Skip to main content
NCBI home page
Orthopedic Reviews logoLink to Orthopedic Reviews
. 2024 Feb 7;16:92644. doi: 10.52965/001c.92644

Partial Patellar Tendon Tears in Athletes: A Systematic Review of Treatment Options, Outcomes, and Return to Sport

Luke A Sandoval 1,, Charles R Reiter 1, James R Satalich 1, Conor N O’Neill 2, John W Cyrus 3, Alexander R Vap 1
PMCID: PMC10853059  PMID: 38343530

Abstract

Introduction

Partial patellar tendon tears (PPTTs) are overuse injuries in sports with frequent jumping, such as basketball and volleyball. There are several treatment options, including both operative and non-operative modalities. Current literature is largely focused broadly on patellar tendinopathy; however, there are few studies which specifically evaluate treatment outcomes for PPTTs.

Objective

To systematically review the literature on treatment options, clinical outcomes, and return to sport (RTS) in athletes with a PPTT.

Methods

PubMed, Embase, and Cochrane were searched through May 1st, 2023 for studies reporting treatment outcomes in athletes with partial patellar tendon tears. Data was extracted on the following topics: treatment modalities, surgical failures/reoperations, surgical complications, RTS, and postoperative time to RTS.

Results

The review covers 11 studies with 454 athletes: 343 males (86.2%) and 55 females (13.8%). The average age was 25.8 years, ranging from 15 to 55 years. 169 patients (37.2%) received only non-operative treatments, while 295 (65.0%) underwent surgery. 267 patients (92.1%) returned to sports after 3.9 months of treatment. The average follow-up was 55.8 months.

Conclusion

Our review of current literature on PPTTs in athletes illustrates over 90% return to sport following either conservative or surgical treatment. There is currently little data that directly compares the treatment options to establish an evidence-based “gold-standard” treatment plan. The data we present suggests that current treatment options are satisfactory but would benefit from future study.

Keywords: Partial patellar tendon tear, partial patellar tendon rupture, athlete, return to sport.

INTRODUCTION

Partial tears or ruptures of the patellar tendon are a progression of chronic patellar tendinopathy,1 which present similarly and are not as well studied in isolation. The pathophysiology of tendinopathies is complex and multifactorial, but one proposed mechanism involves tendon degeneration and microtears.1–3 Patellar tendinopathy, often also called “jumper’s knee,”4 is a relatively common injury among athletes of sports which involve significant jumping.5–7 Previous studies have estimated an overall prevalence of about 14% in elite athletes across several sports, with a higher rates in elite volleyball players (44.6%) and elite basketball players (31.9%).6 The prevalence was estimated to be lower in nonelite athletes, around 8.5%, and most commonly appearing in volleyball, handball, and basketball.7 These sports share common risk factors for patellar tendinopathy and partial tears, including tall stature athletes, higher body mass, frequent jumping, and hard surfaces.5,8,9 In addition to extrinsic factors, such as tendon overload and overuse,8–11 there is data to suggest that intrinsic factors, such as muscle tightness, muscular imbalance, and malalignment,10,12 may also be contributing risk factors.

Partial patellar tendon tears (PPTTs) present added complexity over patellar tendinopathy and complete patellar tendon tears, as continued sports involvement worsens the damage seen in typical tendinopathy, but a partially intact tendon allows additional treatment options compared to full ruptures.13 Whereas treatment for patellar tendinopathy is generally non-operative,10 treatment decisions for PPTTs are complicated by the severity of the tear, the patient’s preferences, and the goals of rehabilitation.13 Examples of non-operative interventions for PPTTs typically include anti-inflammatory medications, physical therapy, and bracing; however, platelet-rich plasma injections and extracorporeal shock wave therapy have become increasingly popular.13

To date, there is no systematic review summarizing the effectiveness and safety of different treatment modalities, outcomes, and return to sport (RTS) rates for PPTT in athletes. This article aims to provide a comprehensive and updated systematic review of the literature on PPTT in athletes, covering treatment options, outcomes, and RTS guidelines. This article also discusses the challenges and limitations of existing studies and suggests directions for future research.

METHODS

Literature & Database Search

A systematic search of published, peer-reviewed literature was conducted with a research librarian of PubMed (Ovid), Embase (Ovid), and Cochrane from inception of the database to May 1st, 2023. The search consisted of a combination of keywords and controlled vocabulary for the following concepts: partial patellar tendon tear, athletes, surgery, conservative management, treatment outcomes, return to sport. The full details of the search strategy for PubMed, Embase, and Cochrane are available in Appendices A, Table A.1, A.2, and A.3, respectively. All identified records were imported into Covidence reference management software (Covidence, https://covidence.org/) and duplicate references were removed (Figure 1). The literature search and subsequent review was conducted in accordance with the Preferred Reporting Items for Systematic Reviews and Meta-Analyses (PRISMA) reporting standards.14

Figure 1. PRISMA 2020 flow diagram for new systematic reviews which included searches of databases and registers only.

Figure 1.

Open in a new tab

Inclusion Criteria & Study Selection

Two blind reviewers (LS, CR) manually screened titles and abstracts to identify records which primarily investigated partial patellar tendon tears and return to sport (RTS) outcomes in athletic patient populations (Figure 1). Studies which lacked treatment outcomes after PPTTs for athletes were excluded from analysis. Case reports, case series, cohort studies, and randomized controlled trials published prior to database search were included for evaluated for inclusion; however, abstracts, reviews, technical notes, letters to the editor, and surgical technique papers were excluded from evaluation. In addition, cadaveric, non-human, and non-English studies were excluded. Any discrepancies and conflicts between reviewers during the study selection process were resolved by a third, independent reviewer (JS) as needed. The full details of the protocols for this systematic review were prospectively registered on PROSPERO and are available at https://www.crd.york.ac.uk/prospero/display_record.php?ID=CRD42023416787.

Risk of Bias & Quality Assessment

The risk of bias for included studies was assessed using the JBI Critical Appraisal tools for cohort studies, case series, and case reports.15 Each checklist is comprised of a unique set of questions to evaluate the validity of methods, quality of analysis and presentation for each study type. Two reviewers (LS, CR) each reviewed the included studies and discussed discrepancies to reach a consensus. Any disagreements were settled by a third, independent reviewer (JS).

Data Extraction

For each included study, one reviewer (LS) independently extracted data into a spreadsheet. After a first pass of the studies, the extracted data was evaluated by another reviewer. Any discrepancies and conflicts between reviewers during this process were resolved by a third, independent reviewer (JS) as needed. Extracted data points included: study type and level of evidence, number of patients, male to female ratio, mean age, sport, level of sport, treatment type/modality, follow-up duration, surgical complications, surgical failures/reoperations, RTS, postoperative RTS time, and patient-reported performance outcome measures.

Statistical Analysis

Categorical variables were summated and presented as total counts or proportions, whereas weighted means were calculated for continuous variables. Outcomes of interest were then tabulated in order to highlight the outcomes from individual reports. A meta-analysis was not performed, and individual participant data was not collected.

RESULTS

Literature Search & Screening

An initial search of the PubMed, Embase, and Cochrane databases returned 258 studies, after removing duplicates (Figure 1). Titles and abstracts were initially screened against the inclusion and exclusion criteria, after which 17 studies remained. The full texts of the remaining studies were then screened, where an additional 6 studies were excluded. Data extraction was performed on 11 studies, which comprised 3 prospective cohort studies (Level II evidence), 3 retrospective cohort studies (Level III evidence), 3 case reports (Level IV evidence), and 2 case series (Level IV evidence). All results were reported in conformity with the PRISMA reporting standards.14

Methodological Assessment & Risk of Bias

The included studies were evaluated for methodological quality and risk of bias in accordance with the JBI Critical Appraisal tools for cohort studies, case series, and case reports.15 Three prospective cohort studies16–18 had a mean score of 9.3 out of 11. Three retrospective cohort studies13,19,20 had a mean score of 9.7 out of 11. Three case reports21–23 had a mean score of 8 out of 8. Two case series24,25 had a mean score of 9.5 out of 10. All studies were deemed suitable for inclusion for this review based on the JBI Critical Appraisal tools criteria.

Patient Demographics

The 11 studies included in this review featured a total population of 454 patients, comprised of 343 males (86.2%), 55 females (13.8%), and the remaining unknown due to unclear reporting in one study (Table 1). The weighted average age of the patients in the included studies is 25.84 years, with a range of 15 to 55 years. There was a diverse set of sports reported by the patients, including: volleyball (n=60), soccer (n=49), running (n=45), basketball (n=36), jumping (n=28), sprinting (n=13), body building (n=11), decathlon (n=9), baseball (n=8), javelin/shotput/discus (n=8), football (n=7), tennis (n=5), tennis/squash/ski (n=5), European handball (n=4), gymnastics (n=3), jai alai (n=1), and lacrosse (n=1). Two studies did not quantify the specific sports practiced by participants.16,18 The level of sport was varied and inconsistently reported across studies; therefore, subjects were grouped into elite and non-elite. Elite athletes were defined as athletes who compete professionally or at national levels, while non-elite included all other athletes.11 Five studies provided level of sport data, of which two included elite athletes24,25 and three included non-elite athletes.19,22,23 Six studies did not specify the level of sporting for the participants.

Table 1. Summary of study demographics.

Study LoE N M/F Age (Mean) Sport (n) Level of Sport
Benner (2013)21 Case report (4) 1 1/0 17 Football (1) Unclear
Boublik (2011)24 Case series (4) 2 2/0 Football (2) Elite (2)
Cooper (2000)25 Case series (4) 2 2/0 24 Basketball (1)
Jai Alai (1)		 Elite (2)
Golman (2020)13 Cohort Study, retrospective (3) 56 Unclear 24.9 Unclear Unclear
Kälebo (1991)16 Cohort Study, prospective (2) 81 78/3 28 Unclear Unclear
Karlsson (1991)17 Cohort Study, prospective (2) 78 72/6 25 Soccer (21)
Running (17)
Jumping (12)
Volleyball (7)
Basketball (6)
Tennis (5)
European Handball (4)
Gymnastics (3)		 Unclear
Karlsson (1992)18 Cohort Study, prospective (2) 81 61/20 24 Soccer
Running
Jumping		 Unclear
Pierets (1999)19 Cohort Study, retrospective (3) 26 17/9 31 Soccer (10)
Volleyball (4)
Basketball (4)
Running (3)
Tennis/Squash/Ski (5)		 Non-⁠elite (26)
Raatikainen (1994)20 Cohort Study, retrospective (3) 124 107/17 26.15 Volleyball (46)
Jumping (15)
Sprinting (13)
Running (12)
Decathlon (9)
Javelin/⁠Shotput/⁠Discus (8)
Soccer (6)
Other (15)		 Unclear
Scollon-⁠Grieve (2011)22 Case Report (4) 1 1/0 18 Lacrosse (1) Non-elite (1)
Teran-Vela (2021)23 Case Report (4) 2 2/0 21.5 Basketball (1)
Soccer (1)		 Non-elite (2)
Open in a new tab

Abbreviations: LoE=Level of Evidence, M/F=Male-to-Female ratio, N=number of participants.

Treatment Options & Complications

Both operative and non-operative treatment options were used in the treatment of PPTT injuries (Table 2). A total of 169 patients (37.2%) received only conservative, non-operative treatments.13,16,18,21–23 These regimens included physical therapy, immobilization, shock wave therapy, and/or ultrasound-guided platelet-rich plasma (PRP) injection. Only one study specified the PRP injection type used, the PRO-PRP KIT leukocyte-poor platelet-rich plasma.23 There was no available data in these studies comparing the efficacy of different non-operative treatments. In contrast, a total of 295 (65.0%) of patients were treated surgically.13,16–20,24,25 Most of these patients had undergone surgical repair after failing to improve with conservative management. Surgical approaches generally consisted of debridement only16–20 or debridement with anchors,25 with one study reporting both techniques13 and one study not specifying the technique used.24 Only one study reported surgical complications, where 2 patients developed superficial wound infections.18 Reoperations were reported in 20 patients (6.8%) across several studies. Patients were followed for a mean duration of 55.8 months. Post-operative physical therapy was described in several studies: five studies described progressive range of motion rehabilitation (with or without bracing) followed by isometric and/or isokinetic strengthening exercises,17,18,20,25 one study described isometric strengthening alone,19 and three studies did not elucidate a post-operative physical therapy regimen.13,16,24 One study provided a detailed outline of the physical therapy program used to rehabilitate patients post-operatively: After 4 weeks of immobilization in a long leg cast, patients began a daily training program consisting of progressive overload exercises including knee extension and leg press exercises. The program also included dynamic exercises such as bicycling (50-300 Watts), walking/jogging on soft mattresses, stair/obstacle walking, and (later) jumping activities.18

Table 2. Summary of study findings.

Study N Non-op Tx only Non-op specific Surgical Tx Reop. & Comp. (n) Mean F/U RTS (n) RTS time (months) ROM Other Performance Outcomes
Benner (2013)21 1 1 Immobilization & physical therapy - - 24 mo. 1/1 (100%) 4 Pre-op: 3-0-105
Post-op: 3-0-145

(a-b-c represents a° hyperextension, b° short of 0° extension, c° extension)		 "Excellent subjective function at the collegiate level"

Cybex 180°/sec (PPTT/preop): 54%, 78%, 66% (1 mo., 2 mo., 2 yrs)

Cybex 60°/sec (PPTT/preop): 47%, 86%, 83% (1 mo., 2 mo., 2 yrs)

Noyes Score: 100/100
Boublik (2011)24 2 - - 2 0/2 Unclear - - -
Cooper (2000)25 2 - - 2 0/2 4 mo. 2/2 (100%) 3.5 Post-op: Full ROM compared to contralateral leg 80% strength compared to contralateral leg at 3 mo. after surgery
Golman (2020)13 56 45 Unclear 11 0/11 Unclear 47/56 (83.9%) -
Kälebo (1991)16 81 56 Unclear 25 1/25 (4%) Unclear - - - -
Karlsson (1991)17 78 - - 78 4/78 (5.1%)

Superficial wound infection (2/78, 2.6%)		 5 yrs (2-15 yrs) 71/78 (91.0%) 4 - Lysholm’s knee score: 95 (mean), 74-100
Only non-RTS patients scored < 84.
Karlsson (1992)18 81 64* Physical therapy 27 2/27 (7.4%) 2 yrs Unclear† - - Non-op: 64/91 (70.4%)* "excellent"

Op: 25/27 (92.5%)* "excellent/good"

Blazina Scale: III (pre-op)
Pierets (1999)19 26 - - 26 - 4.2 yrs 23/26

RTS (full): 4/26 (15.8%)

RTS (less intense): 14/26 (52.6%)

Less demanding sport: 5/26 (21%)

No RTS: 3/26 (10.5%)		 6 Normal knee flexion in all patients & symmetric hyperextension: 13/26 (48.5%) Pain free: 4/26 (15.4%)

Pain with rigorous activity: 9/26 (34.6%)

Pain with mild effort: 7/26 (26.9%)

No change: 1/26 (3.8%)

Worse Pain: 5/26 (19.3%)

Other Exam findings:
Tender to palpation: 45.5%
Post-sport swelling: 18.2%
Hypermobile patella: 45%
Pes planus: 27.3%
Genu vara: 18.2%
Raatikainen (1994)20 124 - - 124 13/124 (10.48%) Unclear 119/124 (96.0%) * 3.5 -
Scollon-Grieve (2011)22 1 1 PRP Injection - - 2 mo. 1/1 (100%) 2 - 90% clinical improvement in ultrasound echogenicity & function at 1 mo.

Complete resolution of pain/limitation at 2 mo.
Teran-Vela (2021)23 2 2 PRP Injection (2)
Shock Wave Therapy (1)
High Intensity Laser (1)		 - - Unclear 2/2 (100%) - - VISA-P Scores (mean):
Pre-Tx: 37.5/10
Post-Tx: 89.5/100
Summary: 454 169
(37.22%)		 295
(64.98%)		 20
(6.78%)		 55.78 266
(71.39%)		 3.94
Open in a new tab

Abbreviations: N=number of participants, Non-op=non-operative, Tx=treatment, F/U=Follow-Up, RTS=return to sport, ROM=range of motion.

* reported as number of knees, not number of patients, as some patients were treated for both knees.

† the number of RTS patients is unclear as the paper counted both number of ligaments and number of patients, which differed. This is excluded from the aggregate RTS statistic in the summary row.

Treatment Outcomes & Return to Sport

Return to sport was defined as a return to general sporting activity, irrespective of pre-injury performance level. RTS was seen in 267 patients (92.1%) after PPTT treatment, with an average postoperative time to RTS of 3.9 months (Table 2). A direct comparison of RTS rates between operative and non-operative patients was made in one study, with 7 of 11 (63%) and 40 of 45 (89%) returning to previous levels of activity.13 Three studies19,21,25 included range of motion (ROM) data. In addition, other outcome measures that were available included: Lysholm’s knee score,26 Victorian Institute of Sport Assessment (VISA) score,27 Blazina scale,4 and Cybex II dynamometer measurements.28 One study19 collected data on postoperative pain as compared to the preoperative state, with patients generally reporting improvements in their pain postoperatively.

DISCUSSION

The objective of this systematic review was to evaluate treatment outcomes and RTS in athletes with PPTT injuries. A review of 11 studies found a 92.1% RTS rate in treated patients. On average, athletes were able to RTS after 3.9 months of treatment. Patients who received operative treatment represented 65.0% of the sample, while patients who only received non-operative treatment represented 37.2% of the sample. Many of the operatively treated patients had failed to improve with previous non-operative treatments. Reoperations were reported in 6.8% of cases. On average, the patients were followed for a duration of 55.8 months.

A comparison to full-thickness (“complete”) tears of the patellar tendon reveals that the RTS rate for complete patellar tendon tears is significantly lower, as reported in studies of professional basketball (75%) and football (50%) players.29,30 In non-elite players, one study on complete patellar tendon tears reported a RTS rate of 87%, which was closer to, but still below, the RTS rate we found in PPTTs.31 Similarly, athletes treated for a PPTT showed a higher RTS rate than patients treated for an anterior cruciate ligament (ACL) tear, where RTS rates ranged between 69% and 87%.32–35

Across the studies examined, PPTT treatments generally began with conservative measures, especially physical therapy, immobilization, injections, and symptom management.13,18,21–23 Only one study18 detailed the physical therapy program used for patients; further research is needed to establish a consensus on the best physical therapy protocols. In some of the studies,13,16,18 this conservative approach was insufficient for some patients and resulted in escalation to surgery. This explains the much larger number of operative patients (65.0%) as compared to solely non-operative patients (37.2%). While there are no studies which directly compare the operative and non-operative treatment outcomes, the data from these studies showing that non-operative treatment is insufficient for certain patients suggests that there may be a relationship in the characteristics of a PPTT and the optimal treatment approach.

Golman et al.13 analyzed the relationship between tendon tear thickness and progression to surgery and found that all patients in the study who required surgery had tears of greater than 50% thickness; this suggests that non-operative therapy is less effective for patients with more severe tears and would benefit more from an operative approach. Interestingly, they did not find any correlation between the severity (i.e., size or percentage) of tear and RTS. The data and novel PPTT classification system these authors present may facilitate more uniform and evidence-based treatment approaches; however, further studies are needed in this area.

The reoperation rate for this sample of patients was reasonable in the context of similar knee operations. We reported a reoperation rate of 6.8%, which was slightly lower than the revision rate for ACL reconstructions. Several cohort studies have reported ACL reconstruction revision rates between 7.1% and 16%.35–37 Screw removals and meniscus procedures were the highest represented causes for reoperations and revisions after primary ACL reconstructions.35,36 Similarly, a 9.9% reoperation rate in acute, complete patellar tendon tear reconstructions is lower than our findings for PPTT operations.38 In acute patellar tendon tears, retears, adhesion lysis, and wound debridement represented the most common causes for reoperation.

The studies in this review reported various postoperative RTS times, as shown in Table 2. With a range that varied from 2 months to 6 months, many of the studies framed RTS capability on the basis of individual performance measures. It is important to make considerations for the sport and the level of sport in an athlete when making RTS recommendations. In addition, more objective performance measures are important to guiding RTS. For example, Karlsson et al. (1991) specified “that patients should not return to sports activities until both the quadriceps and hamstring strengths are over 90% of that of the uninjured side.”17 However, the severity of tear may not be a useful factor in making RTS recommendations, as was explained above.

This review was limited primarily by the variety of methods used to measure treatment outcomes. The heterogeneity of available data complicates comparisons across studies. For example, only one study21 provided specific ROM data, while two other studies19,25 provided qualitative comparisons of ROM and strength between injured and non-injured legs. Two studies18,20 reported data as either the number of patients or the number of knees affected, which differed as some patients presented with bilateral injuries. Therefore, many of analyses did not include the total patient population. Another limitation of this review is the lack of individual patient data. Lastly, the treatment outcomes in surgically treated patients may be confounded by differences in surgical techniques, which have likely improved over the 30 years represented in this data.

CONCLUSION

A PPTTs is an injury amongst athletes participating in sports with frequent jumping, such as volleyball or basketball. This systematic review analyzed 454 athletic patients in 11 studies, spanning from 1991 to 2021, and illustrates return to sport rates over 90% following conservative or surgical treatment. Many patients first attempted non-operative treatments and were operated on after failing to improve with prolonged conservative management. The patients who underwent surgical treatment had a lower reoperation rate than comparable surgically treated knee injuries. The high RTS rate and low reoperation rate in surgical cases suggests that current treatment options are satisfactory; however, there is currently little data that directly compares the treatment options to establish a superior treatment modality. While the data we present suggests that current treatment options are largely successful, further comparisons are needed to the most effective treatment options.

Conflict of Interest

None.

AUTHOR CONTRIBUTIONS

Luke A. Sandoval: Conceptualization, Data curation, Formal analysis, Investigation, Methodology, Project administration, Validation, Visualization, Writing – original draft, Writing – review & editing. Charles R. Reiter: Conceptualization, Data curation, Formal analysis, Investigation, Methodology, Project administration, Validation, Visualization, Writing – review & editing. James Satalich: Conceptualization, Investigation, Methodology, Project administration, Supervision, Validation, Writing – review & editing. Conor O’Neill: Conceptualization, Investigation, Methodology, Project administration, Supervision, Validation, Writing – review & editing. John Cyrus: Data curation, Investigation, Methodology, Resources, Software, Writing – review & editing. Robert O’Connell: Conceptualization, Investigation, Methodology, Project administration, Supervision, Validation, Writing – review & editing. Alexander Vap: Conceptualization, Investigation, Methodology, Project administration, Supervision, Validation, Writing – review & editing.

Acknowledgments

Acknowledgments

None.

APPENDIX A: FULL SEARCH STRATEGY

Table A.1. Search Strategy for PubMed (Ovid) on May 1st, 2023.

ID Search Terms Matches
A ((sport OR sports OR athlete OR athletes OR player OR (return[tiab] AND sport[tiab]) OR (return[ot] AND sport[ot]) OR (return[tiab] AND sports[tiab]) OR (return[ot] AND sports[ot]) OR (return[tiab] AND play[tiab]) OR (return[ot] AND play[ot]) OR (return[tiab] AND participation[tiab]) OR (return[ot] AND participation[ot]) OR (return[tiab] AND activity[tiab]) OR (return[ot] AND activity[ot]) OR (return[tiab] AND activities[tiab]) OR (return[ot] AND activities[ot])) OR (("return to"[tiab] OR "returned to"[tiab] OR "recovered function"[tiab] OR "recovery of function"[tiab] OR "continue participation"[tiab] OR "continued participation"[tiab]) AND (sport[tiab] OR sports[tiab] OR athlete[tiab] OR athletes[tiab] OR player[tiab]))) OR ("Sports"[Mesh] OR "Athletes"[Mesh] OR "Return to Sport"[Mesh]) 518179
B ((("patella"[MeSH] OR "Patellar Ligament"[Mesh]) AND "tendon injuries"[MeSH]) AND partial) OR (partial AND (patellar OR patella) AND (tear* OR rupture* OR injur*)) 458
A+B (((sport OR sports OR athlete OR athletes OR player OR (return[tiab] AND sport[tiab]) OR (return[ot] AND sport[ot]) OR (return[tiab] AND sports[tiab]) OR (return[ot] AND sports[ot]) OR (return[tiab] AND play[tiab]) OR (return[ot] AND play[ot]) OR (return[tiab] AND participation[tiab]) OR (return[ot] AND participation[ot]) OR (return[tiab] AND activity[tiab]) OR (return[ot] AND activity[ot]) OR (return[tiab] AND activities[tiab]) OR (return[ot] AND activities[ot])) OR (("return to"[tiab] OR "returned to"[tiab] OR "recovered function"[tiab] OR "recovery of function"[tiab] OR "continue participation"[tiab] OR "continued participation"[tiab]) AND (sport[tiab] OR sports[tiab] OR athlete[tiab] OR athletes[tiab] OR player[tiab]))) OR ("Sports"[Mesh] OR "Athletes"[Mesh] OR "Return to Sport"[Mesh])) AND (((("patella"[MeSH] OR "Patellar Ligament"[Mesh]) AND "tendon injuries"[MeSH]) AND partial) OR (partial AND (patellar OR patella) AND (tear* OR rupture* OR injur*))) 150
Open in a new tab

Table A.2. Search Strategy for Embase (Ovid) on May 1st, 2023.

ID Search Terms Matches
1 exp sport/ or exp return to sport/ or exp athlete/ 253628
2 (sport or sports or athlete or athletes or (return adj3 sport) or (return adj3 play)).mp. 215744
3 (("return to" or "returned to" or (recover* adj3 function) or (continue* adj2 participation) or restore or restoring or postoperative* or post operative* or participation) adj4 (athlete* or sport*)).mp. 18159
4 1 or 2 or 3 324608
5 ((patellar or patella) adj5 (tear* or rupture* or injur*)).mp. 2193
6 (exp patella/ or exp patellar ligament/) and exp tendon injury/ 501
7 partial.mp. 687100
8 5 or 6 2461
9 7 and 8 137
10 4 and 9 37
Open in a new tab

Table A.3. Search Strategy for Cochrane (Ovid) on May 1st, 2023.

ID Search Terms Matches
1 ((sport OR sports OR athlete OR athletes OR player OR (return AND sport) OR (return AND sport) OR (return AND sports) OR (return AND sports) OR (return AND play) OR (return AND play) OR (return AND participation) OR (return AND participation) OR (return AND activity) OR (return AND activity) OR (return AND activities) OR (return AND activities)) OR (("return to" OR "returned to" OR "recovered function" OR "recovery of function" OR "continue participation" OR "continued participation") AND (sport OR sports OR athlete OR athletes OR player))) 42426
2 MeSH descriptor: [Sports] explode all trees 20753
3 MeSH descriptor: [Athletes] explode all trees 1446
4 MeSH descriptor: [Return to Sport] explode all trees 70
5 1 OR 2 OR 3 OR 4 54470
6 (partial AND (patellar OR patella) AND (tear* OR rupture* OR injur*)) 60
7 MeSH descriptor: [Patella] explode all trees 407
8 MeSH descriptor: [Patellar Ligament] explode all trees 214
9 7 OR 8 601
10 MeSH descriptor: [Tendon Injuries] explode all trees 2190
11 9 AND 10 64
12 6 OR 11 124
13 5 AND 12 96
 
Open in a new tab

Funding Statement

This research did not receive any specific grant from funding agencies in the public, commercial, or not-for-profit sectors.

References

  1. Patellar Tendinopathy and Potential Risk Factors: An International Database of Cases and Controls. Morton Sarah, Williams Sean, Valle Xavier, Diaz-Cueli David, Malliaras Peter, Morrissey Dylan. Sep;2017 Clinical Journal of Sport Medicine. 27(5):468–474. doi: 10.1097/jsm.0000000000000397. doi: 10.1097/jsm.0000000000000397. [DOI] [PubMed] [Google Scholar]
  2. Is tendon pathology a continuum? A pathology model to explain the clinical presentation of load-induced tendinopathy. Cook J L, Purdam C R. 2009British Journal of Sports Medicine. 43(6):409–416. doi: 10.1136/bjsm.2008.051193. doi: 10.1136/bjsm.2008.051193. [DOI] [PubMed] [Google Scholar]
  3. Revisiting the continuum model of tendon pathology: what is its merit in clinical practice and research? Cook J L, Rio E, Purdam C R, Docking S I. Apr 28;2016 British Journal of Sports Medicine. 50(19):1187–1191. doi: 10.1136/bjsports-2015-095422. doi: 10.1136/bjsports-2015-095422. [DOI] [PMC free article] [PubMed] [Google Scholar]
  4. Jumper's knee. Blazina Martin E., Kerlan Robert K., Jobe Frank W., Carter Vincent S., Carlson G. Joanne. Jul;1973 Orthopedic Clinics of North America. 4(3):665–678. doi: 10.1016/s0030-5898(20)32343-9. doi: 10.1016/s0030-5898(20)32343-9. [DOI] [PubMed] [Google Scholar]
  5. Epidemiology of Patellar Tendinopathy in Elite Male Soccer Players. Hägglund Martin, Zwerver Johannes, Ekstrand Jan. Jun 3;2011 The American Journal of Sports Medicine. 39(9):1906–1911. doi: 10.1177/0363546511408877. doi: 10.1177/0363546511408877. [DOI] [PubMed] [Google Scholar]
  6. Prevalence of Jumper's Knee among Elite Athletes from Different Sports: A Cross-sectional Study. Lian Østein B., Engebretsen Lars, Bahr Roald. Apr;2005 The American Journal of Sports Medicine. 33(4):561–567. doi: 10.1177/0363546504270454. doi: 10.1177/0363546504270454. [DOI] [PubMed] [Google Scholar]
  7. Prevalence of Jumper’s Knee Among Nonelite Athletes From Different Sports: A Cross-Sectional Survey. Zwerver Johannes, Bredeweg Steven W., Van Den Akker-Scheek Inge. Jul 7;2011 The American Journal of Sports Medicine. 39(9):1984–1988. doi: 10.1177/0363546511413370. doi: 10.1177/0363546511413370. [DOI] [PubMed] [Google Scholar]
  8. Characteristics of the Leg Extensors in Male Volleyball Players with Jumper's Knee. Lian Øystein, Engebretsen Lars, Øvrebø Rune V., Bahr Roald. May;1996 The American Journal of Sports Medicine. 24(3):380–385. doi: 10.1177/036354659602400322. doi: 10.1177/036354659602400322. [DOI] [PubMed] [Google Scholar]
  9. Performance Characteristics of Volleyball Players with Patellar Tendinopathy. Lian Øystein, Refsnes Per-Egil, Engebretsen Lars, Bahr Roald. Mar;2003 The American Journal of Sports Medicine. 31(3):408–413. doi: 10.1177/03635465030310031401. doi: 10.1177/03635465030310031401. [DOI] [PubMed] [Google Scholar]
  10. Patellar Tendinopathy: Diagnosis and Treatment. Figueroa David, Figueroa Francisco, Calvo Rafael. Dec;2016 Journal of the American Academy of Orthopaedic Surgeons. 24(12):e184–e192. doi: 10.5435/jaaos-d-15-00703. doi: 10.5435/jaaos-d-15-00703. [DOI] [PubMed] [Google Scholar]
  11. Epidemiology of Patellar Tendinopathy in Athletes and the General Population: A Systematic Review and Meta-analysis. Nutarelli Sebastiano, Lodi Camilla Mondini Trissino Da, Cook Jill L., Deabate Luca, Filardo Giuseppe. Jun 1;2023 Orthopaedic Journal of Sports Medicine. 11(6):232596712311736. doi: 10.1177/23259671231173659. doi: 10.1177/23259671231173659. [DOI] [PMC free article] [PubMed] [Google Scholar]
  12. Intrinsic Risk Factors for the Development of Patellar Tendinitis in an Athletic Population: A Two-Year Prospective Study. Witvrouw Erik, Bellemans Johan, Lysens Roeland, Danneels Lieven, Cambier Dirk. Mar;2001 The American Journal of Sports Medicine. 29(2):190–195. doi: 10.1177/03635465010290021201. doi: 10.1177/03635465010290021201. [DOI] [PubMed] [Google Scholar]
  13. Rethinking Patellar Tendinopathy and Partial Patellar Tendon Tears: A Novel Classification System. Golman Mikhail, Wright Margaret L., Wong Tony T., Lynch T. Sean, Ahmad Christopher S., Thomopoulos Stavros, Popkin Charles A. Jan 8;2020 The American Journal of Sports Medicine. 48(2):359–369. doi: 10.1177/0363546519894333. doi: 10.1177/0363546519894333. [DOI] [PubMed] [Google Scholar]
  14. The PRISMA 2020 statement: an updated guideline for reporting systematic reviews. Page Matthew J, McKenzie Joanne E, Bossuyt Patrick M, Boutron Isabelle, Hoffmann Tammy C, Mulrow Cynthia D, Shamseer Larissa, Tetzlaff Jennifer M, Akl Elie A, Brennan Sue E, Chou Roger, Glanville Julie, Grimshaw Jeremy M, Hróbjartsson Asbjørn, Lalu Manoj M, Li Tianjing, Loder Elizabeth W, Mayo-Wilson Evan, McDonald Steve, McGuinness Luke A, Stewart Lesley A, Thomas James, Tricco Andrea C, Welch Vivian A, Whiting Penny, Moher David. Mar 29;2021 BMJ. :n71. doi: 10.1136/bmj.n71. doi: 10.1136/bmj.n71. [DOI] [PMC free article] [PubMed]
  15. Moola S, Munn Z, Tufanaru C, et al. In: JBI Manual for Evidence Synthesis. Aromataris E, Munn Z, editors. JBI; Chapter 7: Systematic reviews of etiology and risk. [DOI] [Google Scholar]
  16. Ultrasonography in the detection of partial patellar ligament ruptures (jumper's knee) Kälebo Peter, Swärd Leif, Karlsson Jon, Peterson Lars. May;1991 Skeletal Radiology. 20(4):285–289. doi: 10.1007/bf02341668. doi: 10.1007/bf02341668. [DOI] [PubMed] [Google Scholar]
  17. Partial rupture of the patellar ligament: Results after operative treatment. Karlsson Jon, Lundin Olof, Lossing Ingrid Wigerstad, Peterson Lars. Jul;1991 The American Journal of Sports Medicine. 19(4):403–408. doi: 10.1177/036354659101900415. doi: 10.1177/036354659101900415. [DOI] [PubMed] [Google Scholar]
  18. Partial rupture of the patellar ligament. Karlsson Jon, Kälebo Peter, Goksör Lars-Ake, Thomee Roland, Swärd Leif. Jul;1992 The American Journal of Sports Medicine. 20(4):390–395. doi: 10.1177/036354659202000404. doi: 10.1177/036354659202000404. [DOI] [PubMed] [Google Scholar]
  19. Jumper's knee: postoperative assessment. Pierets K., Verdonk R., De Muynck M., Lagast J. Jul 26;1999 Knee Surgery, Sports Traumatology, Arthroscopy. 7(4):239–242. doi: 10.1007/s001670050155. doi: 10.1007/s001670050155. [DOI] [PubMed] [Google Scholar]
  20. Operative Treatment of Partial Rupture of the Patellar Ligament. Raatikainen T., Karpakka J., Puranen J., Orava S. Jan;1994 International Journal of Sports Medicine. 15(01):46–49. doi: 10.1055/s-2007-1021019. doi: 10.1055/s-2007-1021019. [DOI] [PubMed] [Google Scholar]
  21. Nonoperative Management of a Partial Patellar Tendon Rupture after Bone-Patellar Tendon-Bone Graft Harvest for ACL Reconstruction. Benner Rodney, Freeman Heather, Shelbourne K. 2013Journal of Knee Surgery. 26(S 01):S123–S127. doi: 10.1055/s-0032-1324810. doi: 10.1055/s-0032-1324810. [DOI] [PubMed] [Google Scholar]
  22. Platelet-Rich Plasma Injection for Partial Patellar Tendon Tear in a High School Athlete: A Case Presentation. Scollon-Grieve Kelly L., Malanga Gerard A. Apr;2011 PM. 3(4):391–395. doi: 10.1016/j.pmrj.2010.11.008. doi: 10.1016/j.pmrj.2010.11.008. [DOI] [PubMed] [Google Scholar]
  23. Patellar tendon rupture after radial pressure wave therapy – also known as radial shock wave therapy – for patellar tendinopathy: Report of two Cases. Insuasti Abarca Walter, Llocclla Delgado Sussan, Terán Vela Paul, Platero Portillo Tania, Martínez Asnalema Diana, Abarca García Lilian. Mar 15;2021 Revista de la Facultad de Medicina Humana. 21(2):449–458. doi: 10.25176/rfmh.v21i2.3621. doi: 10.25176/rfmh.v21i2.3621. [DOI] [Google Scholar]
  24. Patellar Tendon Ruptures in National Football League Players. Boublik Martin, Schlegel Theodore, Koonce Ryan, Genuario James, Lind Charles, Hamming David. Aug 2;2011 The American Journal of Sports Medicine. 39(11):2436–2440. doi: 10.1177/0363546511417083. doi: 10.1177/0363546511417083. [DOI] [PubMed] [Google Scholar]
  25. Partial Rupture of the Distal Insertion of the Patellar Tendon: A Report of Two Cases in Professional Athletes. Cooper Mitchell E., Selesnick F. Harlan. May;2000 The American Journal of Sports Medicine. 28(3):402–406. doi: 10.1177/03635465000280032101. doi: 10.1177/03635465000280032101. [DOI] [PubMed] [Google Scholar]
  26. Evaluation of knee ligament surgery results with special emphasis on use of a scoring scale. Lysholm Jack, Gillquist Jan. May;1982 The American Journal of Sports Medicine. 10(3):150–154. doi: 10.1177/036354658201000306. doi: 10.1177/036354658201000306. [DOI] [PubMed] [Google Scholar]
  27. The VISA score: An index of severity of symptoms in patients with jumper's knee (patellar tendinosis) Visentini Paul J, Khan Karim M, Cook Jill L, Kiss Zoltan S, Harcourt Peter R, Wark John D. Jan;1998 Journal of Science and Medicine in Sport. 1(1):22–28. doi: 10.1016/s1440-2440(98)80005-4. doi: 10.1016/s1440-2440(98)80005-4. [DOI] [PubMed] [Google Scholar]
  28. Cybex Isolated-Joint Testing, and Exercise: A Handbook for Using Cybex® II and the UBXT™; Ronkonkoma, NY. Ronkonkoma, NY: Cybex, Division of Lumex Inc.; [Google Scholar]
  29. The NFL Orthopaedic Surgery Outcomes Database (NO-SOD): The Effect of Common Orthopaedic Procedures on Football Careers. Mai Harry T., Alvarez Andrew P., Freshman Ryan D., Chun Danielle S., Minhas Shobhit V., Patel Alpesh A., Nuber Gordon W., Hsu Wellington K. Jul 20;2016 The American Journal of Sports Medicine. 44(9):2255–2262. doi: 10.1177/0363546516651426. doi: 10.1177/0363546516651426. [DOI] [PubMed] [Google Scholar]
  30. A Comprehensive Return-to-Play Analysis of National Basketball Association Players With Operative Patellar Tendon Tears. Nguyen Michael V., Nguyen John V., Taormina David P., Pham Hien, Alaia Michael J. Oct;2018 Orthopaedic Journal of Sports Medicine. 6(10):232596711880047. doi: 10.1177/2325967118800479. doi: 10.1177/2325967118800479. [DOI] [PMC free article] [PubMed] [Google Scholar]
  31. Acute traumatic patellar tendon rupture: Early and late results of surgical treatment of 38 cases. Roudet A., Boudissa M., Chaussard C., Rubens-Duval B., Saragaglia D. May;2015 Orthopaedics & Traumatology: Surgery & Research. 101(3):307–311. doi: 10.1016/j.otsr.2014.12.017. doi: 10.1016/j.otsr.2014.12.017. [DOI] [PubMed] [Google Scholar]
  32. Return to Sport After ACL Reconstruction With a BTB Versus Hamstring Tendon Autograft: A Systematic Review and Meta-analysis. DeFazio Matthew W., Curry Emily J., Gustin Michael J., Sing David C., Abdul-Rassoul Hussein, Ma Richard, Fu Freddie, Li Xinning. Dec 1;2020 Orthopaedic Journal of Sports Medicine. 8(12):232596712096491. doi: 10.1177/2325967120964919. doi: 10.1177/2325967120964919. [DOI] [PMC free article] [PubMed] [Google Scholar]
  33. Eighty-three per cent of elite athletes return to preinjury sport after anterior cruciate ligament reconstruction: a systematic review with meta-analysis of return to sport rates, graft rupture rates and performance outcomes. Lai Courtney C H, Ardern Clare L, Feller Julian A, Webster Kate E. 2018British Journal of Sports Medicine. 52(2):128–138. doi: 10.1136/bjsports-2016-096836. doi: 10.1136/bjsports-2016-096836. [DOI] [PubMed] [Google Scholar]
  34. Return to Play and Patient Satisfaction After ACL Reconstruction: Study with Minimum 2-Year Follow-up. Nwachukwu Benedict U., Voleti Pramod B., Berkanish Patricia, Chang Brenda, Cohn Matthew R., Williams Riley J., Allen Answorth A. May 3;2017 Journal of Bone and Joint Surgery. 99(9):720–725. doi: 10.2106/jbjs.16.00958. doi: 10.2106/jbjs.16.00958. [DOI] [PubMed] [Google Scholar]
  35. Patient-Reported Outcome, Return to Sport, and Revision Rates 7-9 Years After Anterior Cruciate Ligament Reconstruction: Results From a Cohort of 2042 Patients. Randsborg Per-Henrik, Cepeda Nicholas, Adamec Dakota, Rodeo Scott A., Ranawat Anil, Pearle Andrew D. Jan 18;2022 The American Journal of Sports Medicine. 50(2):423–432. doi: 10.1177/03635465211060333. doi: 10.1177/03635465211060333. [DOI] [PMC free article] [PubMed] [Google Scholar]
  36. One sixth of primary anterior cruciate ligament reconstructions may undergo reoperation due to complications or new injuries within 2 years. Lord Lise, Cristiani Riccardo, Edman Gunnar, Forssblad Magnus, Stålman Anders. Jun 29;2020 Knee Surgery, Sports Traumatology, Arthroscopy. 28(8):2478–2485. doi: 10.1007/s00167-020-06127-w. doi: 10.1007/s00167-020-06127-w. [DOI] [PMC free article] [PubMed] [Google Scholar]
  37. Failure and Reoperation Rates Following Arthroscopic Primary Repair Versus Reconstruction of the Anterior Cruciate Ligament. Van Der List Jelle P., Jonkergouw Anne, DiFelice Gregory S. Jul;2019 Orthopaedic Journal of Sports Medicine. 7(7_suppl5):2325967119S0029. doi: 10.1177/2325967119s00297. doi: 10.1177/2325967119s00297. [DOI] [Google Scholar]
  38. Operative Treatment of Acute Patellar Tendon Ruptures. O’Dowd James A., Lehoang David M., Butler Rebecca R., Dewitt David O., Mirzayan Raffy. Aug 6;2020 The American Journal of Sports Medicine. 48(11):2686–2691. doi: 10.1177/0363546520943879. doi: 10.1177/0363546520943879. [DOI] [PubMed] [Google Scholar]

Articles from Orthopedic Reviews are provided here courtesy of Open Medical Publishing

RESOURCES