Abstract
Objective
This study aimed to investigate the clinical efficacy of closed reduction high-strength sutures combined with Nice knots in treating transverse patella fractures.
Method
We retrospectively analyzed the clinical data of 28 patients who underwent surgery for transverse patella fractures from January 2019 to January 2020. Twelve cases of the study group were treated with closed reduction high-strength sutures combined with Nice knots, and 16 cases in the control group were treated with tension band wiring. Observations included patellar healing, follow-up knee mobility with Böstman score, Lysholm score, surgical data, postoperative complications, and secondary surgery rate.
Result
No statistically significant difference was observed between the two groups in the Patient demographic data, with a mean follow-up of 13.14 ± 1.58 months. There was no delayed healing or deep infection in the two groups. In the control group, 2 cases of internal fixation failure and 1 case of superficial infection were observed. The differences in mean fracture healing time, follow-up Böstman score, Lysholm score and knee mobility between the two groups were not statistically different. However, the differences were statistically significant for the duration of surgery, Incision length, intraoperative bleeding and the secondary surgery rate was lower in the study group.
Conclusion
Closed reduction high-strength sutures have good clinical efficacy in treating transverse patella fractures, with the advantages of shorter duration of surgery and Incision length,less intraoperative bleeding and no secondary removal.
Similar content being viewed by others
Avoid common mistakes on your manuscript.
Introduction
The incidence of patellar fractures is approximately 1% [1] and approximately 70–90% are transverse fractures [2]. A patellar fracture directly affects the knee extension device; an uneven joint surface may lead to osteoarthritis[3]. Therefore, tension band wiring (TBW) is probably the most commonly used and effective surgical method[4, 5]. Still, inevitably, it has the disadvantages of protruding discomfort[6], soft tissue irritation[7], and the need for secondary surgical removal[8]. We used a closed repositioning method combined with high-strength sutures to overcome the problem of protruding implants without affecting stable fixation. We achieved remarkable results, which are summarized below.
Materials and Methods
General Information
After obtaining approval from the institutional ethical review committee, 28 patients with patella fracture 34-C1 admitted to the Department of Traumatic Orthopedics at our institution from January 2019 to January 2020 were retrospectively analyzed. Among them, 16 cases were in the Tension band wiring group; and 12 were in the high-strength sutures (HS) group.
Inclusion criteria: (1) closed transverse patellar fracture (AO/ATO 34 C1); (2) normal knee function before injury (3) age ≥ 18 years and ≤ 70 years. (4) Signed informed consent.
Exclusion criteria: (1) comminuted patellar fracture, (2) multiple fractures or injuries, (3) combined peripheral neurovascular injury, (4) inability to cooperate with follow-up or missing relevant information.
All patients provided written informed consent before the study. In addition, all patients were informed preoperatively about the minimally invasive treatment modality using closed reduction. They were duly informed about the possibility of using incisional reduction. Patients gave their informed consent and signed the informed consent form.
Surgical Techniques
Preoperative Preparation
The patients were admitted to the hospital and externally immobilized with a plaster rest under extension on the same day. Preoperative prophylactic medication against VTE was routinely applied.
Anesthesia and Position
Subarachnoid block anesthesia or combined epidural anesthesia was selected, and the patients were placed in the supine position on the surgical bed.
Surgical Procedure
Combined lumbar and rigid or general anesthesia was chosen. Patients were placed in the supine position, and the part was disinfected and toweled.
HS Group
After repositioning the patella according to the patellofemoral joint surface closure, two scarf clamps or repositioning forceps were used on both sides of the patella to maintain the repositioning. Then two or three 1.5 or 2.0 mm clincher pins were placed percutaneously in the parallel longitudinal direction as temporary fixation. Next, two lateral and two medial incisions were made on each side of the patella at the superior and inferior patellar poles, respectively. Next, through four small incisions, the Ultrabraid NO.2 (Smith & Nephew, USA) was looped and "8" fixed, superiorly through the quadriceps; inferiorly through the inferior pole of the patella. Finally, the Nice knot was tied in the patellar epiphysis and embedded in soft tissue. Next, the kyphosis pin was pulled out in sequence, and the knot was then tied longitudinally through the bone tunnel through the skin and tightened using Nice. After bone fixation was completed, intraoperative fixation stability was assessed by flexing the knee to 90 degrees. The incision was finally sutured and bandaged.
TBW Group
A longitudinal incision was made in the anterior median of the knee, starting 2 cm proximal to the superior border of the patella and ending at the superior border of the tibial tuberosity. The skin and subcutaneous tissue were retracted to expose the patella. The fracture line was cleared of blood clots and embedded soft tissues. The wound and joint surface were thoroughly irrigated. The fracture block was fixed with a scarf clamp or repositioning forceps. The joint surface was flattened by lateral fluoroscopy with a C-arm machine. The superior and inferior fractures were fixed longitudinally with 1.5 or 2.0 mm diameter kerf pins through the patella. Then, 1 to 2, 0.8 mm diameter stainless steel sutures with stitches was tightened against the patella's superior and inferior pole to form an "8" tension band. After flexing the knee joint to confirm the fixation stability, the wound was irrigated and closed by layer, and drainage strips were placed.
Postoperative Management
Patients in both groups received the same postoperative rehabilitation program. Patients performed active quadriceps, ankle, toe flexion, and extension functional exercises two days postoperatively. Afterward, patients were instructed to perform passive knee flexion and extension exercises post-surgery. Partial weight-bearing was acceptable starting on postoperative day 3. When the fracture was radiologically healed, full weight-bearing was allowed. Radiographs were reviewed 2, 4, 8, 12 weeks, and 6 months after surgery for fracture healing and to assess the function of the affected limb.
Evaluation Index
Comparison of the duration of surgery, secondary surgery rate, incision length, complication rate, Böstman score [9], Lysholm score and knee mobility was performed between the two groups. Fracture healing time was determined by imaging data combined with clinical data.
Statistical Analysis
SPSS 24.0 statistical software (IBM, Armonk, NY, USA) was used to statistically analyze the data. The measurement data were expressed as mean ± standard deviation to compare the demographic data (age, gender, type of injury and more), surgical data (duration of surgery, incision length, Intraoperative bleeding), and postoperative-related clinical data (complication rate, Böstman score, Lysholm score,and knee mobility). Categorical variables were expressed as frequencies or percentages, and continuous variables were expressed as mean ± SD. When the continuous variables were normally distributed, an independent sample t test was used to determine the differences between the two groups. Otherwise, nonparametric tests were performed for comparison. Categorical variables were compared using the Pearson chi-square test or Fisher's exact probability method. The postoperative Knee mobility and the functional knee scores were assessed using repeated measures analysis of variance in all statistical analyses. A value of p < 0.05 was considered statistically significant.
Result
All 28 patients were healed till the last follow-up, with an average age of 56.32 ± 7.77 years and a follow-up of 13.14 ± 1.58 months. No significant difference was observed in patient demographic data between the two groups (Table 1).
Comparison of Surgical Data, Complications, and Postoperative Function
The suture group outperformed the TBW group in terms of operative time (61.25 ± 9.80 vs. 76.56 ± 22.11, p = 0.022), incision length (3.08 ± 1.00 vs. 9.94 ± 1.24, p < 0.001), and secondary surgery rate (0 vs. 7, p = 0.024). The difference was statistically significant. (Table 2).
Two cases (12.5%) of superficial infection and one case (6.25%) of internal fixation failure occurred in the TBW group, while none occurred in the super suture group. However, both groups detected lower extremity venous thrombosis in two cases Fig. 1. The difference in complications between the two groups was not statistically significant. (Table 2).
The results showed that the time effect was statistically significant (p < 0.001); No significant difference was observed in the impact of different treatment methods on functional recovery (p > 0.05). No significant difference was found in Knee mobility, Lysholm score, or Böstman score in the two groups at the 1-, 3-, 6-, or 12-month follow-ups (P > 0.05) (Table 3).
Discussion
Recently, high-strength sutures have been used as a substitute for metallic materials and have achieved good clinical results. These results were obtained by Chen et al.[10] using braided polyester sutures (braided polyester) for patella fracture fixation. They conducted a matched historical control study and found no significant difference in healing and operative time compared to the wire tension band. However, the mean number of hospital days (4.04 ± 1.40 vs. 5.76 ± 1.50), number of procedures, and complication rate were significantly lower for nonmetallic fixation. We used the polyethylene braided material Ultrabraid NO.2 suture for internal fixation. The results of the mechanical comparison by Wüst et al. [11] showed that the difference in strength between Ultrabraid and FiberWire sutures was not significantly different without knots. In contrast, Ultrabraid (244 N) had better results with knots than FiberWire (189 N). Our study showed similar findings to these previous results. In our study, no significant difference was observed in healing time, final Böstman score, and knee mobility between the two groups compared to wire tension band wiring. While the differences in operation time, incision length, intraoperative bleeding, and secondary operation rate were statistically significant.
We used the NICE knot to maximize the tension of the seam, as the NICE knot is used in various applications [12]. In-vitro biomechanical analysis by Patel et al.[13] Showed the efficacy of non-metallic materials for the fixation of patella fractures comparable to other metallic materials using special knotting techniques. Further, Meyer et al. [14] tested 12 different knots and found that NICE knots had excellent mechanical strength. It provides a sliding locking feature besides performs well in preventing knot slippage. Thus, overcoming the difficulty of maintaining compression force in general surgical knots [15, 16].
Compared to the previous surgical approach, we used percutaneous sutures. Ma et al. [17] used percutaneous ring ligation to treat patellar fractures and obtained excellent reduction and functional results in 102 of 107 patients. Rathi et al. [18] treated 23 patients with transverse patellar fractures using a percutaneous keratomic pin tension band, where only 3 closed repositioning cases failed. The authors attribute this failure to the missed diagnosis of 2 cases of comminuted fractures and 1 case of small distal fracture. The remaining patients had radiographic healing at 8 weeks, and only one developed knee-femoral arthritis. Based on our previous experience, simple patella fractures can be treated by closed reduction. Therefore, a strict grasp of the fracture type may be the key to performing a good closed reduction. Furthermore, in cases where closed repositioning is not possible, a timely change to incisional repositioning is a wiser option. Although the differences in incision length and operative time were statistically significant in our study, the suture group (0 cases) performed better overall than the wire group (2 cases) in terms of postoperative infection control. However, the differences were not statistically significant, which may be attributed due to the small sample size.
Our study had some limitations. First, we conducted a retrospective cohort study with low evidence. Meanwhile, our small sample size and the short follow-up period lacked long-term efficacy evaluation. More high-quality, double-blind, randomized controlled trials with a larger number of cases are required to validate the advantages of the closed nonmetallic suture technique.
References
Melvin, J. S., & Mehta, S. (2011). Patellar fractures in adults. Journal of American Academy of Orthopaedic Surgeons, 19(4), 198–207.
Yin, Z., Yan, J., Ge, D., Yang, L., Liang, B., & Fei, J. (2021). Comparison of double-strand braided polyester sutures tension band (Nice knot) with cable tension band in transverse patellar fractures. Injury, 52(10), 3085–3090.
Henrichsen, J. L., Wilhem, S. K., Siljander, M. P., Kalma, J. J., & Karadsheh, M. S. (2018). Treatment of Patella Fractures. Orthopedics, 41(6), e747–e755.
Adjal, J., & Ban, I. (2021). Patella fractures treated with suture tension band fixation. Journal of Orthopaedic Surgery and Research, 16(1), 179.
Gwinner, C., Mardian, S., Schwabe, P., Schaser, K. D., Krapohl, B. D., & Jung, T. M. (2016). Current concepts review: Fractures of the patella. GMS Interdiscip Plast Reconstr Surg., 5, 01.
Lefaivre, K. A., O’Brien, P. J., Broekhuyse, H. M., Guy, P., & Blachut, P. A. (2010). Modified tension band technique for patella fractures. Orthopaedics Traumatol, 96(5), 579–582.
Hoshino, C. M., Tran, W., Tiberi, J. V., Black, M. H., Li, B. H., Gold, S. M., et al. (2013). Complications following tension-band fixation of patellar fractures with cannulated screws compared with Kirschner wires. The Journal of Bone and Joint Surgery, 95(7), 653–659.
Kumar, G., Mereddy, P. K., Hakkalamani, S., & Donnachie, N. J. (2010). Implant removal following surgical stabilization of patella fracture. Orthopedics, 12, 33.
Böstman, O., Kiviluoto, O., & Nirhamo, J. (1981). Comminuted displaced fractures of the patella. Injury, 13(3), 196–202.
Chen, C. H., Huang, H. Y., Wu, T., & Lin, J. (2013). Transosseous suturing of patellar fractures with braided polyester - a prospective cohort with a matched historical control study. Injury, 44(10), 1309–1313.
Wüst, D. M., Meyer, D. C., Favre, P., & Gerber, C. (2006). Mechanical and handling properties of braided polyblend polyethylene sutures in comparison to braided polyester and monofilament polydioxanone sutures. Arthroscopy, 22(11), 1146–1153.
Boileau, P., Alami, G., Rumian, A., Schwartz, D. G., Trojani, C., & Seidl, A. J. (2017). The Doubled-Suture Nice Knot. Orthopedics, 40(2), e382–e386.
Patel, V. R., Parks, B. G., Wang, Y., Ebert, F. R., & Jinnah, R. H. (2000). Fixation of patella fractures with braided polyester suture: A biomechanical study. Injury, 31(1), 1–6.
Chakrabarti, D., Thokur, N., & Ajnin, S. (2019). Cable platefixation for Vancouver Type-B1 periprosthetic femoral fractures-Our experience and identification of a subset at risk of non-union. Injury, 50, 2301–2305.
Collin, P., Laubster, E., Denard, P. J., Akuè, F. A., & Lädermann, A. (2016). The Nice knot as an improvement on current knot options: A mechanical analysis. Orthopaedics Traumatol, Surg Res, 102(3), 293–296.
Hughes, S. C., Stott, P. M., Hearnden, A. J., & Ripley, L. G. (2007). A new and effective tension-band braided polyester suture technique for transverse patellar fracture fixation. Injury, 38(2), 212–222.
Ma, Y. Z., Zhang, Y. F., Qu, K. F., & Yeh, Y. C. (1984). Treatment of fractures of the patella with percutaneous suture. Clinical Orthopaed Related Res, 191, 235–241.
Rathi, A., Swamy, M. K., Prasantha, I., Consul, A., Bansal, A., & Bahl, V. (2012). Percutaneous tension band wiring for patellar fractures. J Orthopaedic Surgery, 20(2), 166–169.
Funding
None.
Author information
Authors and Affiliations
Corresponding author
Ethics declarations
Conflict of interest
None.
Ethical Approval
This article does not contain any studies with human or animal subjects performed by any of the authors.
Informed Consent
For this type of study informed consent is not required.
Additional information
Publisher's Note
Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Rights and permissions
Open Access This article is licensed under a Creative Commons Attribution 4.0 International License, which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons licence, and indicate if changes were made. The images or other third party material in this article are included in the article's Creative Commons licence, unless indicated otherwise in a credit line to the material. If material is not included in the article's Creative Commons licence and your intended use is not permitted by statutory regulation or exceeds the permitted use, you will need to obtain permission directly from the copyright holder. To view a copy of this licence, visit http://creativecommons.org/licenses/by/4.0/.
About this article
Cite this article
Huang, L., Li, X., Ye, L. et al. Closed Reduction and High-Strength Sutures for Transverse Patella Fractures: A Retrospective Analysis. JOIO 57, 571–576 (2023). https://doi.org/10.1007/s43465-023-00843-4
Received:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s43465-023-00843-4