Tag Archives: Total knee replacement
Gender-Specific Knee Anthropometry and Its Impact on Total Knee Implant Design
Vol 8 | Issue 2 | July-December 2022 | page: 01-04 | Pavan Soni, Parag Sancheti, Kailas Patil, Sunny Gugale, Sahil Sanghavi, Yogesh Sisodia, Obaid UI Nisar, Darshan Sonawane, Ashok Shyam
https://doi.org/10.13107/jmt.2022.v08.i02.182
Author: Pavan Soni [1], Parag Sancheti [1], Kailas Patil [1], Sunny Gugale [1], Sahil Sanghavi [1], Yogesh Sisodia [1], Obaid UI Nisar [1], Darshan Sonawane [1], Ashok Shyam [1]
[1] Department of Orthopaedics, Sancheti Institute of Orthopaedics and Rehabilitation, Pune, Maharashtra, India.
Address of Correspondence
Dr. Darshan Sonawane,
Department of Orthopaedics, Sancheti Institute of Orthopaedics and Rehabilitation, Pune, Maharashtra, India.
E-mail: researchsior@gmail.com
Abstract
Background: Good results after total knee replacement depend on choosing components that match the patient’s bone shape. Many implants were designed from Western measurements and can fit poorly in other populations, producing mediolateral overhang or undersizing that may cause discomfort or altered load transfer. This study reports direct intraoperative measurements from an Indian cohort to highlight common fit problems.
Methods and materials: Using a sterile calibrated caliper, standardized measurements were taken during primary total knee arthroplasty on 252 knees (May 2017–May 2020). Recorded parameters included lateral and medial femoral anteroposterior lengths, femoral mediolateral width, tibial plateau AP and ML dimensions, and patellar thickness. Every reading was double-checked by the assisting resident. Data were grouped by gender and implant system (Zimmer, Indus) and used to calculate ML/AP aspect ratios, which were then compared with the manufacturers’ size charts present in the thesis.
Results: The cohort showed a clear trend: ML/AP aspect ratio decreased as AP size increased. Smaller knees frequently faced mediolateral undercoverage with available components, while larger knees were more likely to show ML overhang. Overall, the Indus system tended to match the measured dimensions more closely than Zimmer, although some male tibial fits remained imperfect.
Conclusion: Local intraoperative anthropometry reveals predictable mismatches between Indian knee geometry and some implant offerings. Practical steps—choosing systems that better match local anatomy and adopting finer sizing, staged aspect-ratio changes, or asymmetric trays—can reduce intraoperative compromise and improve early comfort.
Keywords: Total knee replacement, Anthropometry, Aspect ratio, Implant fit, Indian population.
Introduction
Successful total knee replacement depends on restoring joint balance and geometry so the replacement behaves as close to a native knee as possible. Choosing the right component size is not a purely technical step — it shapes soft-tissue tension, patellar tracking, and how loads pass through bone and implant for years to come. When component shape or sizing does not reflect a patient’s anatomy, surgeons are forced into compromises: an implant that overhangs mediolaterally can irritate soft tissues and cause persistent discomfort, while one that is too small can expose cancellous bone and change load paths, with potential long-term consequences [1]. Historically, many common prosthesis families were developed using Western anthropometry, which may not match the body proportions seen in other populations [2, 3]. Regional measurement studies and intraoperative series therefore play a practical role — they give surgeons and manufacturers the data needed to reduce mismatch and make better sizing choices for local patients [4]. Pediatric development patterns and normative range-of-motion work also help set realistic functional goals after arthroplasty and contextualize adult dimensions for templating and expectation management [5, 6]. The present intraoperative dataset from this thesis gives direct, surgeon-facing measurements that inform component selection and suggest straightforward, affordable design changes that can reduce routine compromise in Indian patients.
Aims & Objectives
1. Record standardized intraoperative measurements of the distal femur and proximal tibia in patients undergoing primary total knee arthroplasty.
2. Calculate femoral and tibial aspect ratios and document condylar asymmetries and patellar thickness.
3. Compare patient-derived dimensions with size offerings of two implant systems used in the cohort (Zimmer and Indus).
4. Identify recurrent patterns of mismatch and outline pragmatic implications for implant selection and modest manufacturer adaptations.
Review of Literature
Anthropometric and morphometric research consistently shows that knee shape differs across ethnic groups and sexes, and those differences matter for implant fit. Several studies comparing resected bone or imaging-based knee measurements with implant dimensions reported that populations with smaller average stature often face systematic mismatch when Western-derived implants are used without adaptation [7–9]. More sophisticated three-dimensional CT analyses and intraoperative series from East and Southeast Asia have repeatedly noted a practical pattern: the mediolateral-to-anteroposterior (ML/AP) aspect ratio tends to decline as AP dimension increases. In plain terms, larger knees do not increase ML width as fast as AP length, so implants with constant aspect ratios across sizes will either overhang or under-cover depending on the surgeon’s size choice [10–12]. Sex differences add another layer: females often have relatively narrower femora for a given AP height, which raises the risk of ML overhang when selection relies on AP measures alone [13, 14]. Industry responses have included gender-targeted components, asymmetric tibial trays and finer size increments, but randomized clinical data on the functional benefits of gendered implants are mixed and patient-specific solutions remain expensive and logistically demanding [15,16]. As a practical middle path, many authors advocate collecting local intraoperative data, offering finer size gradations and designing staged aspect ratios rather than a single constant ratio across all sizes; these measures can substantially reduce intraoperative compromises without full custom workflows [17, 18]. Systematic reviews stress that some populations — including Indian cohorts — are underrepresented in global datasets and call for more locally sourced intraoperative and imaging studies to guide manufacturers and surgeons [19, 20]. The current thesis contributes to this need by providing direct intraoperative caliper measures and a head-to-head comparison with two implant systems used locally.
Materials and Methods
This is a retrospective single-center series (May 2017–May 2020) using intraoperative caliper data recorded under a standardized protocol. Institutional ethical approval and patient consent were obtained. Inclusion: adults undergoing primary cemented TKR for degenerative disease. Exclusion: revision arthroplasty, inflammatory polyarthritis, ankylosing spondylitis, significant adjacent deformities of hip/spine, skeletal immaturity, and cases requiring major augmentations. After exposure and osteophyte clearance, a calibrated sterile micro-caliper measured: femoral lateral and medial AP condylar lengths, femoral ML between epicondyles, tibial AP lengths for both plateaus, tibial ML width, and patellar AP thickness. Each measurement was independently confirmed by the assisting resident. Femoral and tibial aspect ratios calculated as (ML/AP) × 100. Data were entered into a spreadsheet and stratified by gender and implant system (Zimmer or Indus) using manufacturer tables present in the thesis. Descriptive statistics reported mean ± SD; pragmatic 95% intervals were taken as mean ± 2 SD. The emphasis was on identifying directional mismatches between patient anatomy and implant sizes rather than on formal hypothesis testing. Interobserver checks were performed during data collection as described in the thesis.
Results
252 knees met inclusion criteria: 176 received Zimmer components and 76 received Indus components. Mean cohort age was 62 years (SD 7; range 42–85). Aggregate means (SD): femoral AP lateral 52.85 mm (5.71), femoral AP medial 49.87 mm (5.82), femoral ML 68.75 mm (5.35); tibial AP lateral 49.28 mm (4.77), tibial AP medial 49.62 mm (4.96), tibial ML 69.79 mm (5.61); patellar AP 33.75 mm (2.45). Medium and large implant sizes predominated. Comparison to manufacturer size charts revealed consistent patterns: smaller femora tended to be undercovered mediolaterally with available components, while larger femora more often produced ML overhang. Aspect ratio analysis showed a negative correlation with AP dimension — in other words, ML/AP ratio decreased as AP increased. The Indus system approximated the measured dimensions more closely overall in many parameters, though some male tibial fits remained suboptimal. Detailed tables and size distributions by gender and implant are available in the thesis. No measurement-related adverse events were recorded.
Discussion
This intraoperative series brings home a pragmatic point: implant-patient geometric mismatch is often predictable and rooted in population-level anatomy rather than sporadic surgical error. The central, actionable observation is that ML/AP aspect ratio falls as AP dimension increases. When manufacturers preserve a near-constant aspect ratio across sizes, surgeons face a recurrent dilemma—prioritize AP (risk ML overhang) or prioritize ML (risk AP undersizing). Both choices have clinical implications: ML overhang can irritate soft tissues and produce anterior knee symptoms, while undersizing may expose cancellous bone and alter load transmission with theoretical consequences for wear and fixation. These issues were anticipated in earlier implant and anthropometric work, which first highlighted the mismatch problem and later recommended local data collection to guide design tweaks [1–6]. Subsequent morphometric and 3-D imaging studies reinforced the pattern of declining aspect ratios and documented consistent gender differences that make AP-driven sizing riskier in women [7–14]. Practical design responses discussed in the literature — gender-conscious geometries, asymmetric trays, and finer size increments — have shown variable clinical benefit and carry cost implications, placing them out of reach for universal adoption in many settings [15, 16]. That reality elevates the value of intermediate solutions: stage aspect ratios across size bands so larger AP sizes are designed with proportionally lower ML widths; offer narrower incremental sizing where small and medium ranges predominate; and provide asymmetric tibial trays to match plateau asymmetry. These adjustments are technically feasible, relatively low cost compared with full customization, and directly respond to the anatomical trends this and other studies documented [17–20]. Importantly, implant choice can mitigate mismatch — the dataset shows Indus components matched many local measurements better than Zimmer components, indicating that thoughtful system selection is a useful surgeon-level strategy. Surgeons should use the intraoperative numbers to guide templating and on-table decisions: prioritize ML fit when soft-tissue envelope or patellar tracking suggests overhang risk, or deliberately downsize with augmentation where AP undersizing is clinically acceptable. Limitations include the single-center retrospective design and reliance on caliper-derived two-dimensional measures rather than 3-D imaging; nevertheless, caliper measures are the practical reference at the operating table and therefore highly relevant to everyday decision-making. The thesis data thus provide concrete, local targets that manufacturers and hospitals can use to adapt inventories and pursue modest design changes likely to reduce routine compromise.
Conclusion
In this single-center intraoperative series of 252 knees, ML/AP aspect ratio decreased as AP dimension increased, producing predictable mediolateral undercoverage in smaller knees and ML overhang in larger knees when implants use constant aspect ratios. The Indus system approximated many measured dimensions more closely than Zimmer in this cohort, though male tibial fit discrepancies persisted in places. Practical steps—finer sizing increments, staged aspect ratios across size bands, and asymmetric tibial options—can reduce intraoperative compromise without requiring full custom implants. Prospective outcome studies are needed to test whether closer geometric conformity improves pain, function and implant longevity.
References
1. Blevins JL, Rao V, Chiu YF, Westrich GH. The relationship of height, weight, and obesity on implant sizing in total knee arthroplasty. In: Orthopaedic Proceedings. 2019 Oct; 101(SUPP_11):66.
2. Indelli PF, Aglietti P, Buzzi R, Baldini A. The Insall-Burstein II prosthesis: a 5- to 9-year follow-up study in osteoarthritic knees. J Arthroplasty. 2002;17(5):544–9.
3. Mandavgade MG, Deshmukh MT, Kherde MS, Ingole MS. Forecast of femur bone skeleton with anatomical parameter of Indian population.
4. Reddy KS, Kumar PD. Morphometry of proximal end of femur in population of Telangana state and its clinical application. Indian J Clin Anat Physiol. 2019; 6(1):57–60.
5. Saini UC, Bali K, Sheth B, et al. Normal development of the knee angle in healthy Indian children: a clinical study of 215 children. J Child Orthop. 2010; 4(6):579–86.
6. Central Intelligence Agency. The World Factbook. 2015.
7. Gibson T, Hameed K, Kadir M, et al. Knee pain amongst the poor and affluent in Pakistan. Br J Rheumatol. 1996 Feb; 35(2):146–9.
8. Ariff MS, Arshad AA, Johari MH, et al. The study on range of motion of hip and knee in prayer by adult Muslim males. Int Med J Malaysia. 2015; 14.
9. Roach KE, Miles TP. Normal hip and knee active range of motion: the relationship to age. Phys Ther. 1991; 71:656–65.
10. Zhang Y, Xu L, Nevitt MC, et al. Comparison of prevalence of knee osteoarthritis between elderly Chinese in Beijing and whites in the United States: The Beijing Osteoarthritis Study. Arthritis Rheum. 2001 Sep; 44(9):2065–71.
11. Vaidya SV, Ranawat CS, Aroojis A, Laud NS. Anthropometric measurements to design total knee prostheses for the Indian population. J Arthroplasty. 2000; 15(1):79–85.
12. Hitt K, Shurman JR, Greene K, McCarthy J, Moskal J, Hoeman T, Mont MA. Anthropometric measurements of the human knee: correlation to sizing of current knee arthroplasty systems. JBJS. 2003; 85(suppl_4):115–22.
13. Barroso MP, Arezes PM, da Costa LG, Miguel AS. Anthropometric study of Portuguese workers. Int J Ind Ergon. 2005; 35(5):401–10.
14. Choi KN, Gopinathan P, Han SH, Han CW. Morphometry of the proximal tibia to design the tibial component of total knee arthroplasty for the Korean population. Knee. 2007; 14:295–300.
15. Cheng FB, Ji XF, Lai Y, et al. Three dimensional morphometry of the knee to design total knee arthroplasty for Chinese population. Knee. 2009; 16(5):341–7.
16. Chaichankul C, Tanavalee A, Itiravivong P. Anthropometric measurements of knee joints in Thai population: correlation to sizing of current knee prostheses. Knee. 2011; 18(1):5–10.
17. Yue B, Varadarajan KM, Ai S, Tang T, Rubash HE, Li G. Differences of knee anthropometry between Chinese and white men and women. J Arthroplasty. 2011; 26(1):124–30.
18. Ho WP, Cheng CK, Liau JJ. Morphometrical measurements of resected surface of femurs in Chinese knees: correlation to sizing of current femoral implants. Knee. 2006;13(1):12–4.
19. Chin PL, Tey TT, Ibrahim MY, Chia SL, Yeo SJ, Lo NN. Intraoperative morphometric study of gender differences in Asian femurs. J Arthroplasty. 2011; 26(7):984–8.
20. Kim TK, Phillips M, Bhandari M, Watson J, Malhotra R. What differences in morphologic features of the knee exist among patients of various races? A systematic review. Clin Orthop Relat Res. 2017; 475(1):170–82.
| How to Cite this Article: Soni P, Sancheti P, Patil K, Gugale S, Sanghavi S, Sisodia Y, UI Nisar O, Sonawane D, Shyam A. Gender-Specific Knee Anthropometry and Its Impact on Total Knee Implant Design. Journal of Medical Thesis. 2022 July-December; 8(2):1-4. |
Institute Where Research was Conducted: Department of Orthopaedics, Sancheti Institute of Orthopaedics and Rehabilitation, Shivajinagar, Pune, Maharashtra, India.
University Affiliation: MUHS, Nashik, Maharashtra, India.
Year of Acceptance of Thesis: 2020
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Ten Year Survivorship and Functional Improvement after Total Knee Replacement: A Prospective Cohort Study
Vol 8 | Issue 1 | January-June 2022 | page: 01-04 | Ravi Teja, Parag Sancheti, Kailas Patil, Sunny Gugale, Sahil Sanghavi, Yogesh Sisodia, Obaid Ul Nisar, Darshan Sonawane, Ashok Shyam
https://doi.org/10.13107/jmt.2022.v08.i01.170
Author: Ravi Teja [1], Parag Sancheti [1], Kailas Patil [1], Sunny Gugale [1], Sahil Sanghavi [1], Yogesh Sisodia [1], Obaid Ul Nisar [1], Darshan Sonawane [1], Ashok Shyam [1]
[1] Sancheti Institute of Orthopaedics and Rehabilitation PG College, Sivaji Nagar, Pune, Maharashtra, India.
Address of Correspondence
Dr. Darshan Sonawane,
Sancheti Institute of Orthopaedics and Rehabilitation PG College, Sivaji Nagar, Pune, Maharashtra, India.
Email : researchsior@gmail.com.
Abstract
Background: Osteoarthritis and inflammatory arthritis of the knee cause pain and disability; primary total knee replacement (TKR) is the standard surgical treatment for end-stage disease. This study reports mid-term outcomes after posterior-stabilized fixed-bearing TKR in a regional teaching hospital.
Methods: We retrospectively traced 209 patients (216 knees) who underwent primary TKR between 2005 and 2010 and assessed them between July 2016 and November 2018 (minimum eight-year follow-up). Clinical evaluation included Knee Society Score, Oxford Knee Score, SF-36 and a visual analogue scale for pain. Radiographs were reviewed for alignment and loosening. Survivorship analysis used aseptic mechanical failure and overall revision as endpoints.
Results: At follow-up, mean postoperative range of motion was 109.7° (SD 11.2°). Most patients achieved good to excellent functional scores and high satisfaction. Implant survivorship was excellent with aseptic mechanical survival of 99.5% and overall survivorship of 98.5%. Four major complications (≈1.9%) were recorded and ten patients were lost to follow-up.
Conclusion: Posterior-stabilized fixed-bearing TKR provided durable mid-term pain relief, meaningful functional restoration and high implant survival in this cohort. Careful patient selection, appropriate sizing and meticulous surgical technique likely contributed to favourable outcomes.
Keywords: Total knee replacement, Posterior-stabilized, Survivorship, Oxford Knee Score, Long-term outcomes, Single-centre experience India.
Introduction:
Knee osteoarthritis is a progressive disorder that damages cartilage, modifies subchondral bone and produces pain, stiffness and limited function that impair everyday life. When nonoperative measures fail, total knee replacement (TKR) delivers reliable pain relief and restores mobility for most patients, and it is now a standard solution for end-stage disease. Improvements in implant design, surface processing and surgical technique over recent decades have increased durability and functional outcomes, with many implants showing favourable ten-year survivorship in large series and registries [1–4].
Surgical technique — particularly accurate component alignment and careful soft-tissue balancing — remains decisive for good results, since malalignment or imbalance predisposes to asymmetric wear, instability and early failure [5–7 ]. Patient factors such as age, body composition and bone quality influence both disease progression and postoperative recovery, and therefore must guide implant choice and perioperative planning.[8–10 ] Regional anthropometric differences in knee geometry have been described and can affect component fit; local sizing considerations are important to avoid mismatch and suboptimal biomechanics [11–13].
Complications such as periprosthetic infection, fracture and persistent pain continue to challenge surgeons and may lead to revision procedures, reinforcing the need for meticulous surgical technique, appropriate perioperative protocols and long-term follow-up [14–16]. Despite abundant international literature, outcome data from regional centers are valuable because activity patterns, expectations and anatomy may differ. This study presents mid-term clinical, functional and radiological outcomes and survivorship for patients who underwent primary posterior-stabilized fixed-bearing TKR at a single teaching hospital.
Aims and Objectives
This study aimed to evaluate mid-term clinical and functional outcomes of primary posterior-stabilized fixed-bearing total knee replacement performed at a single teaching hospital. Primary objectives were to measure pain relief, functional recovery and implant survivorship using aseptic mechanical failure and overall revision as endpoints. Secondary objectives included documenting complication rates, comparing outcomes across age groups, and quantifying range of motion alongside validated scores (Knee Society Score, Oxford Knee Score and SF-36). Findings were intended to inform local surgical practice and identify priorities for future research and registry work.
Review of Literature
Osteoarthritis is now recognized as a disease of the whole joint, where cartilage degeneration, subchondral bone change and synovial inflammation interact to produce symptoms and structural progression [17, 18]. Understanding inflammatory mediators and matrix degradation pathways has improved our approach to symptom control and perioperative optimization [19]. Patient phenotype including obesity, bone mass and muscle composition — affects disease risk and post-replacement recovery, which underlines the need for individualized planning [10, 20].
Condylar TKR evolved through iterative refinements aimed at restoring near-physiologic kinematics while limiting polyethylene wear. Registry data and projection studies show rising demand for both primary and revision arthroplasty as populations age, but also demonstrate satisfactory ten-year outcomes for many modern systems when surgical technique and implant selection are appropriate [1, 3, 4]. Design changes have focused on improved conformity, wear resistance and options for constraint to suit ligament status [5].
Surgical exposure and soft-tissue handling influence early rehabilitation and may affect long-term kinematics. Comparative studies of approaches (medial Para patellar, midvastus, subvastus) show small early differences in pain and motion, but achieving balanced ligament tension remains the surgical cornerstone to prevent instability and asymmetric loading that can accelerate failure [6, 7 ]. Constraint level should match ligament competence — cruciate-retaining and posterior-stabilized designs each have roles depending on the clinical scenario.
Fixation technique (cemented versus uncemented) has been widely studied; pooled analyses suggest comparable mid-term survivorship when accounting for implant geometry and execution, indicating that surgical technique and implant design often outweigh fixation choice alone [4]. Population-specific anthropometric studies show smaller Anterio-posterior femoral dimensions in some regional cohorts, reinforcing the need for appropriately sized component options [11, 12].
Complications such as infection, periprosthetic fracture and chronic postoperative pain are leading causes of revision, and preventive strategies coupled with structured follow-up are essential to maintain favourable outcomes [13–16].
Materials and Methods
This retrospective cohort included patients who underwent primary TKR between 2005 and 2010 and were traced for follow-up between July 2016 and November 2018. Institutional ethics approval was obtained and participants provided informed consent for follow-up assessment. Inclusion criteria were primary TKR for primary osteoarthritis or rheumatoid arthritis; cases with prior major knee surgery, post-traumatic arthritis, congenital deformity or revision arthroplasty were excluded. Hospital records and the master chart were reviewed for demographic data, comorbidities, operative details and implant information.
A total of 209 patients (216 knees) met inclusion criteria. Clinical assessment at follow-up used the Knee Society Scores (clinical and functional), Oxford Knee Score, SF-36 questionnaire and a visual analogue scale for pain. Examination recorded range of motion, deformity and stability. Standard anteroposterior and lateral radiographs were reviewed to assess component alignment, radiolucent lines and signs of loosening. Complications such as infection, periprosthetic fracture and aseptic loosening were recorded with details of management and timing.
Survivorship analysis used two endpoints: aseptic mechanical failure and overall revision for any cause. Descriptive statistics summarised demographic and clinical variables; continuous data are reported as means and standard deviations and categorical data as counts and percentages. Comparative analyses between age groups used appropriate inferential tests with significance set at p < 0.05. Ten patients were lost to follow-up and excluded from selected subgroup analyses.
Results
Two hundred and nine patients (216 knees) were available for mid-term analysis. The cohort was predominantly female (67.6% of knees), and the largest age group was 61–70 years (49.1% of knees). Most procedures were unilateral; seven patients underwent bilateral replacement. Mean postoperative range of motion was 109.7° (SD 11.2°), indicating substantial functional recovery. Patient-reported outcomes showed most patients achieved good to excellent results on the Oxford Knee and Knee Society scoring systems. Survivorship was high: aseptic mechanical survival exceeded 99% and overall implant survival approached 98% over the reported follow-up interval. There were four major complications in this series (approximately 1.9%): a periprosthetic fracture, an infection requiring staged revision, tibial component loosening requiring revision in one case, and one additional complication managed conservatively. Ten patients were lost to follow-up and excluded from selected analyses. Overall patient satisfaction was high, with most reporting marked improvement in pain and daily function.
Discussion
Mid-term follow-up in this cohort shows that primary posterior-stabilized fixed-bearing TKR delivers reliable pain relief, meaningful functional improvement and excellent implant survival. Mean postoperative range of motion and patient-reported scores are consistent with many published series, supporting the procedure’s ability to restore daily function when performed with careful technique [1–4].
Low rates of anterior knee pain in our group are in keeping with reports that appropriate patellar management can limit anterior discomfort in selected patients, though patellar resurfacing remains debated [14, 15]. The low complication and revision rates likely reflect careful patient selection, meticulous soft-tissue balancing, and accurate component alignment and standardized cementing techniques — factors emphasized in the literature as central to long-term success [5–7].
Limitations include the retrospective design and heterogeneous implant brands, which complicate direct comparison between systems. A small proportion of patients were lost to follow-up and that attrition could bias survivorship estimates. Cultural and anthropometric differences between populations caution against direct comparison with Western registries; implant sizing tailored to local anatomy can improve component fit and outcomes [11, 12].
Despite these limitations, the strong mid-term survivorship and high patient satisfaction support continued use of PS fixed-bearing designs in similar clinical settings. Future directions include prospective comparative trials of implant designs, multicenter registries capturing diverse populations and longer term surveillance to detect late wear and failure patterns. Registry data will be invaluable to evaluate small but clinically important differences between implants and fixation strategies over decades [3, 4].
Conclusion
Primary posterior-stabilized fixed-bearing total knee replacement produced durable mid-term results in this cohort, with high implant survivorship, substantial pain relief and meaningful restoration of function. Patient satisfaction was high and complication and revision rates were low in the first decade after surgery. Limitations include the retrospective design, implant heterogeneity and a small number lost to follow-up, which limit broad generalisability. These outcomes support continued use of PS fixed-bearing TKR in similar settings while underscoring the need for larger prospective registries and longer follow-up to refine implant selection and surgical strategies.
References
1. Kurtz S, Ong K, Lau E, Mowat F, Halpern M. Projections of primary and revision hip and knee arthroplasty in the United States from 2005 to 2030. J Bone Joint Surg Am. 2007; 89(4):780–785.
2. Pachore JA, et al. SHKS joint registry: a preliminary report. (Details as per thesis source).
3. Robertsson O, et al. Past incidence and future demand for knee arthroplasty in Sweden: report from the Swedish Knee Arthroplasty Register. Acta Orthop Scand. 2000; 71(4):376–380.
4. Lützner J, et al. Long-term results in total knee arthroplasty: a meta-analysis of revision rates and functional outcome. (Details as per thesis source).
5. Indelli PF, et al. The Insall-Burstein II prosthesis: a 5- to 9-year follow-up study in osteoarthritic knees. J Arthroplasty. 2002; 17(5):544–549.
6. Schai PA, et al. Total knee arthroplasty with the PFC system: results at a minimum of ten years and survivorship analysis. J Bone Joint Surg Br. 1998; 80-B: 850–858.
7. Preston S, et al. Towards an understanding of the painful total knee: what is the role of patient biology? Curr Rev Musculoskelet Med. 2016; 9(4):388–395.
8. Scott CE, Howie CR, MacDonald D, Biant LC. Predicting dissatisfaction following total knee replacement: a prospective study of 1217 patients. J Bone Joint Surg Br. 2010; 92(9):1253–1258.
9. Breugem SJM, Haverkamp D. Anterior knee pain after total knee arthroplasty: causes and management. World J Orthop. 2014; 5(3):163–170.
10. Wylde V, et al. Chronic pain after total knee arthroplasty. EFORT Open Rev. 2018; 3:180004.
11. Jain JP, et al. Knee prosthesis sizes in Indian patients undergoing total knee replacement. Int Surg J. 2015; 2(3):348–351.
12. (Anthropometry source as per thesis) — Details recorded in thesis dataset.
13. Blom W, et al. Infection after total knee arthroplasty. J Bone Joint Surg Br. 2004; 86-B (5): (Details as per thesis source).
14. Canton G, et al. Periprosthetic knee fractures: epidemiology, risk factors, diagnosis, management and outcome. Acta Biomed. 2017; 88:118–128.
15. Moon JC, et al. Diagnosis, causes and treatments of instability following total knee arthroplasty. Knee Surg Relat Res. 2014; 26(2):61–67.
16. Robinson WH. Low-grade inflammation as a key mediator of the pathogenesis of osteoarthritis. Nat Rev Rheumatol. 2016; 12(10):580–592.
17. Joshi AK, et al. Study of inflammatory markers in idiopathic osteoarthritis of knee. Int J Res Orthop. 2016; 2(4):350–353.
18. Karlsson MK. Patients with knee osteoarthritis have a phenotype with higher bone mass, higher fat mass, and lower lean body mass. Clin Orthop Relat Res. 2015; 473(1):258–264.
19. Man GS. Osteoarthritis pathogenesis — a complex process that involves the entire joint. J Med Life. 2014; 7(1):37–41.
20. Hong-Wei Liu, et al. Surgical approaches in total knee arthroplasty: a meta-analysis comparing the midvastus and subvastus to the medial Para patellar approach. J Arthroplasty. 2014; 29(12):2298–2304.
| How to Cite this Article: Teja R, Sancheti P, Patil K, Gugale S, Sanghavi S, Sisodia Y, Nisar OUI, Sonawane D, Shyam A. Ten Year Survivorship and Functional Improvement after Total Knee Replacement: A Prospective Cohort Study. Journal of Medical Thesis. 2022 January-June; 8(1): 1-4. |
Institute Where Research was Conducted: Sancheti Institute of Orthopaedics and Rehabilitation PG College, Sivaji Nagar, Pune, Maharashtra, India.
University Affiliation: Maharashtra University of Health Sciences (MUHS), Nashik, Maharashtra, India.
Year of Acceptance of Thesis: 2019
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