information
language English
publishDate 2023
publisher Public Library of Science
record_format MEDLINE/PubMed
spelling pubmed-106316602023-11-08 Remnant tissue enhances early postoperative biomechanical strength and infiltration of Scleraxis-positive cells within the grafted tendon in a rat anterior cruciate ligament reconstruction model Kawakami, Junki Hisanaga, Satoshi Yoshimoto, Yuki Mashimo, Tomoji Kaneko, Takehito Yoshimura, Naoto Shimada, Masaki Tateyama, Makoto Matsunaga, Hideto Shibata, Yuto Tanimura, Shuntaro Takata, Kosei Arima, Takahiro Maeda, Kazuya Fukuma, Yuko Uragami, Masaru Ideo, Katsumasa Sugimoto, Kazuki Yonemitsu, Ryuji Matsushita, Kozo Yugami, Masaki Uehara, Yusuke Nakamura, Takayuki Tokunaga, Takuya Karasugi, Tatsuki Sueyoshi, Takanao Shukunami, Chisa Okamoto, Nobukazu Masuda, Tetsuro Miyamoto, Takeshi PLoS One Research Article When ruptured, ligaments and tendons have limited self-repair capacity and rarely heal spontaneously. In the knee, the Anterior Cruciate Ligament (ACL) often ruptures during sports activities, causing functional impairment and requiring surgery using tendon grafts. Patients with insufficient time to recover before resuming sports risk re-injury. To develop more effective treatment, it is necessary to define mechanisms underlying ligament repair. For this, animal models can be useful, but mice are too small to create an ACL reconstruction model. Thus, we developed a transgenic rat model using control elements of Scleraxis (Scx), a transcription factor essential for ligament and tendon development, to drive GFP expression in order to localize Scx-expressing cells. As anticipated, Tg rats exhibited Scx-GFP in ACL during developmental but not adult stages. Interestingly, when we transplanted the flexor digitorum longus (FDP) tendon derived from adult Scx-GFP+ rats into WT adults, Scx-GFP was not expressed in transplanted tendons. However, tendons transplanted from adult WT rats into Scx-GFP rats showed upregulated Scx expression in tendon, suggesting that Scx-GFP+ cells are mobilized from tissues outside the tendon. Importantly, at 4 weeks post-surgery, Scx-GFP-expressing cells were more frequent within the grafted tendon when an ACL remnant was preserved (P group) relative to when it was not (R group) (P vs R groups (both n = 5), p<0.05), and by 6 weeks, biomechanical strength of the transplanted tendon was significantly increased if the remnant was preserved (P vsR groups (both n = 14), p<0.05). Scx-GFP+ cells increased in remnant tissue after surgery, suggesting remnant tissue is a source of Scx+ cells in grafted tendons. We conclude that the novel Scx-GFP Tg rat is useful to monitor emergence of Scx-positive cells, which likely contribute to increased graft strength after ACL reconstruction. Public Library of Science 2023-11-08 /pmc/articles/PMC10631660/ /pubmed/37939095 http://dx.doi.org/10.1371/journal.pone.0293944 Text en © 2023 Kawakami et al https://creativecommons.org/licenses/by/4.0/This is an open access article distributed under the terms of the Creative Commons Attribution License (https://creativecommons.org/licenses/by/4.0/) , which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.
spellingShingle Research Article
Kawakami, Junki
Hisanaga, Satoshi
Yoshimoto, Yuki
Mashimo, Tomoji
Kaneko, Takehito
Yoshimura, Naoto
Shimada, Masaki
Tateyama, Makoto
Matsunaga, Hideto
Shibata, Yuto
Tanimura, Shuntaro
Takata, Kosei
Arima, Takahiro
Maeda, Kazuya
Fukuma, Yuko
Uragami, Masaru
Ideo, Katsumasa
Sugimoto, Kazuki
Yonemitsu, Ryuji
Matsushita, Kozo
Yugami, Masaki
Uehara, Yusuke
Nakamura, Takayuki
Tokunaga, Takuya
Karasugi, Tatsuki
Sueyoshi, Takanao
Shukunami, Chisa
Okamoto, Nobukazu
Masuda, Tetsuro
Miyamoto, Takeshi
Remnant tissue enhances early postoperative biomechanical strength and infiltration of Scleraxis-positive cells within the grafted tendon in a rat anterior cruciate ligament reconstruction model
title Remnant tissue enhances early postoperative biomechanical strength and infiltration of Scleraxis-positive cells within the grafted tendon in a rat anterior cruciate ligament reconstruction model
title_full Remnant tissue enhances early postoperative biomechanical strength and infiltration of Scleraxis-positive cells within the grafted tendon in a rat anterior cruciate ligament reconstruction model
title_fullStr Remnant tissue enhances early postoperative biomechanical strength and infiltration of Scleraxis-positive cells within the grafted tendon in a rat anterior cruciate ligament reconstruction model
title_full_unstemmed Remnant tissue enhances early postoperative biomechanical strength and infiltration of Scleraxis-positive cells within the grafted tendon in a rat anterior cruciate ligament reconstruction model
title_short Remnant tissue enhances early postoperative biomechanical strength and infiltration of Scleraxis-positive cells within the grafted tendon in a rat anterior cruciate ligament reconstruction model
title_sort remnant tissue enhances early postoperative biomechanical strength and infiltration of scleraxis-positive cells within the grafted tendon in a rat anterior cruciate ligament reconstruction model
topic Research Article
url https://www.ncbi.nlm.nih.gov/pmc/articles/PMC10631660/
https://www.ncbi.nlm.nih.gov/pubmed/37939095
http://dx.doi.org/10.1371/journal.pone.0293944
work_keys_str_mv AT kawakamijunki remnanttissueenhancesearlypostoperativebiomechanicalstrengthandinfiltrationofscleraxispositivecellswithinthegraftedtendoninaratanteriorcruciateligamentreconstructionmodel
AT hisanagasatoshi remnanttissueenhancesearlypostoperativebiomechanicalstrengthandinfiltrationofscleraxispositivecellswithinthegraftedtendoninaratanteriorcruciateligamentreconstructionmodel
AT yoshimotoyuki remnanttissueenhancesearlypostoperativebiomechanicalstrengthandinfiltrationofscleraxispositivecellswithinthegraftedtendoninaratanteriorcruciateligamentreconstructionmodel
AT mashimotomoji remnanttissueenhancesearlypostoperativebiomechanicalstrengthandinfiltrationofscleraxispositivecellswithinthegraftedtendoninaratanteriorcruciateligamentreconstructionmodel
AT kanekotakehito remnanttissueenhancesearlypostoperativebiomechanicalstrengthandinfiltrationofscleraxispositivecellswithinthegraftedtendoninaratanteriorcruciateligamentreconstructionmodel
AT yoshimuranaoto remnanttissueenhancesearlypostoperativebiomechanicalstrengthandinfiltrationofscleraxispositivecellswithinthegraftedtendoninaratanteriorcruciateligamentreconstructionmodel
AT shimadamasaki remnanttissueenhancesearlypostoperativebiomechanicalstrengthandinfiltrationofscleraxispositivecellswithinthegraftedtendoninaratanteriorcruciateligamentreconstructionmodel
AT tateyamamakoto remnanttissueenhancesearlypostoperativebiomechanicalstrengthandinfiltrationofscleraxispositivecellswithinthegraftedtendoninaratanteriorcruciateligamentreconstructionmodel
AT matsunagahideto remnanttissueenhancesearlypostoperativebiomechanicalstrengthandinfiltrationofscleraxispositivecellswithinthegraftedtendoninaratanteriorcruciateligamentreconstructionmodel
AT shibatayuto remnanttissueenhancesearlypostoperativebiomechanicalstrengthandinfiltrationofscleraxispositivecellswithinthegraftedtendoninaratanteriorcruciateligamentreconstructionmodel
AT tanimurashuntaro remnanttissueenhancesearlypostoperativebiomechanicalstrengthandinfiltrationofscleraxispositivecellswithinthegraftedtendoninaratanteriorcruciateligamentreconstructionmodel
AT takatakosei remnanttissueenhancesearlypostoperativebiomechanicalstrengthandinfiltrationofscleraxispositivecellswithinthegraftedtendoninaratanteriorcruciateligamentreconstructionmodel
AT arimatakahiro remnanttissueenhancesearlypostoperativebiomechanicalstrengthandinfiltrationofscleraxispositivecellswithinthegraftedtendoninaratanteriorcruciateligamentreconstructionmodel
AT maedakazuya remnanttissueenhancesearlypostoperativebiomechanicalstrengthandinfiltrationofscleraxispositivecellswithinthegraftedtendoninaratanteriorcruciateligamentreconstructionmodel
AT fukumayuko remnanttissueenhancesearlypostoperativebiomechanicalstrengthandinfiltrationofscleraxispositivecellswithinthegraftedtendoninaratanteriorcruciateligamentreconstructionmodel
AT uragamimasaru remnanttissueenhancesearlypostoperativebiomechanicalstrengthandinfiltrationofscleraxispositivecellswithinthegraftedtendoninaratanteriorcruciateligamentreconstructionmodel
AT ideokatsumasa remnanttissueenhancesearlypostoperativebiomechanicalstrengthandinfiltrationofscleraxispositivecellswithinthegraftedtendoninaratanteriorcruciateligamentreconstructionmodel
AT sugimotokazuki remnanttissueenhancesearlypostoperativebiomechanicalstrengthandinfiltrationofscleraxispositivecellswithinthegraftedtendoninaratanteriorcruciateligamentreconstructionmodel
AT yonemitsuryuji remnanttissueenhancesearlypostoperativebiomechanicalstrengthandinfiltrationofscleraxispositivecellswithinthegraftedtendoninaratanteriorcruciateligamentreconstructionmodel
AT matsushitakozo remnanttissueenhancesearlypostoperativebiomechanicalstrengthandinfiltrationofscleraxispositivecellswithinthegraftedtendoninaratanteriorcruciateligamentreconstructionmodel
AT yugamimasaki remnanttissueenhancesearlypostoperativebiomechanicalstrengthandinfiltrationofscleraxispositivecellswithinthegraftedtendoninaratanteriorcruciateligamentreconstructionmodel
AT ueharayusuke remnanttissueenhancesearlypostoperativebiomechanicalstrengthandinfiltrationofscleraxispositivecellswithinthegraftedtendoninaratanteriorcruciateligamentreconstructionmodel
AT nakamuratakayuki remnanttissueenhancesearlypostoperativebiomechanicalstrengthandinfiltrationofscleraxispositivecellswithinthegraftedtendoninaratanteriorcruciateligamentreconstructionmodel
AT tokunagatakuya remnanttissueenhancesearlypostoperativebiomechanicalstrengthandinfiltrationofscleraxispositivecellswithinthegraftedtendoninaratanteriorcruciateligamentreconstructionmodel
AT karasugitatsuki remnanttissueenhancesearlypostoperativebiomechanicalstrengthandinfiltrationofscleraxispositivecellswithinthegraftedtendoninaratanteriorcruciateligamentreconstructionmodel
AT sueyoshitakanao remnanttissueenhancesearlypostoperativebiomechanicalstrengthandinfiltrationofscleraxispositivecellswithinthegraftedtendoninaratanteriorcruciateligamentreconstructionmodel
AT shukunamichisa remnanttissueenhancesearlypostoperativebiomechanicalstrengthandinfiltrationofscleraxispositivecellswithinthegraftedtendoninaratanteriorcruciateligamentreconstructionmodel
AT okamotonobukazu remnanttissueenhancesearlypostoperativebiomechanicalstrengthandinfiltrationofscleraxispositivecellswithinthegraftedtendoninaratanteriorcruciateligamentreconstructionmodel
AT masudatetsuro remnanttissueenhancesearlypostoperativebiomechanicalstrengthandinfiltrationofscleraxispositivecellswithinthegraftedtendoninaratanteriorcruciateligamentreconstructionmodel
AT miyamototakeshi remnanttissueenhancesearlypostoperativebiomechanicalstrengthandinfiltrationofscleraxispositivecellswithinthegraftedtendoninaratanteriorcruciateligamentreconstructionmodel

Ejemplares similares