INTRODUCTION BONE HEALING Events in fracture healing are responsible for debridement, stabilization, and ultimately remodeling of the fracture site. Healing can take place either primarily, in the presence of rigid fixation, or secondarily in the absence of a rigid fixation. PRIMARY BONE HEALING Occurs with direct and intimate contact between the fracture fragements. The new bone grows directly across the compressed bone ends to unite the fracture. Primary cortical bone healing is very slow and cannot bridge fracture gaps. There is no radiographic evidence of a bridging callus with this mode of healing. It usually occurs approximately 2 weeks from the time of surgery. This is the only method of healing with rigid compression fixation of the fracture. Rigid fixation requires direct cortical contact and an intact intramedullary vasculature. 1
Transcript
INTRODUCTION
BONE HEALING
Events in fracture healing are responsible for debridement, stabilization, and ultimately remodeling of the fracture site.
Healing can take place either primarily, in the presence of rigid fixation, or secondarily in the absence of a rigid fixation.
PRIMARY BONE HEALING
Occurs with direct and intimate contact between the fracture fragements. The new bone grows directly across the compressed bone ends to unite the
fracture. Primary cortical bone healing is very slow and cannot bridge fracture gaps. There is no radiographic evidence of a bridging callus with this mode of
healing. It usually occurs approximately 2 weeks from the time of surgery. This is the only method of healing with rigid compression fixation of the
fracture. Rigid fixation requires direct cortical contact and an intact intramedullary
vasculature.
SECONDARY HEALING
It denotes mineralization and bony replacement of a cartilage matrix with a characteristic radiographic appearance of callus formation.
The greater the motion at the fracture site, the greater will be the quality of the callus.
This external bridging callus adds stability to the fracture site by increasing the bone width.
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This occurs with casting and external fixation as well as intramedullary nailing of the fracture.
Fracture healing
There are three main phases of fracture healing
A. INFLAMMATORY PHASE
In the inflammatory stage, a hematoma develops within the fracture site during the first few hours and days.
Inflammatory cells (macrophages, monocytes, lymphocytes, and polymorphonuclear cells) and fibroblasts infiltrate the bone under prostaglandin mediation.
This results in the formation of granulation tissue, ingrowth of vascular tissue, and migration of mesenchymal cells.
The primary nutrient and oxygen supply of this early process is provided by the exposed cancellous bone and muscle.
B. REPARATIVE PHASE
This phase lasts several months.
The fracture hematoma is then invaded by chondroblasts and fibroblasts, which lay down the matrix for the callus.
Initially a soft callus is formed, composed mainly of fibrous tissue and cartilage with small amounts of bone.
Osteoblasts are then responsible for mineralization of this soft callus, converting in to a hard callus of woven bone and increasing the stability of the fracture
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This type of bone is immature and weak in torque and therefore cannot be stressed.
C. REMODELLING STAGE
It takes months to years.
It consists of osteoclastic and osteoblastic activities that results in replacement of immature disorganized bone with a mature organized bone.
The medullary canal gradually reforms.
There is resorption of bone from the convex surface and new bone formation on the concave surface.
BIOMECHANICAL PRINCIPLES OF FIXATION DEVICES3
Many types of devices are used for fracture fixation.
The biomachanics of fixation are based on either stress sharing or stress shielding devices.
STRESS-SHARING DEVICE
It permits partial transmission of load across the fracture site.
This results in micromotion at the fracture site, thus inducing secondary healing with callus formation.
Eg:- casts, rods and intramedullary nails.
STRESS- SHEILDING DEVICES
It shields the fracture site from stress by transferring stress to the device.
The fracture ends of the bone are held under compression and there is no motion at the fracture site.
Hence resulting in primary bone healing without callus formation.
Eg:-compression platting.
Biomechanics Type of bone Rate of bone
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healing healing
Casts Stress sharing Secondary Fast
Plates Stress shielding Primary Slow
Pin, screws or wire
Stress sharing Secondary Fast
External fixator Stress sharing Secondary Fast
PLASTER CASTS5
INTRODUCTION
The closed treatment of fractures generally consisits of some form of manipulation or reduction followed by application of device to maintain the reduction until healing has occurred.
REDUCTION
The sooner the reduction of a fracture is attempted the better, because swelling of the extremity tends to increase for 6-12 hrs after the injury. This haemorrhage and oedema in the soft tissues make them inelastic and pose a barrier to adequate reduction.
Contraindications of closed reduction
There is no significant displacement
This displacement is little concern(eg. Humeral shaft)
No reduction is possible(eg. Communited fracture of head and neck of humerus)
The fracture has been produced by traction force(eg.displaced fracture of patella)
To achieve reduction following steps are adviced:-
Traction in the long axis of the bone
Reverse the mechanism that produced by the fracture
Align the fragment that can be controlled with the one that cannot
PLASTER CASTS6
It is one of the methods of immobilization. It is done once the satisfactory reduction has been achieved and must be manipulated until primary union has taken place.
The efficiency of plaster immobilization
The object of applying POP casts is to keep the bone ends in apposition and fracture aligned until it heals. It has been said that immobilization by the plaster will work only where the soft tissue is intact, where there is inherent stability of the reduced fracture and where the cast is properly applied.
When a bone is fractured and not widely separated, the soft tissue hinge in the concavity of the angulation is the linkage that allows us to reduce the fracture with manipulation.
3-POINT FIXATION
This should be obtained in fracture modulating cast. For this, one hand must exert pressure over the fracture site on the side opposite to soft tissue bridge, while the other hand gently massages the distal fragment in the proper direction to close gap. Third force is supplied by the portion of the cast over the proximal portion of the limb.
Charnel adviced- it takes a curved cast to produce a straight bone, he divided fractures in to three categories:
Those with inherent stability against shortening(transverse fractures)
Those with potential stability against shortening(oblique fractures less than 45 degrees to long axis of bone.
Those with no stability against shortening( oblique, spiral & comminuted fractures)
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However, there is another factor- the hydrodynamic effect of cast. Because the soft tissues are semifluid, the hydrostatic pressure increases when they are compressed by a cast. This increase in tension tends to keep the limb from shortening as it is most certainly would do where it is unsupported. This factor makes possible early ambulation in fracture of tibia.
Types of cast with there specific uses:
1. Flexion body jacket
It is the most commonly used to treat low back pain.
The purpose of this cast is to provide three point fixation, straightening increased lordosis of lumbar spine, increasing intraadominal pressure by compression on the abdomen.
The patient should remain fairly active and do both abdominal and spinal muscle strengthening exercises while in the cast.
2. Hyperextension body jacket
It is commonly used for the treatment of compression fractures of spine in the thoracolumbar region.
3. Plaster bolero
Used in treating unstable fractures of clavicle that requires hyperextension of shoulders to maintain the position.
4. Minerva cast
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5. Plaster velpu
Is generally used only as a soft tissue dressing to immobilize the shoulder or humerus.
6. Short arm cast
Can be used to immobilse the wrist and base of finger metacarpals
7. Muenster short arm cast
Is used to immobilize the forearm & wrist when flexion- extension can be done of the elbow but limited supination and pronation.
8. Hanging arm cast
Used to treat humerus fractures
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9. Gauntlet cast
Used to immobilize fractures of metacarpals of hand and for minor injuries of wrist
INDICATIONS
1) Fracture in children: internal fixation is almost not indicated in children except for displaced intratrochanteric fractures, some avulsion fractures who have severe life threatening multiple injuries. Children have tremendous capacity to remodel bone as they grow. Non union is rarely a problem in them. Majority of children very quickly regain mormal ROM and strength. For these reasons, these fractures are always treated with closed technique.
2) Undisplaced fractures
3) Poor bone quality: with aging population, osteoporosis is becoming a common problem. Osteoporotic bone is very difficult to fix internally and commonly therefore non surgical methods are indicated in very elderly
4) Systemic contraindication to surgery
5) Local contraindications to surgery: severe skin lesion, local skin infection or other soft tissue condition
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CONTRAINDICATIONS
1) Pressure sores: most commonly over edges, at the edges of the cast
2) Burns: as the exothermic reaction of setting takes place in plaster and fiberglass materials, enough heat is generated to cause a severe burn, particularly if there is no way for heat to dissipate. Common in patients with sensory loss.
3) Allergic dermatitis
4) Vascular compromises, compartment syndrome and nerve injury
5) Malposition
6) Stiffness, disuse, RSD
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BONE SCREWS
A bone screw is used for internal fixation more often than any other implant
Though it appears as a simple device, it has a great deal of complex design.
It has four functional parts: Head, Shaft, Threads and Tip.
HEAD
The screw head serves as an attachment for the screw driver.
Is essential while removing and insertion of the screw.
The undersurface of the screw is the countersink.
SHAFT
The shaft is the smooth part of the screw between the head and the thread.
RUN-OUTS
It is the spot where the shaft ends and the thread begins.
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THREAD
It is wrapped around the core which provides the main support of the screw.
PITCH
It defines the distance between the adjacent threads
LEAD
The distance the screw will advance with each turn, the lead is therefore equal to the pitch.
PRINCIPLE
It provides interfragmentary compression which improves mechanical stability of internal fixation between bone fragments by minimizing the effect of torsion, shear and bending forces.
FUNCTION
It is used either to fasten plates or similar devices on to the bones or as lag screws, to hold together fragements of bones.
TYPES OF SCREWS
CORTICAL SCREWS
It is a machine type of screw.
The threads are smaller (in diameter) and are closely placed ( lower pitch).
The core diameter is relatively large and provides the necessary strength.
The smaller pitch increases the holding power.
Threads are cut in the pilot hole before the screw is inserted.13
The elastic reaction vital to hold the bone surfaces together, comes from elastic deformation of the bone rather than the screw.
Advantage : more engagement of screw threads in to the bone is possible because taps provide four cutting flutes, micro- motion of bone is less likely to occur, therefore these procedures better hold the screw
Disadvantages: it require extra step in operative procedure and because rather smooth track is established, it is more likely to loosen by backing out when it is subjected to cylindrical; stress.
CANCELLOUS SCREW
It is a modified wooden type of screw.
It has larger threads and a higher pitch as compared to the cortical screws.
The core diameter which is smaller than the shaft, provides a greater surface area for purchase of the screw threads on the bone.
It is inserted in to an untapped pilot hole.
Uses: used as fastening devices such as plates in metaphyseal and epiphyseal areas
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Advantages:
i. Holding power in fine trabecular bone is more.
ii. Tapping is not usually required because cancellous bone is fairly soft and easily deformed.
iii. As the screws penetrate, it compressesthe bone to either side, thereby increasing the bone density in the immediate vicinity of the thread, this improves the holding power.
iv. Typically they have smooth shank in poetion immediately adjacent to screw head so that an automatic lag effect occurs without having to overdrill the near cortex
Disadvantage: when used without a plate they are more prominent
CANNULATED SCREWS
It is used for precise insertion in metaphyseal or epiphyseal site over a guide wire.
This reduces the problem of having to remove and reposition an incorrectly placed screw.
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The guide wire also maintains the reduction and controls the fracture fragments.
Cancellous cannulated screws come in large and small sizes.
Large screws are used to fix fractures of the femoral neck, femoral condyle and tibial plateau.
Small cannulated screws are used for distal radius, distal humerus, distal and proximal tibia, carpals and scaphoid.
Advantages: it needs less soft tissue dissection.
Disadvantages: screws are weaker than non cannulated screw particularly in small fragement size, they break more easily when removal is attempted
THE HERBERT SCREW16
It is an specialized implant to achieve intrafragmentary compression.
In this unique device there is no head and threads are present at both the ends of the screws with a pitch differential between the leading and trailing screws.
Principle: intrafragmentary compression is achieved the differences in the threads.
LAG SCREW
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It is the most effective way to achieve compression between two bony fragments.
It pulls the fragments together producing pressure at the fracture line.
Compression between the fracture fragments increases the friction force so that interfragmentary motion is less likely and therefore strengthens the structure.
It achieves this by producing purchase on the distal fragment while being able to turn freely in the proximal.
Lag screw principle:
1. The screw must glide freely through the near fragment and engage only the far fragment.
2. Whenever a screw crosses a fracture line it should be inserted as a lag screw.
3. Two small screws produce a more stable fixation than one large screw.
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The lagging technique can be applied to virtually all of screws. In diaphyseal fractures a cortical screw is applied as a lag screw.
In epiphyseal or metaphyseal fractures cancellous screws are applied.
To effect maximal interfragmentary compression, lag screw must be inserted in to the centre of the fragments and at right angles to the fracture plane.
Uses: in communited fractures, in metaphyseal area, to achieve inter fragemental compression & stability.
Disadvantages: it does not provide great deal of strength, if while doing screw is inserted at an acute angle to fracture plane then as it is tightened it introduces a shearing moment and tends to displace the fragements causes loss of reduction.
NAILS
INTERLOCKING NAILS19
The intramedullary nailing techniques which are in common use today. They are derivd mainly from Gerhard kuntsher.
Biomechanics: interlocking nails act as internal splints, serving as load sharing devices stabilizing fracture fragements and maintaining alignment while permitting slight bending during functional activities, a thicker nailmay not allow bending by allowing the movement of the adjacent joints, rehabilitation is concurrent with treatment and stress shielding is minimal.
FRACTURE HEALING FOLLOWING NAILING
The peripheral circulation is generally maintained however, the remaining process causes additional damage. It has been observed that the small vessels grow in to the existing gaps between the bones and the nail is an astonishingly short period of time from where they penetrate in to the neighbouring malperfused cortical bone and initiate endosteal bone formation.
Tilt nails gives the best results. The healing of well done closed nailing and the shaft of tibia or the femur depends on the fracture geometry and the level of fracture healing in a biological process helped by mechanical stability.
INDICATIONS
1) All closed fractures of tibia
2) Aseptic non union
3) Pathological fractures
4) Deformity correction
5) Septic non union
6) Open fractures up to grade 3 tibial diaphyseal fractures
7) Limb lengthening procedures
8) Arthrodesis
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Advantages:
Fractures fixed with intramedullary nails displayed higher values for blood flow in the whole bone and at the fracture site which remained elevated for longer time than these managed with rigid plate fixation.
For the weight bearing bones, intramedullary nailing is a fixation because the location of the rod in intramedullary canal virtually guarantees proper axial alignment
Disadvantages
The size of the intramedullary canal may limit the size of the nail that can be used, this limits the bending strength of the nail unless extensive reaming performed.
Intramedullary nails particularly reamed nails interfere with the endosteal blood supply, which makes up to 90% of vascular supply to diaphysis of long bone.
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TYPES OF NAILS
1. REAMED NAILS
The classic reamed nail is hollow open section nail of kunscherz. Reaming provides precise fit for nail in intramedullary canal, thereby reducing the incidence of nail in correction and improving the stability of the fixation.
Reaming permits the use of longer nails which are stronger than the smaller ones.
2. Non reamed nails
Single, non reamed, non locking nails have been designed for most of long bones including femur, tibia, humerus and foreram bones.
Single non reamed nails are easy to insert and associated with improved preservation of endosteal blood supply and rapid revascularization.
There disadvantages include an increase likelihood of impaction during driving and because smaller nails must be used.
3. Locking nails
They have single non locking nails absolute. The only advantage of non locking single nails are their simplicity and low cost.
4. Specialized nails
These are based on locking principle;
i. Gamma nails: developed in a short designs for fixation of intratrochanteric fractures. Now they are available in long devices that function like reconstructive nail.
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ii. Alta nails: used in femur subtrochanteric fractures.
PINS
STEINMENN PINS23
Steinmann pins are rigid stainless steel pins of varying lengths, 4-6mm in diameter. After insertion a special stirrup is attached to the pin. The bohler stirrup allows the direction of the traction to be varied without turning the pin in the hole.
They are now a days threaded rather than the ones that are smooth, smooth pins tend to loosen rapidly, so they slip in and out, leading to soft tissue infection or osteomylitis of bone.
Indications
They are mainly used for traction through the femur, tibia, calcaneus
Complication
Pin traction infection
Ligamentous damage
Damage to epiphyseal growth plates when used in children
Depressed scars
DENHMANS PIN
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The denhman pin is identical to Steinmann pin accept for a short raised threaded length situated towards the end.
This threaded portion engages the bone cortex and reduces the risk of pin sliding.
This type of pin is particularly suitable for use in cancellous bone such as calcaneus or osteoporotic bone.
NEUFELD PIN
It is advantageous in elderly, medically unstable patients with impacted and non displaced femoral neck fractures.
TENSION BAND WIRING
If a fracture is to unite, it requires mechanical stability, which is obtained by
compression of the fracture fragments.
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Conversely, distraction or tension interferes with fracture healing.
Therefore, tension forces on a bone must be neutralized or, more ideally,
converted into compression forces to promote fracture healing.
This is especially important in articular fractures, where stability is essential
for early motion and a good functional outcome.
In fractures where muscle pull tends to distract the fragments, such as
fractures of the patella or the olecranon, the application of a tension band
will neutralize these forces and even convert them into compression when
the joint is flexed.
Similarly, a bone fragment can be avulsed at the insertion of a tendon or
ligament.
Examples include the greater tuberosity of the humerus the greater
trochanter of the femur, or the medial malleolus. Here, too, a tension band
can reattach the avulsed fragment, convert tensile force into compression
force allowing immediate motion of the joint.
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EXTERNAL FIXATORS
In the management of limb injuries, external skeletal fixations, wide variety of applications, now has a firm place in the armamentarium of technique available to trauma surgeon.
External fixations is a method of immobilizing fractures by means of pins passed through the skin and bone.
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In external fixation a minimum of metal exists inside the tissues, and the fracture elements are will realigned, distracted or compressed.
INDICATIONS:
1. Compound fractures
2. Closed fractures with severe associated soft tissue injuries; compartment syndrome
3. Limb injuries requiring plastic and vascular procedures.
4. Stress shielding device to protect internal fixation
5. Infected non unions
6. Poly traumatized patients
7. Selected fractures of the pelvis
There are two types main types of external fixators: Pin fixator and Ring fixator
PIN FIXATOR
They are applied quickly to stabilize most diaphyseal fractures.
Also wound access is adequate for management of soft tissue injuries.
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Disadvantages:
1. The fracture needs to be reduced before constructing the frame.
2. The presence of a fixed bar, limits adjustability of the frame to control angulatory and rotatory deformities,
3. It does not allow axial loading at the fracture site.
4. There is high incidence of delayed union and non union.
5. Not suitable for ankle and pelvis fractures.
RING FIXATOR
In this mode of external fixator, the frames have a major role to play in complex reconstructions.
These frames replicate the structure of a long tubular bone and are somewhat like exoskeletal.
The bone is stabilized by tensioned wires acting like an elastic band.
The frame gives stability for the fracture.
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Fracture healing is better than in the pin fixator as weight bearing produces micromovements that favour faster healing.
DISADVANTAGES:
1. They are heavy and cumbersome
2. It is a time consuming procedure
3. There is a risk of neurovascular damage as the pins and wires transverse the entire thickness of the bone.
4. Oedema is a commoner occurrence in unilateral frames.
USES
1. Progressive deformity correction
2. Limb lengthening and
3. Management of non union.
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Basic componenets of an external fixator
Bone screws or pins
Clamps
Couplings
Central body
Compression-distraction system
1. The pin (schanz screw, half pins)
The stabilizing hold on a bone segment is obtained through a specialized bone pin that does not pass much beyond the far cortex
This pin has threads at one end and a rounded tip at the other end.
The half pin is a main stay of the external fixator. It is a modified cortical screw and it is only used as a hold fast, it does not exert intrafragmentary compression as cortical screws.
A Steinmann pin is also used which passes through the bone.
2. The clamp
It provides a connection between the pins and the other components of the fixator.
There are two types, in the first type an indivisual pin is fastened to the frame by a single pin tube articulation. The second type can attach a group of pins together and attach them to the main frame.
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3. The central body
The central body, a connecting rod or a tube is the mian structure of the fixator.
Increasing the number of rods, increases the rigidity of the frame.
4. Compression-distraction system
The compression- distraction assembly can be fixed to the main structure in special circumstances.
These devices are useful to apply compression at the fracture surface or bone interface.
5. Frames
The three dimensional structure built with the components of a fixator system is called a fixator frame, construct, or a fixator configuration.
It is a best suitable stabilization frame in regions where the local topography, anatomy and functional considerations make the erection of the double frame or a triangulated assembly impossible.
The stiffness of this frame in the saggital plane is is higher than in the bilateral uniplanar.
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The increased stiffness neutralizes most bending forces which tend to cause displacement of the fragements.
Indications: The frame is useful in stabilising humeral shaft, the ulna and radius and fracture femur and tibia.
Advantage: Walking is greatly facilitated and the patient can square or sit crossed legged, fewer skin entry holes reduce the possibility of bacterial contamination and the number of scars.
Disadvantages: There is no possibility of improving the reduction alignment once the frame is completed, also there is vulnerability of the anterior tibial crest; should infection occur the strongest portion of the tibia can be severly damaged.
Unilateral biplanar frame
It is the most stable of the unilateral frames and it is well for the treatment of tibial fractures since a large surface of that bone is subcutaneous.
Pins are inserted at various positions without going through muscles, tendons, nerves or vessels.
A unilateral biplanar frame is useful for prolonged application of the fixator in the presence of bone loss or severe soft tissue damage.
Bilateral uniplanar frame
Depending upon the stability produced by the lag screws, the bilateral uniplanar frame is either applied with a axial compression or used simply to neutralize bending and shearing forces.
In the presence of a bone defect or severe communition, one cannot apply compression for fear of producing shortening.
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The stability of this frame is improved by prestressing the Steinmann pins within each main fragement.
The symmetry of the bilateral uniplanar assembly has offers certain mechanical advantages over the unilateral uniplanar frame, it almost completely eliminates lateral movements of the fragements and it allows for uniform distribution of stress on the cortices and the external structure of the frame.
Bilateral biplanar frame
It offers greater torsional stability than other frames, with only a few additional pins.
The frame is useful in the presence of a large bony defect and in achieving arthrodesis of the knee and elbow.
This configuration neutralizes the bending movements in the ventrodorsal or saggital plane, which is of great advantage in the postoperative mobilization of the lower extremity after arthrodesis of the knee joint.
Modular frame
Unilateral uniplanar frame requires pins to be placed in a particular order and does not allow any variation to accommodate soft tissue conditions nor does it permit secondary correction without new pin placement.
In a modular frame which is a modification of the unilateral uniplanar frame, the pins are inserted as local condition demand.
The modular frame gives unnprecendented freedom of pin placement and permits the positioning of pins in different planes according to the anatomy and nature of soft tissue damage.
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An example of the usefulness of this frame is the external fixation of the humerus, where damage to the radial nerve is avoided by applying the pins in two planes at right angles to each other.
BONE PLATES
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Bone plates are like internal splints holding together the fracture ends of the bone.
The bone plates can be classified in to four groups
1. Neutralization plates
2. Compression plates
3. Buttress plates
4. Condylar plates
NEUTRALIZATION PLATES
A neutralization plate acts as a ‘bridge’
PRINCIPLE:
1. It transmits various forces from one end of the bone to the other, bypassing the area of the fracture.
Functions:
1. Acts as a mechanical link between the healthy segments of bone above and below the fracture, such a plate does not produce any compression at the fracture site.
2. Used in combination with a lag screw also counteracts the torsional, bending, and shearing forces that tend to disrupt the screw, allowing mobilization of the extremity.
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3. The most common clinical application of the neutralization plate is to protect the screw fixation of a short oblique fracture or a communited fracture of a long bone.
COMPRESSION PLATES
A compression plate produces a locking force across a fracture site to which it is applied.
This effect occurs according to newton’s third law(action and reaction are equal and opposite).
The plate is attached to a bone fragement. It is then pulled across the fracture site by a device, producing tension in the plate. As a reaction to this tension, compression is produced at the fracture site across which the plate is fixed.
The direction of the compression force is parallel to the plate.
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The role of compression plate
1. Compaction of the fracture to force together the interdigitating spicules of bone and increase the stability of the construct.
2. Reduction of the space between the bone fragements to decrease the gap to be bridged by a new bone.
3. Protection of the blood supply through enhanced fracture stability.
4. Friction, which at the fracture surfaces resists the tendency of the fragements to slide under torsion or shear. This is advantageous as plates are not particularly effective in resisting torsion.
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BUTTRESS PLATE
FUNCTIONS
1. The mechanical function of this plate is to strengthen (buttress) a weakened cortex.
2. It prevents the bone from collapsing during the healing process.
3. It is designed with a large surface area to facilitate wider distribution of the load.
PRINCIPLE
1. In order to prevent shearing at the fracture site or displacement of the fracture fragments bringing about widening of the articular surface, it is necessary to apply a plate from the diaphysis across the outer surface of the metaphyseal-epiphyseal fragment.
2. Such a plate acts as a buttress or retaining wall. A buttress plate applies a force to the bone which is perpendicular to the flat surface of the plate.
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A buttress plate is used to maintain the bone length or to support the depressed fracture fragments.
Commonly used in fixing epiphyseal and metaphyseal fractures.
There are two types of buttress plates T-plate or L-plate
T-plate is used for fixation of the distal radius and tibial plateau, also used to fix fractures of the tibial pilon and the distal humerus.
CONDYLAR PLATE
Its main application is in the treatment of intra articular distal femoral fractures.
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FUNCTIONS:
1. It maintains the reduction of the major intra articular fragments hence restoring the anatomy of the joint surface.
2. It also rigidly fixes the metaphyseal components to the diaphyseal shaft, permitting early mobility of the extremity.
3. It can function as both the neutralization plate as well as the buttress plate.
A condylar plate is used to fix a proximal femoral osteotomy and intercondylar fracture of the femur.
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REFERENCES
1. The elements of fracture fixation:- Anand. J. thakur
