Advertisement for orthosearch.org.uk
Bone & Joint Open Logo

Receive monthly Table of Contents alerts from Bone & Joint Open

Comprehensive article alerts can be set up and managed through your account settings

View my account settings

Visit Bone & Joint Open at:

Loading...

Loading...

Open Access

Foot & Ankle

Particulated autologous cartilage transplantation for the treatment of osteochondral lesion of the talus: can the lesion cartilage be recycled?



Download PDF

Abstract

Aims

Osteochondral lesions of the talus (OLT) are a common cause of disability and chronic ankle pain. Many operative treatment strategies have been introduced; however, they have their own disadvantages. Recently lesion repair using autologous cartilage chip has emerged therefore we investigated the efficacy of particulated autologous cartilage transplantation (PACT) in OLT.

Methods

We retrospectively analyzed 32 consecutive symptomatic patients with OLT who underwent PACT with minimum one-year follow-up. Standard preoperative radiography and MRI were performed for all patients. Follow-up second-look arthroscopy or MRI was performed with patient consent approximately one-year postoperatively. Magnetic resonance Observation of Cartilage Repair Tissue (MOCART) score and International Cartilage Repair Society (ICRS) grades were used to evaluate the quality of the regenerated cartilage. Clinical outcomes were assessed using the pain visual analogue scale (VAS), Foot Function Index (FFI), and Foot Ankle Outcome Scale (FAOS).

Results

All patients had ICRS grade IV cartilage lesions, except for one (ICRS grade III). The paired MOCART scores significantly improved from 42.5 (SD 1.53) to 63.5 (SD 22.60) (p = 0.025) in ten patients. Seven patients agreed to undergo second-look arthroscopy; 5 patients had grade I (normal) ICRS scores and two patients had grade II (nearly normal) ICRS scores. VAS, FFI, and all subscales of FAOS were significantly improved postoperatively (p ≤ 0.003).

Conclusion

PACT significantly improved the clinical, radiological, and morphological outcomes of OLT. We consider this to be a safe and effective surgical method based on the short-term clinical results of this study.

Cite this article: Bone Jt Open 2023;4(12):942–947.

Take home message

Particulated autologous cartilage transplantation significantly improved the clinical, radiological, and morphological outcomes of osteochondral lesions of the talus.

We consider this to be a safe and effective surgical method based on the short-term clinical results of this study.

Introduction

Osteochondral lesions of the talus (OLT) are a common cause of disability and chronic ankle pain. Initial nonoperative management includes rest, immobilization, and anti-inflammatory drugs. Tol et al1 demonstrated a 45% success rate of nonoperative management for the treatment of OLT. If conservative treatment is ineffective, operative treatments, such as bone marrow stimulation (BMS), osteochondral autograft transplantation (OAT), autologous chondrocyte implantation (ACI), or osteochondral allograft transplantation can be considered.2-5 However, these treatment strategies have disadvantages, such as inconsistent clinical and biological outcomes, donor site morbidity, poor integration, and high cost.

Surgical treatment strategies for OLT have advanced significantly over the past decade. Lesion repair using autologous cartilage chips is an emerging treatment method. The surge in interest in this novel strategy has been stimulated by both credible clinical and preclinical studies and the need for a more cost-effective treatment for articular cartilage lesions.6-10 A method was first introduced by Lu et al11 in 2006, in which autologous cartilage was minced and transplanted into an animal chondral defect model. They reported consequent chondrocyte migration and outgrowth, indicating that fragmented cartilage chips could be an abundant source of cartilage for redistribution. In a subsequent study, Christensen et al8 compared autologous cartilage chip transplantation with BMS, finding that autologous cartilage chip transplantation resulted in superior regeneration of hyaline cartilage, less fibrous tissue components, and improved histological scores. This technique uses autologous hyaline cartilage harvested from the trochlear border or intercondylar notch in a knee joint for transplant to the curetted lesion site.

Another possible donor for autologous cartilage transplantation is the detached cartilage from OLT. Previous studies have specified that chondrocytes from the lesion itself are viable and could be used for further transplantation.12,13 However, the clinical outcomes of particulate autologous cartilage transplantation using lesion cartilage are lacking.

In this retrospective study, we investigated the efficacy of autologous cartilage chip transplantation using cartilage derived from OLT. We hypothesized that autologous cartilage chip transplantation would improve clinical and morphological outcomes in patients with OLT.

Methods

We retrospectively analyzed 32 consecutive symptomatic patients with OLT who underwent PACT between August 2020 and December 2021. All surgeries were performed by a senior surgeon (BSK) and all patients had a minimum of one year follow-up. The inclusion criteria for the study were chondral or osteochondral lesions of the talus, no previous surgical treatment for OLT, and pain or functional impairments despite a minimum of six months of conservative treatment. The exclusion criteria were the presence of osteoarthritis (Kellgren-Lawrence grade ≥ 1),14 malalignment of ankle joint, and a history of previous surgical treatment or ankle fracture. Standard preoperative radiography and MRI were performed for all 32 patients. A previously reported method for the measurement of the area and volume of the ellipse which uses the width and length of the lesion on MRI was used.3,15 Follow-up second-look arthroscopy or MRI was performed with patient consent approximately one year postoperatively. An independent radiologist evaluated the images, and the Magnetic resonance Observation of Cartilage Repair Tissue (MOCART) score16 was used (100 best; 0 worst) in the analysis. Pre- and postoperative International Cartilage Repair Society (ICRS) grades17 were used to evaluate the quality of the regenerated cartilage by an independent orthopaedic surgeon.

Pre- and postoperative clinical outcomes were assessed using the pain visual analogue scale (VAS), Foot Function Index (FFI),18 and Foot Ankle Outcome Score (FAOS).19 The translational and transcultural adaptation of both functional outcome measures into the domestic version were validated.20,21

Surgical technique

All arthroscopic procedures were performed using the same technique. The patient was placed in the supine position, and two anterior portals (anteromedial and anterolateral) were used for the arthroscope and working instrument. Non-invasive traction (15 pounds) was applied using a footstrap for gentle ankle distraction. The joint was examined arthroscopically and the site and stability of the lesion were assessed. The cartilage was detached from the lesion using a grasper (Figure 1), and a small fragment of the cartilage was sent to the pathology department to check the viability. The remaining cartilage was then particulated into an approximately 1 mm3 cube using a scalpel by an operating assistant. During fragmentation, the cartilaginous subchondral bone was examined by the senior author (BSK); unstable fragments were removed, and microfractures were performed to create a stable, smooth articular surface. Associated intra-articular lesions were assessed during surgery and debrided, removed, or excised. After removing the saline, the particulate cartilages were placed on the lesion under direct visualization using a dry scope (Figure 1). A freer elevator was used to shape the packed cartilage to align with the surrounding articular surface. Fibrin glue (GC Biopharma, Korea) was applied over the minced cartilage for stabilization.

Fig. 1 
            a) Detached cartilage of the osteochondral lesion was harvested using a grasper. b) Subchondral bone defect was curetted and microfracture was performed to create a sufficient bleeding surface. c) After saline drainage, under direct visualization using a dry-scope, the particulated cartilages were transplanted to fill the lesion. d) Fibrin glue was applied over the cartilage fragments for stabilization.

Fig. 1

a) Detached cartilage of the osteochondral lesion was harvested using a grasper. b) Subchondral bone defect was curetted and microfracture was performed to create a sufficient bleeding surface. c) After saline drainage, under direct visualization using a dry-scope, the particulated cartilages were transplanted to fill the lesion. d) Fibrin glue was applied over the cartilage fragments for stabilization.

An active range of motion exercises were encouraged two to three days postoperatively. The patients were placed in a splint for two weeks. After removal of the stitches, the patients wore firm walker boots, and partial weightbearing was permitted using crutches until postoperative six weeks.

Statistical analysis

SPSS version 25.0 (IBM, USA) was used for all statistical analyses. Patient demographics and clinical outcomes are presented as mean ± standard deviation (SD) or number. We performed Kolmogorov-Smirnov and Shapiro-Wilk normality tests to check the normality of the data. We used paired t-test to assess pre- and postoperative outcomes and Mann-Whitney test to compare subcategories. Pearson’s correlation analysis was used to analyze correlations between patient characteristics and outcomes. The level of statistical significance was set at p < 0.05.

Results

Patient characteristics are presented in Table I. A total of 16 patients (50%) had a BMI > 25 kg/m2, three patients had a large lesion surface area (> 150 mm2), and seven patients had a large cyst (> 300 mm3). Chronic lateral ankle instability (CLAI) was diagnosed in 14 patients; therefore, a concomitant modified Broström operation was performed.

Table I.

Patient characteristics (n = 32).

Variable Data
Mean age, yrs, (SD; range) 37.3 (16.5; 17 to 63)
Male, n (%) 18 (56.3)
Right, n (%) 17 (53.1)
Mean BMI, kg/m2 (SD; range) 25.3 (3.9; 19.2 to 36.9)
Mean area, mm2 (SD; range) 79.7 (40.7; 21.2 to 173.1)
Mean volume, mm3 (SD; range) 226.8 (184.9; 15.3 to 993.2)
Mean preoperative MOCART score (SD; range) 38.3 (14.0; 5 to 75)
Mean follow-up duration, mnths (SD; range) 17.1 (5.3; 12 to 30)
  1. MOCART, Magnetic resonance Observation of Cartilage Repair Tissue; SD, standard deviation.

Intra-articular lesions observed in arthroscopy are presented in Table II. All patients had ICRS grade IV cartilage lesions, except for one (ICRS grade III). A small piece of the cartilage fragment was biopsied from each patient. Pathologists confirmed the viability of the lesion cartilage on the basis of live chondrocytes (mean 31.4 cells/high power field; 26 to 39) and live hyaline matrix from all specimens (Figure 2).

Table II.

Intra-articular lesions and accompanying procedures in arthroscopy.

Intra-articular lesions Procedure N (%)
Synovitis Debridement 28 (87.5)
Soft-tissue impingement Debridement 21 (65.6)
Ossicle Removal 4 (12.5)
Osteophyte Excision 3 (9.4)
Loose body Removal 3 (9.4)
Os trigonum Excision 3 (9.4)
Ganglion Excision 1 (3.1)
Fig. 2 
          Representative of the histological examination of a detached lesion cartilage. Hematoxylin and eosin staining was performed to check cell viability. Live chondrocytes within the lacunae (arrow) and the hyaline matrix (asterisk) were confirmed in all specimens (n = 32) (scale bars 200 μm).

Fig. 2

Representative of the histological examination of a detached lesion cartilage. Hematoxylin and eosin staining was performed to check cell viability. Live chondrocytes within the lacunae (arrow) and the hyaline matrix (asterisk) were confirmed in all specimens (n = 32) (scale bars 200 μm).

The clinical outcomes are shown in Table III. All parameters, including the pain VAS, FFI, and FAOS scores, showed significant postoperative improvements. Age, BMI, lesion area, and lesion volume were not significantly correlated with clinical outcomes according to Pearson’s analysis (p ≥ 0.133). Risk factors including BMI > 25 kg/m2 (n = 16), large lesion area > 150 mm2 (n = 3), large lesion volume > 300 mm3 (n = 7), and presence of CLAI (n = 14) were assessed using nominal scales to determine whether they influenced the clinical outcomes. Subgroup analysis was performed to compare clinical outcomes according to lesion size, volume, BMI, and presence of CLAI. There were no significant differences among the subgroups according to the VAS, FFI, and FAOS scores (p ≥ 0.081, Mann-Whitney test).

Table III.

Clinical outcomes of arthroscopic particulated autologous cartilage transplantation.

Variable, mean (SD) Preoperative Postoperative p-value*
VAS 6.6 (0.9) 2.3 (2.0) < 0.001
FFI 46.5 (18.7) 15.4 (12.6) < 0.001
FAOS < 0.001
Symptom 53.2 (15.8) 79.9 (13.1) < 0.001
Pain 53.6 (13.5) 83.2 (13.1) < 0.001
Active daily living 70.0 (15.1) 90.7 (9.4) < 0.001
Sports 49.7 (17.0) 64.0 (24.3) 0.003
Quality of life 36.7 (15.4) 71.8 (20.2) < 0.001
Sum 52.6 (11.5) 77.9 (13.6) < 0.001
  1. *

    Paired t-test.

  1. FAOS, Foot and Ankle Outcome Scale; FFI, Foot Function Index; VAS, visual analogue scale.

Follow-up MRIs were performed in ten patients after mean 12.0 months (SD 2.6; 11 to 19). The paired MOCART scores significantly improved from 42.5 (SD 1.53) to 63.5 (SD 22.6) (p = 0.025, paired t-test) (Figure 3). Seven patients agreed to undergo second-look arthroscopy after mean 11.4 months (SD 2.0; 11 to 14). Five patients had grade I (normal) ICRS scores, and two patients had grade II (nearly normal) ICRS scores (Figure 4). There were no reported complications related to any of the surgeries.

Fig. 3 
          a, b, and c) Preoperative standing anteroposterior radiograph and MRI scans of a 20-year-old female patient showing a completely detached osteochondral lesion (10 mm width, 20 mm length) on the medial talar dome. d, e, and f) 11-month postoperative images showing restoration of the lesion with homogenous cartilage well integrated with the surrounding cartilage. Note the reduced joint fluid in the postoperative MRI (f) compared to the preoperative image (c).

Fig. 3

a, b, and c) Preoperative standing anteroposterior radiograph and MRI scans of a 20-year-old female patient showing a completely detached osteochondral lesion (10 mm width, 20 mm length) on the medial talar dome. d, e, and f) 11-month postoperative images showing restoration of the lesion with homogenous cartilage well integrated with the surrounding cartilage. Note the reduced joint fluid in the postoperative MRI (f) compared to the preoperative image (c).

Fig. 4 
          a, c) Initial arthroscopic findings of two patients after microfracture and their corresponding second-look arthroscopic findings (b,d). a, b) A 21-year-old male patient with preoperative and 11-month postoperativearthroscopic findings with grade I International Cartilage Repair Society (ICRS) score. c, d) A 25-year-old female patient with preoperative and 12-month postoperative arthroscopic findings with grade I ICRS score.

Fig. 4

a, c) Initial arthroscopic findings of two patients after microfracture and their corresponding second-look arthroscopic findings (b,d). a, b) A 21-year-old male patient with preoperative and 11-month postoperativearthroscopic findings with grade I International Cartilage Repair Society (ICRS) score. c, d) A 25-year-old female patient with preoperative and 12-month postoperative arthroscopic findings with grade I ICRS score.

Discussion

The present study is the first to investigate PACT using lesioned cartilage for the treatment of OLT. The cartilage detached from the lesion was particulated and recycled to serve as a scaffold for live chondrocytes to enhance the healing process. The primary finding of this study was improved clinical and morphological outcomes. Biological healing response, examined via MRI or second-look arthroscope, was characterized with favourable cartilage repair.

The use of autologous cartilage chips for repair was first described in 1983 and has been further investigated in recent years.7,8,11,22 Animal models have demonstrated that articular chondrocytes from cartilage chips are not notably damaged if the cartilage is cut using a sharp scalpel and can migrate from their initial matrix to form a novel extracellular matrix.23-27 Chondrocytes that are brought to the surface of their surrounding matrix start to proliferate again as part of a natural healing process, which has been shown to spontaneously heal small cartilage lesions in animal models.28 In addition, PACT has shown significant cartilage repair results without bone graft in the shallow osteochondral lesion in a recent preclinical study.29 Moreover, the degree of fragmentation is important. When cartilage chips are too large, a limited number of chondrocytes are activated. Bonasia et al30 reported that the paste-like appearance of cartilage chips would provide an optimal environment for the regeneration of high-quality tissue.30

Is the detached cartilage from an osteochondral lesion viable? Can damaged cartilage be recycled and used to enhance regeneration? Previous studies have reported that chondrocytes from the lesion itself are viable and could be used for further transplantation.12,13 Chaipinyo et al13 showed that lesion articular cartilage was comparable to normal articular cartilage in morphology, cell density, ability to proliferate, and protein synthesis.13 Biant et al12 showed that mean concentration of glycosaminoglycan and the quantity of DNA in cell pellets from lesions and normal cartilage were not significantly different. Furthermore, the contents were comparable to those of chondrocytes from autologous bone marrow derived cells.12 These findings are comparable with our result that the fragments from the lesion are alive with healthy chondrocytes and hyaline matrix (Figure 2).

Previous studies using minced cartilage transplantation for osteochondral knee lesions have reported promising short-term outcomes. Christensen et al9 showed significant clinical and radiological improvements using autologous bone graft and cartilage chips in eight patients with a one-year follow-up. All parameters according to International Knee Documentation Committee (IKDC) score31 (from 35.9 to 68.1; p < 0.01), Tegner score32 (from 2.6 to 4.7; p < 0.05), 4/5 subscales of Knee injury and Osteoarthritis Outcome Score (KOOS)33 (p < 0.05), and MOCART score (from 22.5 to 52.5; p < 0.01) increased significantly. Massen et al10 reported significant improvements in pain (from 7.2 (SD 1.9) to 1.8 (SD 1.6); p < 0.001), function (from 7.2 (SD 2.0) to 2.1 (SD 2.3); p < 0.001), and MRI findings in osteochondral lesions of 27 patients treated with a minced cartilage procedure with a two-year follow-up.10

In addition, several studies compared the results of PACT with BMS. PACT showed more hyaline cartilage (17.1%) and less fibrous tissue (23.8%) compared to BMS (2.9% and 41.1%, respectively) in a preclinical study (p < 0.01 and p < 0.01, respectively).8 Also, PACT was superior to BMS in ICRS II scores and type II collagen staining after six months (p < 0.05 and p < 0.05, respectively). Cole et al34 prospectively compared the effect of BMS and cell-based cartilage repair using the Cartilage Autograft Implantation System (CAIS) with two-year follow-up, and concluded that IKDC score and most subdomains on the KOOS were significantly higher in the CAIS group. Moreover, higher incidence of intralesional osteophyte formation was observed in the BMS group (70%) than in the CAIS group (25%) at one-year follow-up. Although it is not discussed in this study, the superior clinical and histological results of PACT to BMS are expected to be similar in the ankle which should be investigated subsequently.

Allogenous particulate juvenile cartilage has been widely used in ankle joints. Ryan et al35 concluded that particulated juvenile allografts were effective whether by arthroscopy or open arthrotomy. However, Saltzman et al36 showed that three out of six patients (50%) had persistent subchondral bone oedema and an uneven repaired tissue surface. Coetzee et al37 concluded that clinical outcomes diminished when the lesion was larger than 150 mm2. Similarly, Dekker et al38 found that larger defects more than 125 mm2 were prone to clinical failure (6/15 patients; 40%). Although limited in numbers, the current study has shown promising outcomes in patients with large lesion areas over 150 mm2 or large lesion volume over 300 mm3. Longer follow-up periods are required to confirm the promising clinical outcomes of PACT in patients with large lesions.

This study has several limitations. First, this was a retrospective study with a short follow-up period. Thus, we were unable to deduce any possible interactions between clinical and radiological outcomes and risk factors, including high BMI, large lesions, and large volume. Long-term deterioration of the regenerated cartilage cannot be ruled out. Second, the absence of a control group, such as BMS or OAT, is another limitation, although the results of the current study were consistent in all patients. Third, the lack of postoperative pathology could have weakened the correlation between the histological and the clinical or radiological outcomes. However, previous preclinical studies have shown a superior quality of regenerated cartilage in PACT, which could explain the improved outcomes.

In conclusion, PACT significantly improved the clinical, radiological, and morphological outcomes of OLT. We consider this to be a safe and effective surgical method based on the short-term clinical results of this study. Larger, controlled, long-term studies are needed to validate this procedure.


Correspondence should be sent to Bom Soo Kim. E-mail:

References

1. Tol JL , Struijs PA , Bossuyt PM , Verhagen RA , van Dijk CN . Treatment strategies in osteochondral defects of the talar dome: a systematic review . Foot Ankle Int . 2000 ; 21 ( 2 ): 119 126 . Crossref PubMed Google Scholar

2. Park KH , Hwang Y , Han SH , et al. Primary versus secondary osteochondral autograft transplantation for the treatment of large osteochondral lesions of the talus . Am J Sports Med . 2018 ; 46 ( 6 ): 1389 1396 . Crossref PubMed Google Scholar

3. Shim DW , Park KH , Lee JW , Yang YJ , Shin J , Han SH . Primary autologous osteochondral transfer shows superior long-term outcome and survival rate compared with bone marrow stimulation for large cystic osteochondral lesion of talus . Arthroscopy . 2021 ; 37 ( 3 ): 989 997 . Crossref PubMed Google Scholar

4. Easley ME , Latt DL , Santangelo JR , Merian-Genast M , Nunley JA . Osteochondral lesions of the talus . Am Acad Orthop Surg . 2010 ; 18 ( 10 ): 616 630 . Crossref PubMed Google Scholar

5. Ferkel RD , Scranton PE , Stone JW , Kern BS . Surgical treatment of osteochondral lesions of the talus . Instr Course Lect . 2010 ; 59 : 387 404 . PubMed Google Scholar

6. Christensen BB , Olesen ML , Hede KTC , Bergholt NL , Foldager CB , Lind M . Particulated cartilage for chondral and osteochondral repair: a review . Cartilage . 2021 ; 13 ( 1_suppl ): 1047S 1057S . Crossref PubMed Google Scholar

7. Christensen BB , Foldager CB , Olesen ML , Hede KC , Lind M . Implantation of autologous cartilage chips improves cartilage repair tissue quality in osteochondral defects: a study in Göttingen Minipigs . Am J Sports Med . 2016 ; 44 ( 6 ): 1597 1604 . Crossref PubMed Google Scholar

8. Christensen BB , Olesen ML , Lind M , Foldager CB . Autologous cartilage chip transplantation improves repair tissue composition compared with marrow stimulation . Am J Sports Med . 2017 ; 45 ( 7 ): 1490 1496 . Crossref PubMed Google Scholar

9. Christensen BB , Foldager CB , Jensen J , Lind M . Autologous dual-tissue transplantation for osteochondral repair: early clinical and radiological results . Cartilage . 2015 ; 6 ( 3 ): 166 173 . Crossref PubMed Google Scholar

10. Massen FK , Inauen CR , Harder LP , Runer A , Preiss S , Salzmann GM . One-step autologous minced cartilage procedure for the treatment of knee joint chondral and osteochondral lesions: a series of 27 patients with 2-year follow-up . Orthop J Sports Med . 2019 ; 7 ( 6 ): 2325967119853773 . Crossref PubMed Google Scholar

11. Lu Y , Dhanaraj S , Wang Z , et al. Minced cartilage without cell culture serves as an effective intraoperative cell source for cartilage repair . J Orthop Res . 2006 ; 24 ( 6 ): 1261 1270 . Crossref PubMed Google Scholar

12. Biant LC , Bentley G . Stem cells and debrided waste: two alternative sources of cells for transplantation of cartilage . J Bone Joint Surg Br . 2007 ; 89 ( 8 ): 1110 1114 . Crossref PubMed Google Scholar

13. Chaipinyo K , Oakes BW , Van Damme M-PI . The use of debrided human articular cartilage for autologous chondrocyte implantation: maintenance of chondrocyte differentiation and proliferation in type I collagen gels . J Orthop Res . 2004 ; 22 ( 2 ): 446 455 . Crossref PubMed Google Scholar

14. Kellgren JH , Lawrence JS . Radiological assessment of osteo-arthrosis . Ann Rheum Dis . 1957 ; 16 ( 4 ): 494 502 . Crossref PubMed Google Scholar

15. Choi WJ , Park KK , Kim BS , Lee JW . Osteochondral lesion of the talus: is there a critical defect size for poor outcome? Am J Sports Med . 2009 ; 37 ( 10 ): 1974 1980 . Crossref PubMed Google Scholar

16. Schreiner MM , Raudner M , Marlovits S , et al. The MOCART (Magnetic Resonance Observation of Cartilage Repair Tissue) 2.0 Knee Score and Atlas . Cartilage . 2021 ; 13 ( 1_suppl ): 571S 587S . Crossref PubMed Google Scholar

17. van den Borne MPJ , Raijmakers NJH , Vanlauwe J , et al. International Cartilage Repair Society (ICRS) and Oswestry macroscopic cartilage evaluation scores validated for use in Autologous Chondrocyte Implantation (ACI) and microfracture . Osteoarthr Cartil . 2007 ; 15 ( 12 ): 1397 1402 . Crossref PubMed Google Scholar

18. Budiman-Mak E , Conrad KJ , Roach KE . The Foot Function Index: a measure of foot pain and disability . J Clin Epidemiol . 1991 ; 44 ( 6 ): 561 570 . Crossref PubMed Google Scholar

19. Roos EM , Brandsson S , Karlsson J . Validation of the foot and ankle outcome score for ankle ligament reconstruction . Foot Ankle Int . 2001 ; 22 ( 10 ): 788 794 . Crossref PubMed Google Scholar

20. Huh J-W , Eun I-S , Ko Y-C , et al. Reliability and validity of the korean version of the foot function index . J Foot Ankle Surg . 2016 ; 55 ( 4 ): 759 761 . Crossref PubMed Google Scholar

21. Lee KM , Chung CY , Kwon SS , et al. Transcultural adaptation and testing psychometric properties of the Korean version of the Foot and Ankle Outcome Score (FAOS) . Clin Rheumatol . 2013 ; 32 ( 10 ): 1443 1450 . Crossref PubMed Google Scholar

22. Albrecht FH . Closure of joint cartilage defects using cartilage fragments and fibrin glue . Fortschr Med . 1983 ; 101 ( 37 ): 1650 1652 . PubMed Google Scholar

23. Bonasia DE , Marmotti A , Rosso F , Collo G , Rossi R . Use of chondral fragments for one stage cartilage repair: a systematic review . World J Orthop . 2015 ; 6 ( 11 ): 1006 1011 . Crossref PubMed Google Scholar

24. Frisbie DD , Lu Y , Kawcak CE , DiCarlo EF , Binette F , McIlwraith CW . In vivo evaluation of autologous cartilage fragment-loaded scaffolds implanted into equine articular defects and compared with autologous chondrocyte implantation . Am J Sports Med . 2009 ; 37 Suppl 1 : 71S 80S . Crossref PubMed Google Scholar

25. Lind M , Larsen A . Equal cartilage repair response between autologous chondrocytes in a collagen scaffold and minced cartilage under a collagen scaffold: an in vivo study in goats . Connect Tissue Res . 2008 ; 49 ( 6 ): 437 442 . Crossref PubMed Google Scholar

26. Wang N , Grad S , Stoddart MJ , et al. Particulate cartilage under bioreactor-induced compression and shear . Int Orthop . 2014 ; 38 ( 5 ): 1105 1111 . Crossref PubMed Google Scholar

27. Redman SN , Dowthwaite GP , Thomson BM , Archer CW. . The cellular responses of articular cartilage to sharp and blunt trauma . Osteoarthr Cartil . 2004 ; 12 ( 2 ): 106 - 116 . Crossref PubMed Google Scholar

28. Mukoyama S , Sasho T , Akatsu Y , et al. Spontaneous repair of partial thickness linear cartilage injuries in immature rats . Cell Tissue Res . 2015 ; 359 ( 2 ): 513 520 . Crossref PubMed Google Scholar

29. Shim DW , Lee K-M , Lee D , et al. Osteochondral repair with autologous cartilage transplantation with or without bone grafting: a short pilot study in mini-pigs . Cartilage . 2023 ; 19476035231199442 . Crossref PubMed Google Scholar

30. Bonasia DE , Martin JA , Marmotti A , et al. The use of autologous adult, allogenic juvenile, and combined juvenile-adult cartilage fragments for the repair of chondral defects . Knee Surg Sports Traumatol Arthrosc . 2016 ; 24 ( 12 ): 3988 3996 . Crossref PubMed Google Scholar

31. Irrgang JJ , Anderson AF , Boland AL , et al. Development and validation of the international knee documentation committee subjective knee form . Am J Sports Med . 2001 ; 29 ( 5 ): 600 613 . Crossref PubMed Google Scholar

32. Tegner Y , Lysholm J . Rating systems in the evaluation of knee ligament injuries . Clin Orthop Relat Res . 1985 ; 198 ( 198 ): 43 49 . PubMed Google Scholar

33. Roos EM , Roos HP , Lohmander LS , Ekdahl C , Beynnon BD . Knee Injury and Osteoarthritis Outcome Score (KOOS)--development of a self-administered outcome measure . J Orthop Sports Phys Ther . 1998 ; 28 ( 2 ): 88 96 . Crossref PubMed Google Scholar

34. Cole BJ , Farr J , Winalski CS , et al. Outcomes after a single-stage procedure for cell-based cartilage repair: a prospective clinical safety trial with 2-year follow-up . Am J Sports Med . 2011 ; 39 ( 6 ): 1170 1179 . Crossref PubMed Google Scholar

35. Ryan PM , Turner RC , Anderson CD , Groth AT . Comparative outcomes for the treatment of articular cartilage lesions in the ankle with a DeNovo NT Natural Tissue Graft: open versus arthroscopic treatment . Orthop J Sports Med . 2018 ; 6 ( 12 ): 2325967118812710 . Crossref PubMed Google Scholar

36. Saltzman BM , Lin J , Lee S . Particulated juvenile articular cartilage allograft transplantation for osteochondral talar lesions . Cartilage . 2017 ; 8 ( 1 ): 61 72 . Crossref PubMed Google Scholar

37. Coetzee JC , Giza E , Schon LC , et al. Treatment of osteochondral lesions of the talus with particulated juvenile cartilage . Foot Ankle Int . 2013 ; 34 ( 9 ): 1205 1211 . Crossref PubMed Google Scholar

38. Dekker TJ , Steele JR , Federer AE , Easley ME , Hamid KS , Adams SB . Efficacy of particulated juvenile cartilage allograft transplantation for osteochondral lesions of the talus . Foot Ankle Int . 2018 ; 39 ( 3 ): 278 283 . Crossref PubMed Google Scholar

Author contributions

D. W. Shim: Conceptualization, Data curation, Funding acquisition, Investigation, Resources, Software, Validation, Visualization, Writing – original draft.

H. Hong: Formal analysis, Investigation, Software.

J. W. Lee: Formal analysis, Methodology, Supervision, Visualization.

B. S. Kim: Data curation, Investigation, Methodology, Project administration, Validation, Visualization, Writing – review & editing.

Funding statement

The author(s) disclose receipt of the following financial or material support for the research, authorship, and/or publication of this article: This work was supported by Inha University Research Grant (67945-1).

Data sharing

The data that support the findings for this study are available to other researchers from the corresponding author upon reasonable request.

Ethical review statement

This study was approved by the Inha University Hospital Institutional Review Board (INHAUH 2023-01-030).

Open access funding

The authors report that the open access funding for this manuscript was supported by Inha University Research Grant (67945-1).

© 2023 Kim et al. This is an open-access article distributed under the terms of the Creative Commons Attribution Non-Commercial No Derivatives (CC BY-NC-ND 4.0) licence, which permits the copying and redistribution of the work only, and provided the original author and source are credited. See https://creativecommons.org/licenses/by-nc-nd/4.0/