To Study The Efficacy And Safety Of Rivaroxaban In The Prevention Of Venous Thromboembolism (VTE) After Total Hip And Knee Arthroplasty

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Vol 3 | Issue 2 | Sep-Dec 2017 | page: 03-07  |S K Rai*, V P Raman, Naveen Shejale, S S Wani , Rohit Varma

Author: SK Rai*[1], VP Raman[2], Naveen Shejale[3], SS Wani  [1] , Rohit Varma [1]

 

1Department of Orthopaedics, Indian Naval  Hospital Ship Asvini, Colaba, Mumbai, India.
2Department of Orthopedics, Malla Reddy Institute of Medical Sciences, Suraram, Hyderabad, India.
3Department of Orthopaedics, Indian Naval Hospital Ship Kalyani, Visakhapatnam, India.

Address of Correspondence
Dr. S K Rai,
Department of Orthopaedics, Indian Naval  Hospital Ship Asvini, Colaba, Mumbai, India.
Email: skrai47@yahoo.com

Abstract

Objective: Development of venous thrombo-embolism (VTE) including deep venous thrombosis (DVT) is a common complication after total hip and total knee Arthroplasty, pelvic fracture or long bone fractures especially in lower limb. Currently used drugs for DVT prophylaxis after these procedures have important limitations, including parenteral administration, and unpredictable plasma levels requiring frequent monitoring and dose adjustment leading to decreased patient compliance. In our study we used oral Rivaroxaban, which  is one of the newer  oral anticoagulants and is a direct factor Xa inhibitor that has demonstrated superior efficacy, compared  to that of enoxaparin or any parenteral  LMWH.
Materials & Methods: In our study, 180 patients who underwent Total knee replacement (TKR) or Total hip replacement (THR) in our centre were included. They were put on oral Rivaroxaban, 10 mg once daily, started 6 hours after surgery and continued for 03 weeks in case of TKR and 6 weeks in case of THR.
Results: Venous thrombo-embolism (VTE)  and Deep vein thrombosis (DVT) are common complications  after THR and TKR and cause a substantial burden to patients, healthcare providers, increase costs to the patients and increase both  morbidity and mortality, if not addressed  promptly. Currently available anticoagulants in the form of subcutaneous injection have limitations that lead to decreased compliance with DVT prophylaxis guidelines. Rivaroxaban which is oral 10 mg  once daily has superior efficacy compared to enoxaparin or any parenteral LMWH  for the prevention of the same and the patient compliance is also very good. There were no incidences of increased bleeding or wound infection in our study as compared to control group which were given subcutaneous enoxaparin.
Key words: Venous thrombo-embolism, deep vein thrombosis, Total knee replacement, Total hip replacement, Rivaroxaban, DVT prophylaxis.

Introduction
Venous thrombo-embolism (VTE) including deep vein thrombosis (DVT) is a major medical problem characterized by thrombi formation in the deep venous system and can sometimes result in a fatal pulmonary embolism (PE). DVT occurs most commonly in the legs, although thrombi can also form in the veins of the arms as well [1].
Deep vein thrombosis (DVT) is an important complication following total knee and hip arthroplasty, especially when the patient remains in bed for prolonged periods after surgery. However, the incidence of DVT is often underestimated due to subclinical or minimal symptoms and signs. In Western countries, prophylactic agents against DVT are administered routinely after TKA. However, in a developing country like India, regular DVT prophylaxis is often not given to patients undergoing TKA or THA.
As the number of total joint arthroplasties being performed worldwide continues to grow, a commensurate increase in the number of venous thromboembolism (VTE) events can be anticipated. Although the incidences of symptomatic deep vein thrombosis (DVT) and pulmonary embolism (PE) are low, the incidence of asymptomatic DVTs has been estimated to be 20 %–40 % of inpatients undergoing total hip arthroplasty (THA) and total knee arthroplasty (TKA) [2]. Therefore, the use of effective and safe chemoprophylaxis  is crucial for minimizing the risk of VTE events in these patients.
In literature, despite hundreds of clinical studies, there is still no consensus on the ideal method of thromboprophylaxis for patients undergoing THA and TKA. This inconsistency has raised the concern that many patients are at risk for insufficient prophylaxis or excessive bleeding risks. In a retrospective study involving 3497 patients who had THAs or TKAs between April 1, 2004 and December 31, 2006, Selby et al. found that only 40 % of patients received the 8th edition American College of Chest Physicians (ACCP) recommended thromboprophylaxis [3]. In the United States, DVT and PE result in up to 600000 hospitalizations a year, and nearly 50000 individuals die annually as a result of Pulmonary embolism [4].
Hip arthroplasty, knee arthroplasty, and hip fracture surgeries are strongly associated with a risk of developing DVT [5]. The incidence of asymptomatic DVT after a major orthopedic surgery without prophylaxis reportedly ranges from 30% to 80% [6], whereas the incidence of symptomatic DVT reportedly ranges from 0.5% to 4% [7]. Although the incidence of asymptomatic DVT is greater than that of symptomatic DVT, the clinical importance of asymptomatic DVT remains unclear [8].

Materials and Methods
In our study, 180 patients who had undergone TKR or THR in our centre (Department of Orthopaedics, Indian Naval Hospital Ship Asvini, Colaba, Mumbai, 400005, India) were included, and they used oral Rivaroxaban 10 mg once daily, started 6 hr after surgery and continued for 3 weeks in case of TKR and 6 weeks in case of THR. The study was conducted between June 2012 and  Dec  2016.  Patients already on any anticoagulants preoperatively were excluded from the study. In addition to 180 patients 30 patients of TKR and 10 patients of THR were given only subcutaneously Enoxapaerin for prevention of DVT as control group.
All patients were evaluated preoperatively and underwent proper pre anesthesia check up.  Patients  who  were detected to have impaired renal function during pre anesthesia check  were excluded from the study, because in patients with impaired renal function, the clearance of Rivaroxaban is decreased moderately, and its use is not recommended for patients with severe renal impairment (creatinine clearance < 30 mL/min).[9]
All total knee arthroplasties were done by us without the use of a tourniquet. A closed drainage system was inserted before closure of the wound, and a light compression dressing was applied to the knee. The drain was usually removed on the third postoperative day and a progressive, continuous passive motion and physical therapy protocol was started on the first or second postoperative days (usually before drain removal). Pre operatively, IV antibiotic Tiecoplanin 400 mg  was given just before incision and after 12 hr post operatively and continued for next  two days as  once daily doses. All patients were given oral Rivaroxaban 10 mg once daily, started 6 hr after surgery and continued for  03 weeks in case of TKR and 6 weeks in case of THR.
All patients were clinically examined daily for calf tenderness and Homan’s sign. All patients were prospectively monitored for deep vein thrombosis using colour Doppler done by intervention radiologist from postoperative day number 3 (range, post op day 3 to 7). Doppler signals were evaluated at the common femoral, popliteal, and posterior tibial vessels. Compression to produce coaptation of the vein walls was applied sequentially and throughout the deep veins beginning at the inguinal ligament and proceeding in scan head width increments through all 3 pairs of tibio peroneal veins, the sural veins, and the soleal sinuses. The Doppler  examination was considered normal when the signals showed equal, bilateral, spontaneous, and phasic flow in all veins (except the posterior tibial veins) and good augmentation in response to distal compression of the limb. The image was reported as negative when there was complete coaptation of the vein walls because of local compression.
A Doppler study was considered positive for DVT  (a) if distal limb compression produced no or reduced augmentation of flow in comparison with that in the contralateral limb; (b), if both common femoral vein Doppler signals were continuous or  (c)  if one common femoral vein Doppler signal showed decreased ventilatory  phasicity as compared with the contralateral limb. Color flow was used only as an adjunctive measure and not as a diagnostic criterion. Thrombi were classified as proximal if the popliteal or femoral veins were involved and distal if only the veins of the calf were involved. D-dimer test was also performed depending on colour Doppler findings and also for clinical correlation.
At the time of discharge, all patients were instructed to take oral Rivaroxaban 10 mg once daily dose till 3 weeks in case of TKR and 6 weeks in case of THR.

Results
In our study, we followed up 180 patients who had undergone TKR or THR (TKR 120 patients and THR 60 patients) between June 2012 and Dec 2016. Out of 180 patients, 09 patients who developed calf swelling and pain on 5-8 days post operatively with positive Homan’s sign were evaluated by colour Doppler and d-dimer test. Out of these 09 patients, seven patients showed positive color Doppler and positive d- dimer test. All these 07 patients( 05 TKR patients and 02 THR patients)  were further treated by parenteral LMWH (enoxaparin). The remaining two patients showed negative color Doppler study.  However depending on clinical findings i.e positive Homan sign and calf tenderness, these were also treated by parenteral LMWH (enoxaparin) and improved over 2 weeks.
In our study 120 patients underwent TKR and out of 120 patients only 05( 04%) patient developed DVT while 60 patients underwent THR and out of 60 patients only 02( 03%) patient developed DVT.

 

Table 1: Development of DVT post operatively

Joint replacement No of patients (n) No of patients who developed clinical sign of DVT post operatively No of patients showed positive Colour Doppler & d-Dimer
TKR 120 06(05%) 05/120 (04%) Positive for DVT
THR 60 03(01%) 02/60 (03%) Positive for DVT
Total 180 09

Table 2 : Patients demographic details

Age No of TKR patients No of THR patients Patient developed DVT after TKR with positive colour Doppler & d-Dimer Patient developed DVT after THR with positive colour Doppler & d-Dimer
55-65 years 19 12 01       –
66-75 years 75 41 02 01
More than 75 years 26 07 02 01
Total 120 80 05 02

 

Discussion
Thrombo-prophylaxis and anti-thrombotic therapy when indicated, remains crucial in the peri- and post-operative management of patients who undergo major orthopaedic surgical procedures, particularly total knee and hip  arthroplasty and major  fracture surgery, especially around the hip . Optimal thromboprophylaxis is currently mandatory in most orthopaedic practices to avoid the dreaded complications of venous thrombo-embolism (VTE). The pathogenesis of VTE is multifactorial and includes the well-known Virchow’s triad of hypercoagulability, venous stasis, and endothelial damage. With current advances in orthopaedic surgery, a multimodal approach to thromboprophylaxis, optimum anaesthetic management, and decreased post-operative convalescence/bed rest,  have reduced  the risks of venous thromboembolism after  total knee, hip  arthroplasty and major  fracture surgery  in the lower extremity. The rates of venous thromboembolism (VTE) complications such as deep vein thrombosis (DVT) and pulmonary embolism (PE) have been shown to be around 40–60% within 7 to 14 days following orthopaedic lower limb surgery without thromboprophylaxis .[10]  Most of these thrombi resolve spontaneously; however, a small percentage (1–4%) will develop into symptomatic VTE [11]. The incidence of fatal pulmonary embolisms in patients not receiving thromboprophylaxis ranges from 0.3–1% following total knee and hip joint arthroplasty and around 3.6% after  major long bone fracture surgery [12]. A prescient and rational  approach to reduce the incidence of VTE is therefore of paramount importance.

Thromboprophylaxis options for prevention of DVT
For prevention of DVT, the following modalities are available, which can be used depending upon patient characteristics,  medical and surgical co-morbidities and what is most suitable for the individual patient.

  1. Mechanical methods
    Many centres still use mechanical thromboprophylaxis as an adjunct in the prevention of VTE. These include the use of graduated compression stockings, venous foot pumps, and active external compression devices (continuous and intermittent). The benefits of these include the non-invasive nature of its application, the fact that it requires no monitoring and the fact that it poses no increased risk of bleeding [13]. The virtue of external pressure applied to the limb, is that it promotes blood flow velocity, reduces venous stasis, and increases levels of systemic fibrinolysins [14]. Intermittent pneumatic compression devices have been shown to reduce significantly the incidence of  DVT when combined with chemoprophylaxis compared to either therapy in isolation [14].
  1. Pharmacological methods

Warfarin
Warfarin is a vitamin K antagonist which expresses its anticoagulant properties via the inhibition of clotting factors (namely II, VII, IX and X) and continues to be used  in orthopaedic centres to this day. The level of anticoagulation achieved can be determined by close monitoring of the patient’s INR (International Normalised Ratio). When compared to low molecular weight heparin (LMWH) for thromboprophylaxis following hip and knee replacement , warfarin showed statistically significant higher rates of asymptomatic clot formation. It must be noted, however, that in cases of symptomatic VTE, there was no significant difference between the two chemo-prophylactic agents [15]. Although studies have shown that LMWH is associated with increased bleeding complications in the short term, when given for an extended period (six weeks), more symptomatic bleeds were observed in the warfarin group [16].

 

Aspirin( Acetyl salicylic Acid)
Low dose Aspirin is also used for VTE prevention at present. It inhibits thromboxane, which is necessary for the binding of platelets during the process of clot formation. Apart from orthopaedic surgery, it is widely used in the management of stroke and myocardial infarctions and in hypercoagulopathy.  It requires no monitoring and is generally well tolerated. There is evidence to support the notion that aspirin is not inferior to LMWH in VTE prevention; however, the current AAOS and ACCP guidelines do not advise its use in isolation without combined mechanical prophylaxis [17].

Heparin (unfractionated heparin and low molecular weight heparin LMWH)
Unfractionated heparin (UH) and LMWH have been used for orthopaedic surgery thromboprophylaxis for decades. LMWH has largely replaced UH due to the fact that no monitoring is required and  its simple mode of administration via subcutaneous injection. Many studies have shown fewer VTEs and less bleeding complications with LMWH compared with UH in orthopaedic surgery [18]. The current guidelines from the American Academy of Orthopaedic Surgeons (AAOS) and the American College of Chest Physicians (AACP) continue to promote LMWH as the pharmacological thrombo-prophylactic agent of choice following joint replacement [19].

Apixaban
It is an oral factor Xa inhibitor, and has been approved for VTE prophylaxis following orthopaedic surgery in Europe since May 2011, and is under review by the United States Food and Drug Administration (FDA) at the present time. Compared to LMWH in patients undergoing joint replacement, Apixaban showed significantly superior results in the prevention of  DVT and its related mortality[20].

Dabigatran
It is an  orally available direct thrombin (factor IIa) inhibitor.  Dabigatran has been approved by the European Commission since March 2008 for use in orthopaedic surgery, while FDA approval is reserved for certain indications in patients with atrial fibrillation. Studies on Dabigatran, while emphasizing  its efficacy have shown similar but not superior results in DVT prophylaxis compared with LMWH while  side effects in terms of bleeding risks are almost the same [21].

Rivaroxaban
Rivaroxaban, the first orally available factor Xa antagonist, received FDA approval for VTE prophylaxis in July 2011. Four phase III randomized control trials showed Rivaroxaban to be superior to LMWH in preventing total VTE and symptomatic events in patients undergoing hip and knee TJA [22]. Some recent studies have showed an increased risk of re-operation secondary to infection and wound complications in patients receiving Rivaroxaban. This, coupled with a tendency to an increased risk of gastrointestinal bleeding, has given impetus to the continued use of LMWH  for thrombo-prophylaxis [23].

Current Guidelines from AAOS and ACCP
The recent guidelines published by the AAOS and ACCP provide the most widely accepted advice regarding the use of thromboprophylaxis in elective orthopaedic hip and knee arthroplasty.  These represent a comprehensive and systematic scrutiny of the literature, an update of previously published guidelines and expert consensus in VTE prevention and management. Differences in opinion between physicians and surgeons were noted especially in regard to bleeding risks. Hence, risk stratification of patients is advised and further research into this area is currently continuing.
Both guidelines emphasize on the  importance of  DVT prophylaxis using various different regimens as compared to no prophylaxis. The AAOS guidelines from 2016 include a strong recommendation against the use of routine duplex ultrasonography screening post-operatively. Under the moderate recommendations, the group suggests discontinuing anti-platelet agents (clopidogrel  & aspirin) pre-operatively and pharmacological thromboprophylaxis with/or without  mechanical compressive devices in patients not at risk following joint replacement .
Recommendations based on consensus were developed in several areas where evidence was not sufficiently reliable. These included:-

(a) the duration of thromboprophylaxis treatment to be  individually tailored according to patient specifics using a multi-disciplinary approach involving physicians
(b) the combination of mechanical and pharmacological thromboprophylactic  agents,
(c) mechanical devices in patients with a higher risk of bleeding,
(d) early mobilisation following  joint replacement.

The latest ACCP guidelines from 2016 have suggested starting anticoagulant prophylaxis 12 or more hours pre-operatively or postoperatively rather than four hours or less preoperatively or post-operatively. In the absence of a bleeding disorder and not including major fracture surgery, any form of thromboprophylaxis is recommended above no prophylaxis for a minimum of 10 to 14 days. LMWH is preferred above all other pharmacological agents, and the addition of a mechanical device like intermittent pneumatic compression device (IPCD) is recommended. An extended duration of thromboprophylaxis of up to 35 days is suggested following surgery. When subcutaneous injections are rejected or unacceptable to  the patient,  the oral thrombo-prophylactic agent Apixaban or Dabigatran is advisable. Individuals with bleeding disorders are recommended to receive either mechanical prophylaxis in the form of ICPD in isolation or no thromboprophylaxis. No VTE prophylaxis is considered necessary when dealing with lower limb immobilisation following isolated injuries and low-risk patients undergoing elective knee arthroscopy.
In patients undergoing surgery for hip fractures, the United Kingdom National Institute for Health and Clinical Excellence (NICE) have published guidelines covering the overall management of the individual and places significant emphasis on thromboprophylaxis. It recommends mechanical agents (compression stockings, foot pumps and IPCD) at the time of admission and pharmacological agents (i.e. LMWH or UH) provided that there are no contraindications. Pharmacological agents are stopped prior to surgery (12 hours for Fondaparinux and six hours for LMWH) and recommenced six to 12 hours post-operatively. Thromboprophylaxis is continued for up to 28–35 days following surgery.

Conclusion
Each orthopaedics surgeon must have  a good knowledge and understanding of  the various mechanical and pharmacological thromboprophylactic agents  will significantly help them to reduce the incidence of venous thromboembolism following major orthopaedic elective joint arthroplasties and other major orthopaedic surgeries, especially involving lower limbs. The usage guidelines for the various pharmacological agents continue to be updated constantly. Newer studies in this area will help prepare appropriate prophylactic strategies and bring about new options in the treatment and prevention of VTE. More independent studies may improve our pharmacological experience in  thrombo-prophylactic protocols following major elective orthopaedic  surgery . Appropriate risk stratification measures need to be continuously developed to ensure the right thrombo-prophylactic protocol for the right patient in the right clinical setting. In our study, patients given  Rivaroxaban 10 mg orally once daily showed good  results with no increased incidence of local or gastrointestinal bleeding . There were also no wound infections while receiving Rivaroxaban .
Based on our study, we can conclude that  an ideal  thrombo-prophylactic agent should be effective , with nil or minimal chance of bleeding or  wound infection, high patient compliance and be economically affordable.

 

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How to Cite this article:  Rai S K, V P Raman, Shejale N, Wani S S, Varma R.  To Study The Efficacy And Safety Of Rivaroxaban In The Prevention Of Venous Thromboembolism (VTE) After Total Hip And Knee Arthroplasty. Trauma International Sep-Dec 2017;3(2):03-07.

 


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Comparison of Various Modalities of Treatment for Tibial Plateau Fracture

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Vol 3 | Issue 2 | Sep – Dec 2017 | page: 12-15 | Prafulla Herode, Abhijeet Shroff, Mohan Sadaria, Jeegar Patel, Satish Uchale

Author: Prafulla Herode [1], Abhijeet Shroff [1], Mohan Sadaria [2], Jeegar Patel [1], Satish Uchale [1].

[1]Department of Orthopaedics, Dr. D. Y. Patil Hospital and Medical College,Pimpri,Pune, India,
[2]Senior Consultant and Orthopaedic Surgeon, Sadaria Orthopaedic Hospital, Surat, Gujarat, India.

Address of Correspondence
Dr. Abhijeet Shroff,
Department of Orthopaedics, Dr. D. Y. Patil Hospital and Medical College, Pimpri, Pune, India.
E-mail: drjmsadaria@gmail.com

Learning Points for this Article: Thus we learned that Displaced/Depressed intraarticular fractures belonging to Schatzker’s type I, II and III should be treated by surgical methods,ORIF gives satisfactory results by maintaining precise articular congruity and preventing early osteoarthritis.

Abstract

Background: Tibial plateau fractures are quite challenging for orthopaedic surgeons,and earlier, most of tibial plateau fractures were treated conservatively which resulted in joint line incongruity, early osteoarthritis, and knee stiffness. Now, treatment of these fractures has changed. We did this study to compare the outcome of different modalities of treatment in tibial plateau fractureswith advantages and disadvantages.
Materials and Methods: During 2 years from April 2015 to May 2017, 30 patients were treated for closed tibial plateau fractures, of which 4 patients were treated by conservative methods, and 26 patients were treated by surgical methods.
Results: Result showed the higher involvement of young, middle-aged males than older females with maximum Type I fractures. Operative results were better in complicated fractures which treated with buttress plate where there was no much difference in the outcome of simple TypesI and II fractures, and hence, we preferred conservative modality for them.
Conclusion: The correct method of management of tibial condylar fractures depends on good clinical judgment. If rational treatment is to be instituted, the surgeon must have sound knowledge of the pattern of the injury and a clear understanding of the knee examination and imaging studies and must be familiar with a variety of techniques available at present for treating tibial condyle fractures.
Keywords: Tibial plateau, conservative, cannulated cancellous screw, buttress plate.

References

1. Schatzker J, McBroom R, Bruce D. The tibial plateau fracture. The Toronto experience 1968-1975. Clin Orthop Relat Res 1979;138:94-104.
2. Jensen DB, Rude C, Duus B, Bjerg-Nielsen A. Tibial plateau fractures. A comparison of conservative and surgical treatment. J Bone Joint Surg Br 1990;72(1):49-52.
3. Bowes DN, Hohi M. Tibial condyle fracture: Evaluation of treatment and out come. Clin Orthop 1982;171:104.
4. Blokker CP, Rorabeck CH, Bourne PB. Tibia plateau fractures – An analysis of the results of treatment in 60 patients. Clin Orthop 1984;182:193-198.
5. Ebraheim NA, Sabry FF, Haman SP. Open reduction and internal fixation of 117 tibial plateau fractures. Orthopedics 2004;27(1):1281-1287.
6. Lansinger O, Bergman B, Körner L, Andersson GB. Tibial condylar fractures. A twenty-year follow-up. J Bone Joint Surg Am 1986;68(1):13-19.
7. Sament R, Mayanger JC, Tripathy SK, Sen RK. Closed reduction and percutaneous screw fixation for tibial plateau fractures. J Orthop Surg (Hong Kong) 2012;20(1):37-41.
8. Raza H,Hashmi P, Abbas K, Hafeez K. Minimally invasive percutaneous plate osteosynthesis in tibia plateau fractures. J Orthop Surg 2012;20(1):42-47.

How to Cite this article:  Herode P, Shroff A, Sadaria M, Patel J, UchaleS. Comparison of Various Modalities of Treatment for Tibial Plateau Fracture. Trauma International Sep – Dec 2017;3(2):12-15.

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Two-Staged Management of Proximal Tibial Fractures with Impending Compartment Syndrome By Temporary External Stabilization and Fasciotomy and Delayed Definitive Fixation

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Vol 3 | Issue 2 | Sep – Dec 2017 | page: 16-20 | M. Shoaib Qureshi, Mangesh Panat, Pratik Israni

Author: M. Shoaib Qureshi [1], Mangesh Panat [1], Pratik Israni[1].

[1]Department Of Orthopedics, Mgm Hospital & Research Centre, Aurangabad, India

Address of Correspondence
Dr.  Mangesh Panat,
Dept. of orthopedics, mgm medical college and hospital.
Email: mangeshpanat@yahoo.co.in

Learning Points for this Article: This article will focus on successful management of proximal tibia fractures with impending compartment syndrome in two stages supporting the practice of delayed internal fixation until the soft-tissue envelope allows for definitive fixation.

Abstract

Introduction: High energy proximal tibia fractures with soft tissue involvement presenting with dicolored patches over the leg and severe swelling, compound wounds, blisters with tight compartments and absent or feeble dorsalis pedis or posterior tibial arteries warrant to go in for a staged procedure. In patients with multiple injuries, an external fixator can be applied quickly with minimal blood loss for unstable periarticular fractures around the knee. Two-stage procedures involve (1) early joint spanning external fixators with fasciotomy for the medial and posterior compartments, (2) and late definitive fixation with plates or nails and with skin grafting.
Materials and Methods: In our study, we present a short series of 15 proximal tibial fractures with impending compartment syndrome. Patients selected for this study were (1) closed proximal tibia fracture intra- and peri-articular and metaphysis diaphysis junction communited and noncommunited fractures (2) impending compartment syndrome evaluated based on excessive swelling, tight compartments, blisters over skin, feeble or absent dorsalis pedis or posterior tibial pulsations, color Doppler suggestive of severe subcutaneous edema associated with monophasic or absent flow over distal arteries.
Exclusion criteria: (1) Low energy proximal tibia fracture without soft tissue insult and compound wounds over the proximal tibia fractures, (2) associated popliteal artery injuries.
Conclusion: With the initial application of a bridging external fixator followed by delayed internal fixation protocol for pilon fractures has been successful in reducing the historically high rates of wound complications associated with these high-energy injuries. As well this protocol allows the use of minimally invasive plate osteosynthesis technique which is based on a combination of the principles of stability, restoration of anatomy and early motion while eliminating the need for excessive soft tissue dissection.
Keywords: Proximal Tibial fractures, External fixators, Fasciotomy, Definitive fixation.

References

1. Dougherty PJ, Silverton C, Yeni Y, Tashman S, Weir R. Conversion from temporary external fixation to definitive fixation: Shaft fractures. J Am Acad Orthop Surg 2006;14:S124-S127.
2. Chan PS, Klimkiewicz JJ, Luchetti WT, Esterhai JL, Kneeland JB, Dalinka MK, et al. Impact of CT scan on treatment plan and fracture classification of tibial plateau fractures. J Orthop Trauma 1997;11(7):484-489.
3. Weigel DP, Marsh JL. High-energy fractures of the tibial plateau. Knee function after longer follow-up. J Bone Joint Surg Am 2002;84(9):1541-1551.
4. Ricci WM, Rudzki JR, Borrelli J Jr. Treatment of complex proximal tibia fractures with the less invasive skeletal stabilization system. J Orthop Trauma 2004;18(8):521-527.
5. Gosling T, Schandelmaier P, Muller M, Hankemeier S, Wagner M, Krettek C. Single lateral locked screw plating of bicondylar tibial plateau fractures. Clin Orthop Relat Res 2005;439:207-214.
6. Egol KA, Tejwani NC, Capla EL, Wolinsky PL, Koval KJ. Staged management of high-energy proximal tibia fractures (OTA types 41): The results of a prospective, standardized protocol. J Orthop Trauma 2005;19(7):448-455.
7. Watson JT, Moed BR, Karges DE, Cramer KE. Pilon fractures. Treatment protocol based on severity of soft tissue injury. Clin Orthop Relat Res 2000;78-90.
8. Haidukewych GJ, Collinge CA. Conversion of Temporary External Fixation to Formal Internal Fixation for Complex per Articular Injuries of the Lower Extremity: Is there an Infection risk? Presented at the American Academy of Orthopaedic Surgeons Annual Meeting, Dallas, Texas; 2002.

How to Cite this article:  Qureshi MS, Panat M, Israni P. Two-Staged Management of Proximal Tibial Fractures with Impending Compartment Syndrome By Temporary External Stabilization and Fasciotomy and Delayed Definitive Fixation. Trauma International Sep-Dec 2017;3(2):16-20.

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Fractures of the distal end of humerus treated with joshi external stabilizing system

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Vol 3 | Issue 2 | Sep – Dec 2017 | page: 8-11 | Meganath Pawar, Mohammed Ibrahim

Author: Meganath Pawar [1], Mohammed Ibrahim [2].

[1]Department of Orthopaedics, ESIC Medical College, Gulbarga, Karnataka, India,
[2]Department of Orthopaedics, GIMS Medical College, Gulbarga, Karnataka, India.

Address of Correspondence
Dr. Mohammed Ibrahim
Department of Orthopaedics, GIMS Medical College, Gulbarga, Karnataka, India.
Email: dribrahimparvez@gmail.com

Learning Points for this Article: Application of simple and easy method for treated of complex fractures at peripheral level

Abstract

Fracture of the distal humerus is a common and debilitating injury and accounts for 2% of all adult fractures. Patients with displaced, unstable distal humeral fractures may have improved outcomes if managed operatively.
Objectives: The objectives were aimed to study the results of using Joshi’s external stabilizing system (JESS) for the management of fractures of distal humerus.
Materials and Methods: This prospective study was conducted in GGHGulbarga on 15 subjects with distal humerus fractures. As per AO classification,C typefractures were included and prepared for JESS fixation. The results of the treatment were evaluated as per Cassebaum functional criteria. Patients were followed up for 12 months.
Results: Among15 patients, 9 males and 6 females, 6 hadC1, 6 had C2, and 3 had C3. Mean duration of JESS application was 8 weeks. Among 15 patients,10 had excellent, 3 had satisfactory result, and 2 had unsatisfactory result.
Conclusion: JESS is an alternativesimple and easyoption for the treatment of distal humerus fractures, showing excellent to good results in cases of AO C1, C2, and C3 fracture.
Keywords: Distal humerus intracondylar, Joshi’s external stabilizing system.

 References

1. Babhulkar S, Babhulkar S. Controversies in the management of intra-articular fractures of distal humerus in adults. Indian J Orthop2011;45(3):216-225.
2. Galano GJ, Ahmad CS, Levine WN. Current treatment strategies for bicolumnar distal humerus fractures. J Am AcadOrthopSurg2010;18(1):20-30.
3. Safoury YA, Atteya MR. Treatment of post-infection nonunion of the supracondylar humerus with Ilizarov external fixator. J Shoulder Elbow Surg2011;20(6):873-879.
4. Zlotolow DN, Catalano LW, Barron OA,Glickel SZ. Surgical exposure of the humerus. J Am AcadOrthopSurg2006;14(13):754-765.
5. Qureshi KK, Sabir MR, Yasin G. Assessment of elbow function after stable fixation of AO Type C fracture of the distal humerus in adults. Prof Med J 2005;12:331-335.
6. Cheung EV, Steinmann SP. Surgical approaches to the elbow. J Am AcadOrthopSurg2009;17(5):325-333.
7. O’Driscoll SW, Sanchez-Sotelo J, Torchia ME. Management of the smashed distal humerus. OrthopClin North Am2002;33:19-33, vii.
8. Sanchez-Sotelo J, Torchia ME, O’Driscoll SW. Complex distal humeral fractures: Internal fixation with a principle-based parallel-plate technique. Surgical technique. J Bone Joint Surg Am2008;90Suppl 2:31-46.

How to Cite this article:  Pawar M, Ibrahim M. Fractures of the Distal End of Humerus Treated with Joshi External Stabilizing System. Trauma International Sep-Dec 2017;3(2):8-11.

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To study the efficacy and safety of Rivaroxaban in the prevention of venous thromboembolism after Total Hip and Knee Arthroplasty

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Vol 3 | Issue 2 | Sep-Dec 2017 | page: 3-7 | S. K. Rai, V. P. Raman, Naveen Shejale, S. S. Wani, Rohit Varma

Author: S. K. Rai [1], V. P. Raman [2], Naveen Shejale[3], S. S. Wani [1], Rohit Varma [1].

[1]Department of Orthopaedics, Indian Naval Hospital Ship Asvini, Colaba, Mumbai, 400005, India.
[2]Malla Reddy Institute of Medical Sciences, Suraram, Hyderabad, 500055, India.
[3]Department of Orthopaedics, Indian Naval Hospital Ship Kalyani, Visakhapatnam, 530005, India.

Address of Correspondence
Dr. SK Rai
Department of Orthopaedics, Indian Naval Hospital Ship Asvini, Colaba, Mumbai, 400005, India.
Email: skrai47@yahoo.com

Learning Points for this Article: To prevent of venous thromboembolism after total Hip and Knee Arthroplasty there is parenteral low molecular weight heparin is available and being used in many centers but it has to be given my trained paramedic or nurse however oral drug like Rivaroxaban in once daily doses and it is patients friendly and can be taken at home after discharge. It is safe and as effective as parenteral low molecular weight heparin.

Abstract

Objective: Development of venous thrombo-embolism (VTE) including deep venous thrombosis (DVT) is a common complication after total hip and total knee Arthroplasty, pelvic fracture or long bone fractures especially in the lower limb. Currently used drugs for DVT prophylaxis after these procedures have important limitations, including parenteral administration, and unpredictable plasma levels requiring frequent monitoring and dose adjustment leading to decreased patient compliance. In our study we used oral rivaroxaban, which is one of the newer oral anticoagulants and is a direct factor Xa inhibitor that has demonstrated superior efficacy, compared to that of enoxaparin or any parenteral low molecular weight heparin (LMWH).
Materials and Methods: In our study, 180 patients who underwent Total knee replacement (TKR) or Total hip replacement (THR) in our center were included. They were put on oral rivaroxaban, 10 mg once daily, started 6 h after surgery and continued for 3 weeks in case of TKR and 6 weeks in case of THR.
Results: VTE and DVT are common complications after THR and TKR and cause a substantial burden to patients, healthcare providers, increase costs to the patients and increase both morbidity and mortality, if not addressed promptly. Currently available anticoagulants in the form of subcutaneous injection have limitations that lead to decreased compliance with DVT prophylaxis guidelines. Rivaroxaban which is oral 10 mg once daily has superior efficacy compared to enoxaparin or any parenteral LMWH for the prevention of the same and the patient compliance is also very good. There were no incidences of increased bleeding or wound infection in our study as compared to control group which were given subcutaneous enoxaparin.
Keywords: Venous thrombo-embolism, deep vein thrombosis, Total knee replacement, Total hip replacement, Rivaroxaban, deep venous thrombosis prophylaxis.

References

1. Kucher N. Clinical practice. Deep-vein thrombosis of the upper extremities. N Engl J Med. 2011;364:861–869. [PubMed]
2. Ciccone WJ, II, Fox PS, Neumyer M, Rubens D, Parrish WM, Pellegrini VD., Jr Ultrasound surveillance for asymptomatic deep venous thrombosis after total joint replacement. J Bone Joint Surg Am. 1998;80:1167–74. [PubMed].
3. Selby R, Borah BJ, McDonald HP, Henk HJ, Crowther M, Wells PS. Impact of thrombo-prophylaxis guidelines on clinical outcomes following total hip and total knee replacement. Thromb Res. 2012;130(2):166–72. [PubMed].
4. Prevention of venous thrombosis and pulmonary embolism. NIH Consensus Development. JAMA. 1986;256:744–749. [PubMed].
5. Cohen AT. Asia-Pacific Thrombosis Advisory Board. Asia-Pacific Thrombosis Advisory Board consensus paper on prevention of venous thromboembolism after major orthopaedic surgery. Thromb Haemost. 2010;104:919–930. [PubMed].
6. Piovella F, Wang CJ, Lu H, Lee K, Lee LH, Lee WC, et al. Deep-vein thrombosis rates after major orthopedic surgery in Asia. An epidemiological study based on postoperative screening with centrally adjudicated bilateral venography. J Thromb Haemost. 2005;3:2664–2670. [PubMed]
7. Januel JM, Chen G, Ruffieux C, Quan H, Douketis JD, Crowther MA, et al. Symptomatic in-hospital deep vein thrombosis and pulmonary embolism following hip and knee arthroplasty among patients receiving recommended prophylaxis: a systematic review. JAMA. 2012;307:294–303. [PubMed]
8. Eikelboom JW, Karthikeyan G, Fagel N, Hirsh J. American Association of Orthopedic Surgeons and American College of Chest Physicians guidelines for venous thromboembolism prevention in hip and knee arthroplasty differ: what are the implications for clinicians and patients? Chest. 2009;135:513–520. [PubMed]
9. D. Kubitza, M. Becka, W. Mueck et al., “Effects of renal impairment on the pharmacokinetics, pharmacodynamics and safety of rivaroxaban, an oral, direct Factor Xa inhibitor,” British Journal of Clinical Pharmacology, vol. 70, no. 5, pp. 703–712, 2010.
10. Geerts WH, Bergqvist D, Pineo GF, Heit JA, Samama CM, Lassen MR, et al. Prevention of venous thromboembolism: American College of Chest Physicians evidence-based clinical practice guidelines (8th Edition) Chest. 2008;133(6 Suppl):381S–453S. doi: 10.1378/chest.08-0656 . [PubMed]
11. Kim YH, Oh SH, Kim JS. Incidence and natural history of deep-vein thrombosis after total hip arthroplasty. A prospective and randomised clinical study. J Bone Joint Surg Br. 2003;85(5):661–665.[PubMed]
12. Stringer MD, Steadman CA, Hedges AR, Thomas EM, Morley TR, Kakkar VV. Deep vein thrombosis after elective knee surgery. An incidence study in 312 patients. J Bone Joint Surg Br. 1989;71(3):492–497.[PubMed]
13. Fisher CG, Blachut PA, Salvian AJ, Meek RN, O’Brien PJ. Effectiveness of pneumatic leg compression devices for the prevention of thromboembolic disease in orthopaedic trauma patients: a prospective, randomized study of compression alone versus no prophylaxis. J Orthop Trauma. 1995;9(1):1–7. [PubMed]
14. Lachiewicz PF, Kelley SS, Haden LR. Two mechanical devices for prophylaxis of thromboembolism after total knee arthroplasty. A prospective, randomised study. J Bone Joint Surg Br. 2004;86(8):1137–1141.[PubMed]
15. Hull R, Raskob G, Pineo G, Rosenbloom D, Evans W, Mallory T, et al. A comparison of subcutaneous low-molecular-weight heparin with warfarin sodium for prophylaxis against deep-vein thrombosis after hip or knee implantation. N Engl J Med. 1993;329(19):1370–1376. [PubMed]
16. Hull RD, Pineo GF, Francis C, Bergqvist D, Fellenius C, Soderberg K, et al. Low-molecular-weight heparin prophylaxis using dalteparin extended out-ofhospital vs in-hospital warfarin/out-of-hospital placebo in hip arthroplasty patients: a doubleblind, randomized comparison. North American Fragmin Trial Investigators. Arch Intern Med. 2000;160(14):2208–2215. [PubMed]
17. Stewart DW, Freshour JE. Aspirin for the prophylaxis of venous thromboembolic events in orthopedic surgery patients: a comparison of the AAOS and ACCP guidelines with review of the evidence. Ann Pharmacother. 2013;47(1):63–74. [PubMed]
18. Palmer AJ, Koppenhagen K, Kirchhof B, Weber U, Bergemann R. Efficacy and safety of low molecular weight heparin, unfractionated heparin and warfarin for thrombo-embolism prophylaxis in orthopaedic surgery: a meta-analysis of randomised clinical trials. Haemostasis. 1997;27(2):75–84. [PubMed]
19. Mont MA, Jacobs JJ. AAOS clinical practice guideline: preventing venous thromboembolic disease in patients undergoing elective hip and knee arthroplasty. [[cited 2014 Jan 19]];J Am Acad Orthop Surg. 2011 Dec 19(12):777–8. [Internet] Available from: http://www.ncbi.nlm.nih.gov/pubmed/22134210 . [PubMed]
20. Lassen MR, Gallus A, Raskob GE, Pineo G, Chen D, Ramirez LM. Apixaban versus enoxaparin for thromboprophylaxis after hip replacement. N Engl J Med. 2010;363(26):2487–2498. [PubMed]
21. Eriksson BI, Dahl OE, Rosencher N, Kurth AA, van Dijk CN, Frostick SP, et al. Oral dabigatran etexilate vs. subcutaneous enoxaparin for the prevention of venous thromboembolism after total knee replacement: the RE-MODEL randomized trial. J Thromb Haemost. 2007;5(11):2178–2185. [PubMed]
22. Eriksson BI, Borris LC, Friedman RJ, Haas S, Huisman MV, Kakkar AK, et al. Rivaroxaban versus enoxaparin for thromboprophylaxis after hip arthroplasty. N Engl J Med. 2008;358(26):2765–2775.[PubMed].
23. Jameson SS, Rymaszewska M, Hui ACW, James P, Serrano-Pedraza I, Muller SD. Wound complications following rivaroxaban administration: a multicenter comparison with low-molecular-weight heparins for thromboprophylaxis in lower limb arthroplasty. J Bone Joint Surg Am. 2012;94(17):1554–1558. [PubMed].

How to Cite this article: Rai S K, Raman V P, Shejale N, Wani S S, Varma R. To study the efficacy and safety of Rivaroxaban in the prevention of venous thromboembolism after Total Hip and Knee Arthroplasty. Trauma International Sep – Dec 2017;3(2):3-7.

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Acute Complete Acromioclavicular Dislocations: A Prospective Multicenter Therapeutic Study Comparing Combined Intra-articular and Extra-articular Fixation with Intra-articular K-wire Fixation

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Vol 3 | Issue 2 | Sep – Dec 2017 | page: 21-24 | Biswajit Sahu, Ranajit Panigrahi, Nishit Palo, Ashok Priyadarshi, Saswat Samant

Author: Biswajit Sahu [1], Ranajit Panigrahi [2], Nishit Palo [3], Ashok Priyadarshi [4], Saswat Samant [5].

[1] Department of Orthopaedics, VSS Medical College.
[2] Department of orthopedics, Hi-Tech Medical College
[3] Department of Orthopaedics, Santosh Medical College,Ghaziabad, UP.
[4] Department of orthopedics, Hi-Tech Medical College, Bhubaneswar

Address of Correspondence
Dr Saswat Samant
Department of Orthopaedics, Hi-tech Medical College
Bhubaneswar.
Email: Saswatsamant135@gmail.com

Learning Points for this Article: Isolated intra-articular K-wire fixation also fails to provide the required stability to the injured joint, especially in developing countries, where patients fail to adhere to the rehabilitation protocol. Thus, combining both, the intra-articular and coracoclavicular fixations seem to be a promising modality in terms of stability and secure fixation. Combining the intra- and extra-articular techniques significantly decreases the complication rates as seen with the isolated fixation techniques.

Abstract

The AC joint is commonly involved in traumatic injuries that affect the shoulder.Treatment of these injuries has been controversial and continues to evolve to this day ranging from conservative management and k-wire fixations to screw fixation, and more recently, arthroscopically assisted ligament reconstructions with no definite consensus about the ideal method of treatment.Each modality has its own advantages and disadvantages. In this prospective therapeutic multicenter study, we compared combined intra-articular fixation and screw coracoclavicular repair versus the intra-articular fixation with k-wires alone to assess the stability, failure rates, and outcomes of combining the two methods of fixation versus isolated intra-articular fixation.combining both, the intra-articular and coracoclavicular fixations seem to be a promising modality in terms of stability and secure fixation. Combining the intra- and extra-articular techniques significantly decreases the complication rates as seen with the isolated fixation techniques.
Keywords: Acromioclavicular dislocations, intra-articular, multicenter.

References

1. Simovitch R, Sanders B, Ozbaydar M, Lavery K, Warner JJ. Acromioclavicular joint injuries: Diagnosis and management. J Am Acad Orthop Surg 2009;17(4):207-219.
2. Galatz LM, Hollis Jr RF, Williams Jr GR. Acromioclavicular Joint Injuries. Rockwood and Green’s Fractures in Adults. 7th ed. Philadelphia: Lippincott Williams & Wilkins; 2010. p. 1210-1242.
3. De Carli A, Lanzetti RM, Ciompi A, Lupariello D, Rota P, Ferretti A. Acromioclavicular third degree dislocation: Surgical treatment in acute cases. J Orthop Surg Res 2015;10(1):13.
4. Saccomanno MF, Fodale M, Capasso L, Cazzato G, Milano G. Reconstruction of the coracoclavicular and acromioclavicular ligaments with semitendinosus tendon graft: A pilot study. Joints 2014;2(1):6-14.
5. Steinbacher G, Sallent A, Seijas R, Boffa JM, Espinosa W, Cugat R. Clavicular hook platefor grade-III acromioclavicular dislocation. J Orthop Surg (Hong Kong) 2014;22(3):329-332.
6. Zhu YY, Cui HY, Jiang PQ, Wang JL. Complications of treatment of acromioclavicular joint dislocation and unstable distal clavicular fracture with clavicular hook plate. Zhongguo Gu Shang 2013;26(11):927-931.
7. Virtanen KJ, Savolainen V, Tulikoura I, Remes V, Haapamäki V, Pajarinen J, et al. Surgical treatment of chronic acromioclavicular joint dislocation with autogenous tendongrafts. Springerplus 2014;3:420.
8. Stucken C, Cohen SB. Management of acromioclavicular joint injuries. Orthop Clin North Am 2015;46(1):57-66.
9. Tidwell JE, Kennedy PM, McDonough EB. Concurrent treatment of a middle-third clavicle fracture and Type IV acromioclavicular dislocation. Am J Orthop (Belle Mead NJ) 2014;43(11):E275-E278.
10. Pan Z, Zhang H, Sun C, Qu L, Cui Y. Arthroscopy-assisted reconstruction of coracoclavicular ligament by Endobutton fixation for treatment of acromioclavicular joint dislocation. Arch Orthop Trauma Surg 2015;135(1):9-16.
11. Williams GR, Nguyen VD, Rockwood CR. Classification and radiographic analysis of acromioclavicular dislocations. Appl Radiol 1989;12:29-34.
12. Tossy JD, Mead NC, Sigmond HM. Acromioclavicular separations: Useful and practical classification for treatment. Clin Orthop Relat Res 1963;28:111-119.
13. Adams FL. The Genuine Works of Hippocrates. Vol. 1-2. New York: William Wood &Company; 1886.
14. Bearn JG. Direct observations on the function of the capsule of the sternoclavicular joint in clavicular support. J Anat 1967;101(Pt 1):159-170.
15. Cadenat FM. The treatment of dislocations and fractures of the outer end of the clavicle. Int Clin 1917;1:145-169.
16. Weaver JK, Dunn HK. Treatment of acromioclavicular injuries, especially complete acromioclavicular separation. J Bone Joint Surg Am 1972;54(6):1187-1194.
17. Wolf EM, Pennington WT. Arthroscopic reconstruction for acromioclavicular joint dislocation. Arthroscopy 2001;17(5):558-563.
18. Lancourt JE. Acromioclavicular dislocation with adjacent clavicular fracture in a horseback rider. A case report. Am J Sports Med 1990;18(3):321-322.

How to Cite this article: Sahu B, Panigrahi R, Palo N, Priyadarshi A, Samant S. Acute Complete Acromioclavicular Dislocations: A Prospective Multicenter Therapeutic Study Comparing Combined Intra-articular and Extra-articular Fixation With Intra-articular K-wire FixationTrauma International Sep-Dec 2017;3(2):21-24.

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New Comprehensive Classification Systems for Peri-trochanteric Femur Fractures

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Vol 3 | Issue 2 | Sep – Dec 2017 | page: 31-34 | Aditya K. Agrawal

Author: Aditya K. Agrawal [1].

[1]Dept of Orthopaedics, Dhiraj Hospital, SBKS MIRC, SumandeepVidyapeeth, Waghodia, Vadodara, Gujarat, 391760 India.

Address of Correspondence
Dr. Aditya K. Agrawal
Dept of Orthopaedics, Dhiraj Hospital,
SBKS MIRC, SumandeepVidyapeeth, Waghodia,
Vadodara, Gujarat, 391760 India.
Email: adityagrawal83@gmail.com

Abstract

Purpose: A classification is considered as good classification if it describes the particularregion of bone, type of fracture, personality of fracture in either planes and helps in selectionof implant and most importantly easy to understand by an orthopedic surgeon. Classification becomes more complicated when there is double region involvement with comminution,or distal fracture is in shaft leading to segmental fracture.
Materials and Methods: There are numerous classification systems available in the presentliterature for peri-trochanteric femur fractures. These include Evan’s, Tronzo, and Boyd andGriffin, OTA classifications for peri-trochanteric region, Seinsheimer’s and Fieldingclassifications for sub-trochanteric region. AO classification which is widely acceptedcritically defines peri-trochanteric, head and neck region of fracture femur.
Results: Drawbacks of existing classifications are that they are based on fractureconfiguration in sagittal plane only except Seinsheimer’s classification which is based oncoronal plane fracture morphology. Furthermore, double regions/ multiple regions arenot properly defined in these classification systems. If the proper classification system is not followed, it will lead to the selection of wrong implants which thereby leads to complications.
Discussion: Advantages of our new classification system are that it is easy to understand; allregions of peri-trochanteric femur are covered, and in the selection of proper implant.Hence, intra-operative complications can be avoided with proper pre-operative planning.
Conclusion: Thus, we hope that our new comprehensive classification of peri-trochantericfemur may help to solve the mysteries surrounding the understanding, classifying, and treating the fractures of peri-trochanteric femur.
Keywords: Classification, comprehensive, femur, fracture, peri-trochanteric.

References

1. Marks R. Hip fracture epidemiological trends, outcomes, and risk factors, 1970-2009. Int J Gen Med 2010;3:1-17.
2. Chang KP, Center JR, NguyenTV, Eisman JA. Incidence of hip and other osteoporotic fractures in elderly men andwomen: Dubbo osteoporosis epidemiology study. J Bone Miner Res 2004;19:532-6.
3. Saudan M, Lubbeke A, Sadowskil C, Riand N, Stern R, Hoffmeyer P,.“Per-trochanteric fractures: Is there an advantage to an intramedullary nail: A randomized prospective study of 206 patients comparing the dynamic hip screw and proximal femoral nail,”. JOrthopTrauma, 2002; 16,386-93.
4. Pajarinen J,Lindahl J, Michelsson O, Savolainen V, Hirvensalo E. Pertrochanteric femoralfractures treated with a dynamic hip screw or a proximal femoral nail. A randomised study comparing post-operative rehabilitation. J Bone Joint Surg Br 2005;87:76-81.
5. Baumgaertner MR, Curtin SL, Lindskog DM. Intramedullary versus extramedullary fixation for the treatment of intertrochanteric hip fractures. Clin OrthopRelat Res 1998;348:87-94.
6. DavisTR, Sher JL, Horsman A, Simpson M, Porter BB, Checketts RG. Intertrochanteric femoral fractures. Mechanical failure after internal fixation. J Bone Joint Surg Br 1990;72:26-31.
7. Adams C.I, Robinson C. M, Court-Brown C.M, and Mcqueen M.M. “Prospective randomized controlled trail of an intramedullary nail versus dynamic screw and plate for intertrochanteric fractures of the femur,.” JOrthopTrauma, 2001; 15, 394-400.
8. Gadegone WM, Salphale YS. Proximal femoral nail-an analysis of 100 cases of proximal femoral fractures with an average follow up of 1 year. IntOrthop 2007;31:403-8.
9. Ballal MS, Emms N,Thomas G. Proximal femoral nail failures in extracapsular fractures of the hip. JOrthopSurg (Hong Kong) 2008;16:146-9.
10. Flores LA, Harrington IJ, Heller M.The stability of intertrochanteric fractures treated with a sliding screw-plate. J BoneJoint Surg Br 1990;72:37-40.
11. Bridle S.H, Patel A.D, Bircher M,. (1991) “Fixation of intertrochantericfractures of the femur: A randomized prospective comparison of the gamma nail anddynamic hip screw,”.J Bone Joint Surg, 1991; 73,330-4.
12. Halder SC.The Gamma nail for peritrochanteric fractures. J Bone Joint Surg Br 1992;74:340-4.
13. Schipper IB, Steyerberg EW, Castelein RM, van der HeijdenFH, den Hoed PT, Kerver AJ, et al. Treatment of unstable trochanteric fractures.Randomised comparison of the gamma nail and the proximal femoral nail. J BoneJoint Surg Br 2004;86:86-94.
14. Morihara T, Arai Y,Tokugawa S, Fujita S, Chatani K, Kubo T. Proximal femoral nail for treatment oftrochanteric femoral fractures. J OrthopSurg (Hong Kong) 2007;15:273-7.

How to Cite this article:  Agrawal A. K. New Comprehensive Classification Systems for Peri-trochanteric Femur Fractures. Trauma International Sep-Dec 2017;3(2):31-34.

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Percutaneous Release of Trigger Finger: A Safe And Cost effective Procedure

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Vol 3 | Issue 2 | Sep – Dec 2017 | page: 25-27 | Vinod Nair, Amit Chaudhary, Clevio Desouza, Harshal Hurkat, Shiju George

Author: Vinod Nair [1], Amit Chaudhary [1], Clevio Desouza [1], Harshal Hurkat [1], Shiju George [1].

[1]Department Of Orthopaedics, Dr D.Y.Patil Hospital, Pune, Maharashtra, India.

Address of Correspondence
Dr. Clevio Desouza
D. Y. Patil Medical College, Pimpri, Pune ,Maharashtra

Email: cleviod@yahoo.com

Learning Points for this Article: This articles shows us that although in its initial stages percutaneous release of trigger finger is a safe and cost effective procedure.

Abstract

Introduction: Trigger finger is a common cause of pain and disability of the hand. Trigger finger (or thumb) arises either from thickening of the flexor tendon sheath (which occurs following tenosynovitis of infective, traumatic or rheumatolgical origin) or from nodular thickening of the flexor tendon itself which may be congenital. Percutaneous release results in earlier functional recovery and patient satisfaction. This is a cost-effective and rapid method which saves a surgical procedure and results in a better functional outcome.
KeyWords: Trigger finger, percutaneous release, outpatient treatment, cost-benefit analysis.

References

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How to Cite this article:  Nair V, Chaudhary A , Desouz C, Hurkat H, George S. Percutaneous Release of Trigger Finger: A Safe and Cost effective Procedure. Trauma International Sep-Dec 2017;3(2):25-27.

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Evaluation of Radiological and Functional Outcome of Calcaneum Fractures using Essex-Lopresti Technique of Reduction

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Vol 3 | Issue 2 | Sep -Dec 2017 | page: 28-30 | Atul A Kharat, Sandeep R Biraris, Pramod P Chikhalikar, Sheran Ali, G Krishna Naresh Goud

Author: Atul A Kharat [1], Sandeep R Biraris [2], Pramod P Chikhalikar [3], Sheran Ali [1], G Krishna Naresh Goud [2].

[1]Department of Orthopaedics, Pad. Dr D Y Patil Medical College & Hospital, Nerul, Navi Mumbai.
[2]Department of Orthopaedics, Mumbai Port Trust Hospital, Wadala (E), Mumbai.
[3]Department of Orthopaedics, Pad. Dr D Y Patil Medical College, Pune.

Address of Correspondence
Dr. Sandeep R Biraris,
Department of Orthopaedics, Mumbai Port Trust Hospital, Wadala (E), Mumbai, Maharashtra-400037.
Email: drsandeeprb@gmail.com

Learning Points for this Article: This articles states about various treatment modalities about management of the calcaneum fractures, it shows that non-displaced fractures can be treated conservatively and also Bohler’s and Gissane’s angles should be maintained post-operatively to have a good functional outcome.

Abstract

Background: Calcaneum fractures account for approximately 2% of all fractures, with displaced intra-articular fractures comprising 60-75% of these injuries of which 10% have associated spine fractures and 26% are associated with other extremity injuries. Several authors have reported that patients may be totally incapacitated for up to 3 years and partially impaired for up to 5 years post injury, Although modern surgical techniques have improved the outcome, controversy still exists regarding classification, treatment, operative technique, and post-operative management.
Materials and Methods: 28 out of 31 cases were analyzed prospectively and retrospectively from July 2011 to August 2013 after local ethical and scientific clearance. Three patients had lost to follow-up. All patients with calcaneum fractures above age of 18 with either simple or open injuries were included in the study, excluding pediatric and complex injuries. All patients were clinically evaluated and Bohler’s, Gissane’s angles were calculated preoperatively. All patients were treated with one of the modalities, which include conservative, Steinmann pinning, and Calcaneum plate fixation. All patients were followed up in outpatient basis fortnightly for 3 months and on 6th month and 1 year respectively, to check signs of union of fracture, subtalar movements, and complications if any. After radiological evaluation, functional outcome assessment was done using American Orthopaedic Foot and Ankle Society
Results: Mean age was 35.1 with range 20-52 years, male to female ratio of 9:1. 85% were due to high-velocity trauma. The most common type of injury was tongue type. Preoperative mean Bohler’s and Gissane’s angles which were about 14.87 and 121.5 degrees respectively, the improved angles postoperatively were 25.68 and 104.37 degrees. One patient had heel pain, one patient had residual edema, one patient developed subtalar and ankle stiffness, there was one case of tendocalcaneus weakness, one with broadening of heel, and one case of wound infection.
Conclusion: Undisplaced or minimally displaced calcaneum fractures are best-treated conservatively with cast immobilization for 6 weeks. Essex-Lopresti technique of reduction was superior technique for displaced fractures and achievement of Bohler’s and Gissane’s angle to the after reduction was judgemental for optimal functional outcome.
Keywords: Calcaneum, Essex-Lopresti, functional outcome.

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How to Cite this article:  Kharat AA, Biraris SR, Chikhalikar PP, Ali S, Goud GKN. Evaluation of Radiological and Functional Outcome of Calcaneum Fractures using Essex-Lopresti Technique of Reduction. Trauma International Sep-Dec 2017;3(2):28-30.

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