The Taylor Spatial Frame (TSF) is an external fixator used by podiatric and orthopaedic surgeons to treat complex fractures and bone deformities. The medical device shares a number of components and features of the Ilizarov apparatus. The Taylor Spatial Frame is a hexapod device based on a Stewart platform, and was invented by orthopaedic surgeon Charles Taylor. The device consists of two or more aluminum or carbon fibre rings connected by six struts. Each strut can be independently lengthened or shortened to achieve the desired result, e.g. compression at the fracture site, lengthening, etc. Connected to a bone by wires or half pins, the attached bone can be manipulated in six axes (anterior/posterior, varus/valgus, lengthen/shorten.) Angular, translational, rotational, and length deformities can all be corrected simultaneously with the TSF. TAYLOR SPATIAL FRAME and TSF are trademarks of global orthopaedics company, Smith & Nephew.
The TSF is used in both adults and children. It is used for the treatment of acute fractures, mal-unions, non-unions and congenital deformities. It can be used on both the upper and lower limbs. Specialised foot rings (as seen in the picture) are also available for the treatment of complex foot deformities.
Video Taylor Spatial Frame
Post Operative procedure
Correcting deformities
Once the fixator is attached to the bone, the deformity is characterised by studying the postoperative x-rays, or CT scans. The angular, translational, rotational, and length deformity values are then entered into specialised software, along with parameters such as the ring size and initial strut lengths. The software then produces a "prescription" of strut changes that the patient follows. The struts are adjusted daily by the patient until the correct alignment is achieved.
Correction of the bone deformity can typically take 3-4 weeks. For simpler fractures where no deformity is present the struts may still be adjusted post-surgery to achieve better bone alignment, but the correction takes less time. For individuals performing strut adjustment. a hand mirror may be useful to aid in reading the strut settings.
Once the deformity has been corrected, the frame is then left on the limb until the bone fully heals. This often takes 3-6 months, depending on the nature and degree of deformity.
Dynamisation
When the bone has sufficiently healed, the frame is dynamised. This is a process of gradually reducing the supportive role of the frame by loosening the struts one at a time. This causes force that was previously transmitted around the fracture site and through the struts to be transmitted through the bone.
Removal of frame
After a period of dynamisation, the frame can be removed. This is a relatively simple procedure often performed under gas and air analgesic.
The rings are removed by cutting the olive wires using wire cutters.
The wires are then removed by first sterilising them and then pulling them through the leg using pliers. The threaded half pins are simply unscrewed.
Maps Taylor Spatial Frame
Use for fractures
External fixation via TSFs tends to be less invasive than internal fixation and therefore has lower risks of infection associated with it. This is particularly relevant for open fractures.
For open comminuted fractures of the tibial plateau the use of circular frames (like TSF) has markedly reduced infection rates.
The time taken for bones heal (time to union) varies depending on a number of factors. Open fractures take longer to heal, and infection will delay union. For tibial fractures union is generally achieved between 3 and 6 months
though to union can be a rather subjective, and the dynamistion process combined with irregular appointment may interfere with these measures.
Infection
Infection of the pin sites (points where wires enter the skin) of the TSF is a common complication (estimates are that it affects 20% percent of patients). In extreme cases this can result in osteomylitis which is difficult to treat. However, pin site infections are normally successfully treated with a combination of oral antibiotics, intravenous antibiotics, or removal of the affected pin.
Pin sites are classified as percutaneous wounds
Best practice for maintenance of pin sites is unclear and requires more study. Common practice involves the regular cleaning of the pin sites with chlorhexidine gluconate solution (advice varies from every day to every week), regular showering, and dressing of sites that exude liquid with non-woven gauze soaked in chlorhexidine gluconate. This dressing can be held in place with bungs or makeshift clips or by twisting around the wire.
Advice varies as to whether scab tissue or any "crust" surrounding a pin site should be maintained. With some literature arguing that this acts as a barrier to entry, while other literature argues this may increase the risk of infection.
Cost of treatment
The taylor spatial frame is general tool for fixating and moving bone fragments in a gradual way. This means that costs can vary dramatically.
The cost of a frame itself was around 2,500 pounds sterling in 2006 though this cost will vary depending on the number of components in the frame.
Cases involving treatment of nonunion of fracture are complicated and time-consuming with costs of around 30,000 pounds sterling in 2006 and treatment can take between 1 and 2 years. Of these costs about 23,000 pound sterling reflect follow-up outpatient treatment and cost for hospital stays, which can vary dramatically between patients.
Further reading
- Choudhuri, Milind (2008). "Taylor Spatial Frame". In Kulkarni, G.S. Textbook of orthopedics and trauma (2nd ed.). Jaypee Brothers Publishers. ISBN 9788184482423.
- US Active 6129727A, Ed Austin; Anthony James & James E. Orsak, "Orthopaedic spatial frame apparatus", published 2000-10-10, assigned to Smith and Nephew Inc
See also
- Distraction osteogenesis
- Bone fracture
- Trauma surgery
- Traumatology
- External fixation
References
External links
- Information on Taylor Spatial Frame (TSF), design, geometry, advantages and limitations
- Smart Correction Application for Hexapod Fixator with Radiographic Navigation Software
Source of the article : Wikipedia