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Internal fixation

Internal fixation is a surgical technique in orthopedics used to treat fractures by repositioning bone fragments into their normal alignment and stabilizing them with implantable hardware, such as plates, screws, rods, nails, wires, or pins, which are inserted directly into or around the bone to promote healing. This method, often performed as part of open reduction and internal fixation (ORIF), is indicated for displaced, unstable, or complex fractures that cannot be adequately managed with non-surgical immobilization like casts or splints, ensuring proper bone union and restoring function. The origins of internal fixation trace back to the late 18th century with early attempts at wire cerclage for bone stabilization, evolving significantly in the 19th century when German surgeon Carl Hansmann described the first use of a plate and screws in 1886 to secure fractures. By the early 20th century, advancements included William A. Lane's introduction of metal plates in 1895, though initial designs suffered from issues like corrosion and infection due to poor materials and aseptic techniques. The modern standardization of internal fixation techniques emerged in the mid-20th century through the AO Foundation, established in 1958 by Swiss surgeons including Maurice Müller, who emphasized rigid fixation principles to minimize soft tissue damage and enable early patient mobilization. In the procedure, surgeons make an incision to access the fracture site (open reduction), realign the bone fragments under imaging guidance, and secure them with hardware tailored to the fracture type—such as intramedullary nails for long bone shafts or compression plates for articular surfaces—before closing the wound. Benefits include shorter hospital stays, reduced risk of malunion or nonunion, and faster return to weight-bearing activities compared to conservative treatments, particularly in active patients or those with intra-articular fractures. However, potential complications encompass infection at the surgical site, hardware failure or irritation, delayed healing, and rare systemic issues like blood clots, with risks mitigated through antibiotics, sterile protocols, and patient-specific planning. Recovery from internal fixation typically involves immobilization with slings, braces, or crutches for several weeks, followed by physical therapy to regain strength and range of motion, with full healing often taking 3 to 12 months depending on the bone and patient factors. Implants, commonly made of biocompatible materials like titanium or stainless steel, are designed to remain in place permanently unless they cause discomfort, in which case elective removal may be performed after bony consolidation. Ongoing research focuses on bioabsorbable implants and minimally invasive approaches to further reduce complications and improve outcomes in diverse patient populations.

Overview and Principles

Definition and Purpose

Internal fixation is a surgical in which implants, such as plates, screws, , or , are used to stabilize fractured fragments internally, without reliance on external supports like casts or splints. These devices are placed directly within the to hold the in proper during the . The primary purpose of internal fixation is to promote optimal fracture healing by maintaining anatomical reduction of the bone, providing sufficient stability to allow early patient mobilization, and minimizing the risks of complications such as nonunion or malunion. By achieving absolute or relative stability tailored to the fracture type, it facilitates bone union while preserving soft tissue integrity and enabling quicker return to function, often resulting in shorter hospital stays compared to nonoperative methods. Unlike external fixation, which employs devices outside the skin to provide adjustable but less rigid support, internal fixation implants are positioned beneath the skin to deliver more stable, load-sharing or load-bearing fixation suitable for weight-bearing bones like the femur or tibia. This internal approach reduces infection risks associated with transcutaneous pins and supports direct mechanical loading to stimulate healing. The basic process begins with fracture reduction under anesthesia, where the bone fragments are realigned to restore normal anatomy, followed by the application of fixation implants to secure the position and promote healing through controlled strain at the fracture site.

Biomechanical Principles

Internal fixation relies on biomechanical principles that balance mechanical stability with biological healing processes to promote fracture union. These principles ensure that the implant provides sufficient support to maintain alignment and length while allowing appropriate stress transfer to stimulate bone regeneration. The core concepts derive from the interplay between fracture gap mechanics, implant stiffness, and physiological loading, as outlined in foundational orthopedic trauma guidelines. Absolute stability is achieved when internal fixation eliminates interfragmentary motion at the fracture site, typically through direct anatomic reduction and rigid compression. This is accomplished using techniques such as lag screws, which compress bone fragments across the fracture gap to achieve zero micromotion under physiological loads, making it ideal for simple, low-energy fractures like oblique or transverse patterns in cortical bone. Such stability promotes primary bone healing via direct osteonal remodeling without callus formation, as the lack of strain at the site mimics intramembranous ossification. In contrast, relative stability permits controlled micromotion at the fracture interface, fostering secondary healing through endochondral ossification and callus formation. This approach is suited for comminuted or multifragmentary fractures, where techniques like bridge plating span the fracture zone without direct fragment contact, allowing interfragmentary strain typically between 2% and 10% under load to stimulate periosteal and endosteal callus development. Bridge plating, for instance, acts as an internal fixator by preserving vascularity and promoting indirect reduction, which is crucial for metaphyseal or diaphyseal injuries with bone loss. Fixation constructs are further classified by their load distribution: load-sharing versus load-bearing. Load-sharing implants, such as intramedullary nails or standard plates with interfragmentary screws, distribute forces between the device and healing bone, encouraging stress transfer to the fracture site and reducing the risk of implant overload during early healing phases. Load-bearing fixation, often used in articular or periprosthetic fractures, relies on the implant to withstand full physiological loads until bone consolidation, as seen with heavy reconstruction plates that protect non-weight-bearing segments but may lead to stress shielding if overly rigid. The choice depends on fracture location and bone quality to optimize healing without implant failure. These principles align with Wolff's law, which posits that bone architecture remodels in response to mechanical stresses, adapting trabecular orientation and cortical thickness to optimize load resistance during fracture healing. In internal fixation, controlled loading post-surgery stimulates this adaptive remodeling, enhancing bone density and strength at the healed site while preventing atrophy from disuse. For example, progressive weight-bearing after relative stability fixation leverages Wolff's law to guide callus hypertrophy into mature lamellar bone. A fundamental equation underlying implant design is the stress formula: \sigma = \frac{F}{A} where \sigma is stress, F is applied force, and A is cross-sectional area. Implants reduce stress concentrations at fracture sites by increasing the effective area over which forces are distributed, preventing local bone failure and fatigue in the construct. This biomechanical relationship guides material selection and geometry to match bone's elastic modulus, minimizing shielding effects.

Historical Development

Early Techniques

The origins of internal fixation trace back to the late 18th century with early wire cerclage techniques, such as the first described humeral fracture fixation in 1775. By the late 19th century, surgeons began experimenting with rudimentary devices to stabilize fractures internally rather than relying solely on external splints or casts. In 1886, German surgeon Carl Hansmann introduced the first documented use of a metal plate secured with screws for bone fixation, initially applied to treat tibial shaft and iliac crest fractures, marking a shift toward more direct mechanical stabilization of bone fragments. Earlier attempts included the use of wires and pins; for instance, in 1877, British surgeon Joseph Lister employed silver wire to repair a transverse patellar fracture, demonstrating the potential of metallic cerclage for simple fragment approximation. In 1895, British surgeon William Arbuthnot Lane introduced steel plates for fracture fixation, though early designs faced corrosion issues. These early methods focused on basic stabilization but were limited by the available materials and surgical environments. By the early 20th century, Belgian surgeon Albert Lambotte advanced these techniques, pioneering the use of plates and wires for a broader range of fractures around 1905 and introducing a diamond-shaped plate in 1909, which he termed "osteosynthesis" to describe the synthesis of bone through internal means. Lambotte's innovations, including pre-drilled plates to reduce bone damage, were applied to fractures such as those of the humerus and femur, emphasizing absolute stability to promote healing. However, materials like ivory pegs and silver wires were also experimented with during this period; ivory offered some biocompatibility and resorption potential, potentially lowering infection risks compared to metals, though it provided insufficient mechanical strength for load-bearing bones. Significant challenges plagued these early techniques, primarily high infection rates stemming from non-sterile operating conditions and the incomplete adoption of aseptic principles, which often led to osteomyelitis and non-union depending on fracture type and location. Poor material choices exacerbated issues, as early metals like silver and iron corroded rapidly in vivo, causing tissue irritation, while organic options like ivory degraded unpredictably without adequate stability. World War I further highlighted these limitations, as battlefield surgeons, influenced by Lambotte's methods, attempted plating for compound fractures amid high amputation rates, but frequent failures due to contaminated wounds and limited resources underscored the risks of internal fixation in austere settings. A key limitation of these pioneering efforts was the rudimentary understanding of asepsis and biomechanics; surgeons lacked knowledge of bacterial contamination pathways and the need for relative stability to allow callus formation, resulting in rigid constructs that disrupted vascularity and delayed healing, with overall success rates remaining low until mid-20th-century refinements.

Modern Advancements

The establishment of the AO Foundation in 1958 marked a pivotal shift in internal fixation practices, founded by Swiss surgeons Maurice E. Müller, Martin Allgöwer, and Hans Willenegger to standardize operative fracture treatment through evidence-based principles. This organization emphasized anatomical reduction of fractures, stable rigid fixation to promote primary bone healing, preservation of vascular supply, and early functional rehabilitation, which collectively reduced complications and improved outcomes compared to earlier conservative methods. The AO's collaborative research and education efforts, including the development of specialized instrumentation, laid the groundwork for global adoption of internal fixation as a reliable standard. In the late 1960s, the AO group introduced dynamic compression plating (DCP), a refinement that enabled controlled axial compression across fracture sites via eccentric screw placement in oblong plate holes, enhancing stability without excessive rigidity. Developed through extensive biomechanical testing by researchers like Stephan M. Perren, the DCP system improved load distribution and promoted secondary bone healing by allowing micromotion under compression, particularly beneficial for diaphyseal fractures. This innovation superseded earlier static plates by minimizing stress shielding and reducing the risk of implant failure. Post-1970s advancements in intramedullary nailing focused on long bone fractures, with key milestones including the widespread adoption of interlocking nails that provided rotational stability and prevented shortening. Originating from refinements to Gerhard Küntscher's original Küntscher nail, these developments in the 1970s and 1980s—such as proximal and distal locking screws—enabled minimally invasive insertion and load-sharing fixation, becoming the gold standard for femoral and tibial shaft fractures with union rates exceeding 95%. Further evolutions, like flexible nails for pediatric cases and cephalomedullary devices for proximal femur fractures, optimized biomechanical performance while minimizing soft tissue disruption. The 1990s and 2000s saw the emergence of locking plate technology, where threaded screw heads engage directly with the plate to form a fixed-angle construct, significantly improving fixation in low-density osteoporotic bone. This "internal fixator" approach, pioneered by the AO and companies like Synthes, distributed loads more evenly across multiple points, reducing peri-implant stress concentrations and enhancing pull-out resistance in compromised bone. Clinical studies demonstrated superior outcomes in metaphyseal fractures, with lower rates of screw loosening compared to conventional plates. By the 2020s, bioabsorbable implants have advanced as a promising alternative to metallic hardware, degrading gradually over 6-24 months to avoid removal surgeries while providing initial mechanical support equivalent to titanium in select applications. Materials like polylactic acid and magnesium alloys have been refined for controlled resorption rates, minimizing inflammatory responses and supporting bone regeneration in fractures of the radius and ankle. Concurrently, 3D-printed custom plates, leveraging patient-specific imaging and additive manufacturing, enable precise anatomical fit and incorporation of porous structures for osseointegration, reducing operative time and improving long-term stability in complex cases like pelvic or mandibular fractures. These personalized solutions, increasingly adopted in specialized trauma centers, represent a shift toward individualized fixation with complication rates comparable to off-the-shelf implants.

Indications and Patient Selection

Common Fracture Types

Internal fixation is commonly indicated for various fracture patterns in long bones and articular surfaces, where stable alignment is essential for healing and functional recovery. Diaphyseal fractures, occurring in the shaft of long bones such as the femur, tibia, and humerus, represent a primary indication due to their potential for displacement and nonunion if not stabilized. These fractures are often treated with intramedullary nailing to provide axial stability and allow early mobilization, achieving union rates exceeding 95% in femoral shaft cases. Similarly, tibial diaphyseal fractures benefit from intramedullary devices, which minimize soft tissue disruption while restoring length and rotation. Humeral shaft fractures, frequently associated with radial nerve injury, are stabilized using plates or nails to prevent malunion and support weight-bearing activities. Intra-articular fractures, which involve the joint surface, demand precise anatomic reduction to avoid post-traumatic arthritis and preserve joint function. For instance, distal radius fractures with intra-articular extension require open reduction and internal fixation (ORIF) when unstable, yielding good outcomes in 82-90% of appropriately selected cases by restoring volar tilt and radial height. Ankle fractures extending into the tibiotalar joint similarly necessitate ORIF for displaced patterns to ensure congruent reduction and ligamentous stability. These fractures highlight the need for fixation that maintains articular congruity, as even minor steps in the joint surface can lead to long-term degenerative changes. The distinction between comminuted and simple fractures significantly influences fixation strategies, with fragment number and stability guiding implant choice. Simple fractures, involving two main fragments, often achieve stability through compression plating or lag screws to promote primary bone healing via direct contact. In contrast, comminuted fractures with multiple fragments require bridging constructs like locking plates to span the defect and provide relative stability, facilitating secondary healing through callus formation without excessive interfragmentary strain. This approach is particularly vital in high-energy injuries where bone loss complicates reduction. In polytrauma scenarios involving multiple fractures, damage control orthopedics prioritizes temporary stabilization to mitigate the systemic inflammatory response before definitive fixation. External fixation or provisional nailing is employed initially for long bone fractures in unstable patients, reducing secondary complications like fat embolism and allowing physiologic recovery prior to ORIF. This staged approach has been shown to lower mortality in severe polytrauma compared to immediate total care. Patient-specific factors, including age and bone quality, further refine indications for internal fixation. In older adults with osteoporosis, reduced bone density increases failure risk with conventional plates, necessitating locking plate systems that enhance purchase in poor-quality bone and improve fixation stability for fragility fractures. These devices convert shear forces to compressive loads at the bone-screw interface, reducing the need for precise contouring and supporting early weight-bearing in metaphyseal regions.

Contraindications and Alternatives

Internal fixation is contraindicated in cases of active local or systemic infection, such as osteomyelitis, due to the high risk of exacerbating the infection through surgical implantation. Similarly, grossly contaminated open fractures or wounds with poor soft tissue coverage represent absolute contraindications, as these conditions increase the likelihood of postoperative infection and implant failure. Medically unstable patients, including those with hemorrhagic shock (systolic blood pressure <90 mmHg), hypothermia (<33°C), or uncorrected coagulation disorders, are also unsuitable for internal fixation, as the procedure could worsen hemodynamic instability. Relative contraindications include open epiphyses in pediatric patients, where internal fixation risks damaging growth plates and causing growth disturbances. Highly unstable pelvic fractures may be better managed with external fixation initially, as internal approaches can be technically challenging and associated with higher complication rates in such scenarios. Severe comorbidities, such as advanced osteoporosis or uncontrolled diabetes, serve as relative contraindications, particularly in elderly patients, where the risks of surgery may outweigh benefits. Alternatives to internal fixation depend on fracture stability and patient factors; for stable, non-displaced fractures, non-operative management with casting or bracing is often preferred to avoid surgical risks. External fixation provides a suitable alternative for contaminated wounds, open fractures, or temporary stabilization in polytrauma cases, allowing for soft tissue management without deep implantation. In elderly patients with low-energy fractures and significant comorbidities, guidelines recommend considering non-operative approaches, such as traction or mobilization with physical therapy, to minimize perioperative mortality. Key decision factors for choosing internal fixation over alternatives include the surgeon's expertise, availability of resources in the clinical setting, and the patient's ability to comply with postoperative rehabilitation. The American Academy of Orthopaedic Surgeons (AAOS) guidelines, updated in 2021 for hip fractures in older adults, emphasize shared decision-making, recommending non-operative management for select low-demand elderly patients with stable fractures to balance risks and functional outcomes.

Surgical Techniques

Open Reduction Internal Fixation (ORIF)

Open Reduction Internal Fixation (ORIF) is a surgical technique used to treat displaced or unstable fractures by directly accessing the bone through an incision, realigning the fragments, and stabilizing them with internal hardware. This approach is particularly indicated for complex fractures where precise anatomical restoration is essential for optimal healing and function. Preoperative planning begins with thorough imaging to assess the fracture. Standard X-rays are routinely obtained to confirm the fracture location, pattern, and displacement, while computed tomography (CT) scans may be employed for more detailed evaluation of intra-articular involvement or comminution. The surgeon reviews these images alongside the patient's overall health, fracture stability, and soft tissue condition to determine the need for ORIF over non-surgical options. The procedure is typically performed under general anesthesia, which induces unconsciousness and facilitates muscle relaxation, though regional anesthesia may be used in select cases. The patient is positioned supine, lateral, or prone depending on the fracture site to optimize surgical access, with the affected limb prepared and draped sterilely. Intraoperative fluoroscopy provides real-time imaging guidance to ensure accurate reduction and hardware placement throughout the surgery. Surgical steps commence with an incision over the fracture site to expose the bone, allowing direct visualization of the fragments and surrounding soft tissues. Manual reduction follows, where the surgeon physically manipulates the bone ends into anatomical alignment using clamps or traction. Internal fixation is then applied, commonly with plates and screws to secure the fragments, though rods, wires, or pins may be used based on the fracture characteristics. The wound is irrigated, closed in layers with sutures or staples, and the limb may be immobilized with a splint or cast postoperatively. The direct visualization afforded by ORIF enables precise handling of complex fractures, such as those with multiple fragments or significant soft tissue interposition, which may not be adequately addressed via closed methods. Typical operative duration ranges from 1 to 3 hours, varying with the bone involved and fracture complexity.

Closed Reduction Internal Fixation (CRIF)

Closed reduction internal fixation (CRIF) involves the non-surgical realignment of fractured bone fragments through closed manipulation or skeletal traction, followed by the percutaneous insertion of internal fixation devices to stabilize the fracture without direct exposure of the site. This technique relies on indirect reduction methods, such as manual traction or the use of fracture tables, to restore anatomical alignment, after which implants like intramedullary nails or screws are introduced through small skin incisions remote from the fracture. Fluoroscopy or other imaging guidance ensures accurate placement, minimizing the need for extensive dissection. CRIF is commonly employed for diaphyseal fractures of long bones, particularly intramedullary nailing of femoral and tibial shaft fractures, where the medullary canal provides a natural pathway for implant insertion. In femoral shaft fractures, antegrade nailing typically begins with a small incision at the greater trochanter or piriformis fossa, followed by guidewire placement and reaming under imaging control to accommodate the nail. Similarly, for tibial shaft fractures, a percutaneous approach through the patellar tendon or suprapatellar portal allows nail insertion, achieving union rates above 90% in appropriately selected cases. These applications leverage the biomechanical advantages of intramedullary devices to load-share with the bone, promoting healing while preserving periosteal blood supply. Intraoperative imaging, primarily fluoroscopy, is essential for CRIF to confirm reduction quality, guide implant trajectory, and verify final positioning, often using biplanar views to avoid malalignment. Advanced navigation systems may supplement fluoroscopy in complex cases, enhancing precision without additional incisions. This real-time visualization reduces operative time and radiation exposure compared to traditional methods. Compared to open reduction internal fixation (ORIF), CRIF offers benefits including reduced risk of surgical site infection due to minimal soft tissue disruption and smaller incisions, as well as accelerated postoperative recovery with earlier mobilization. These advantages stem from preserved vascularity and decreased wound complications, particularly in patients with compromised soft tissues. However, CRIF has limitations in achieving precise reduction for fractures involving articular surfaces, where indirect techniques may not adequately restore joint congruity, potentially leading to suboptimal outcomes; in such scenarios, ORIF is often preferred for direct visualization and anatomical reconstruction.

Minimally Invasive Osteosynthesis (MIO)

Minimally invasive osteosynthesis (MIO) represents a contemporary surgical approach in internal fixation that combines elements of open reduction internal fixation (ORIF) and closed reduction internal fixation (CRIF) to minimize soft tissue disruption while achieving stable fracture alignment and healing. By employing small incisions and indirect reduction techniques, MIO preserves periosteal blood supply and reduces postoperative morbidity compared to traditional open methods. This technique has gained prominence since the early 2000s, particularly for periarticular and diaphyseal fractures where biological fixation is prioritized over absolute anatomic reduction. Percutaneous plating, a core component of MIO often termed minimally invasive plate osteosynthesis (MIPO), involves inserting locking plates through minimal skin incisions without extensive exposure of the fracture site. Surgeons typically create proximal and distal portals to pass a precontoured plate submuscularly, bridging the fracture gap, followed by percutaneous screw placement to secure the construct. This method disrupts less vascularity than conventional plating, promoting callus formation and reducing the risk of delayed union. For instance, in femoral shaft fractures, MIPO has demonstrated reliable union rates exceeding 90% with minimal implant irritation. Intramedullary devices integrated into MIO protocols, such as locking intramedullary nails, are inserted via small entry portals to maintain closed reduction and limit soft tissue stripping. These nails provide axial stability and load-sharing across the fracture, often combined with percutaneous locking screws for rotational control. The technique is particularly suited for long bone fractures, where the nail is advanced over a guide wire under fluoroscopic guidance, avoiding open exposure. Studies indicate that minimally invasive nailing achieves comparable biomechanical stability to open methods while accelerating early mobilization. Computer-assisted navigation and robotic systems enhance precision in MIO by enabling real-time imaging and trajectory planning, reducing reliance on intraoperative fluoroscopy since their integration in orthopedic trauma during the 2000s. Navigation tracks instrument position relative to preoperative CT scans, facilitating accurate plate or nail placement through small incisions, while robotic arms can automate drilling and insertion for enhanced reproducibility. These technologies have been shown to decrease radiation exposure by up to 50% and improve screw accuracy to over 95% in complex cases. As of 2025, robotic systems integrated with navigation have become more prevalent, reducing fluoroscopy time and enhancing accuracy in orthopedic trauma surgery. MIO finds specific application in proximal humerus fractures, where percutaneous plating via deltopectoral or anterolateral approaches stabilizes displaced surgical neck patterns with low rates of avascular necrosis. Similarly, for distal femur fractures, lateral MIPO techniques using locking compression plates address extra-articular and partial articular injuries, preserving quadriceps function and enabling earlier weight-bearing. These applications are favored in osteoporotic bone, where indirect reduction minimizes further comminution. Clinical evidence supports MIO's advantages, with meta-analyses indicating lower postoperative complication rates, including infection, compared to traditional ORIF due to reduced wound size and contamination risk. For example, systematic reviews of humeral shaft fractures have reported lower overall complication rates for MIPO (around 14%) versus ORIF (around 21%), alongside shorter operative times and hospital stays. These outcomes underscore MIO's role in improving patient recovery while maintaining union rates above 90%.

Implants and Fixation Devices

Types of Implants

Internal fixation employs a variety of implants designed to stabilize fractures by providing compression, neutralization, or load-sharing functions, categorized primarily by their mechanical roles and bone interaction. Screws form the foundational elements of many fixation constructs, engaging bone directly to achieve stability. Cortical screws are optimized for dense cortical bone, featuring a large outer diameter and fine thread pitch to maximize pullout strength and bicortical purchase. Cancellous screws, in contrast, are tailored for spongy metaphyseal or epiphyseal bone, with deeper, coarser threads to enhance grip in porous structures and improve resistance to subsidence. Lag screws specifically generate interfragmentary compression by advancing the threaded portion across the fracture site while the head seats against the near cortex, thereby eliminating micromotion and promoting primary bone healing through absolute stability. Plates serve as versatile splints that bridge fracture gaps and distribute forces across the bone. Dynamic compression plates (DCP) utilize oval screw holes allowing eccentric insertion, which translates axial load into lateral compression at the fracture site for enhanced stability in simple patterns. Locking compression plates (LCP) incorporate threaded screw heads that lock into the plate, providing fixed-angle constructs that resist angular deformity, particularly beneficial in multifragmentary or metaphyseal fractures where bone quality may compromise standard screw purchase. Intramedullary nails are elongated devices inserted into the medullary canal of long bones to act as internal struts, sharing axial loads with the bone. Solid nails offer greater bending rigidity, scaling with the fourth power of their radius, making them suitable for high-load environments, whereas hollow designs provide similar torsional resistance but with reduced weight and proportional rigidity to the third power of the radius. Locking mechanisms, such as proximal and distal screws, prevent rotational instability and axial migration; static locking maintains length in unstable fractures, while dynamic locking permits controlled motion to stimulate secondary healing. Wires and cables offer flexible stabilization for periarticular or soft-tissue-preserving applications. Cerclage wires encircle bone fragments to approximate them under tension, delivering relative stability that allows micromotion and callus formation while minimizing vascular disruption. Other implants, such as pins and rods, provide targeted support in specialized scenarios. Smooth or threaded pins temporarily hold small fragments or align bones during healing, often in pediatric or hand surgery contexts, and are typically removed once union occurs. Rods, akin to nails but without medullary reaming, offer provisional fixation in spinal or external augmentation roles, emphasizing load-sharing without deep canal invasion.

Materials and Design Considerations

Internal fixation implants are primarily constructed from metallic and bioabsorbable materials, each selected for their mechanical properties, biocompatibility, and clinical suitability. Stainless steel, particularly 316L grade, is widely used due to its high strength for load-bearing applications and relative affordability compared to other metals, making it suitable for temporary implants in trauma cases. Titanium alloys, such as Ti-6Al-4V, offer superior corrosion resistance in physiological environments and compatibility with magnetic resonance imaging (MRI), allowing patients to undergo scans without significant artifact interference or safety risks. Bioabsorbable materials provide an alternative to permanent metallic implants by gradually degrading, eliminating the need for removal surgery. Polymers like poly-L-lactic acid (PLLA) are commonly employed, with degradation occurring through hydrolysis over periods typically ranging from 12 to 24 months, during which they maintain sufficient mechanical integrity before resorbing into non-toxic byproducts. Recent advancements as of 2025 include the development of zinc-based biodegradable alloys for temporary implants, offering faster degradation rates than traditional polymers while maintaining mechanical strength, and 3D-printed metallic implants tailored to patient anatomy for improved fit and reduced surgery time. Additionally, smart implants incorporating sensors for real-time monitoring of strain and healing progress are emerging, enhancing postoperative management. Design considerations for these implants emphasize modularity to allow customization based on fracture anatomy and patient-specific needs, enabling surgeons to assemble components like plates and screws for optimal fit. Surface coatings, such as hydroxyapatite, are applied to enhance osseointegration by promoting direct bone-implant contact and accelerating healing through improved protein adsorption and cellular attachment. Fatigue resistance is a critical design factor, as implants must endure repetitive loading equivalent to millions of gait cycles over years of use; standards require survival beyond 10^6 to 10^7 cycles under simulated physiological stresses to prevent failure. Regulatory standards ensure material safety and performance, with the U.S. Food and Drug Administration (FDA) mandating compliance with ISO 10993 for biocompatibility evaluation, including cytotoxicity, sensitization, and implantation tests to assess tissue interactions. Additionally, ISO 13485 governs quality management systems for manufacturing these devices.

Specific Clinical Applications

Intracapsular Hip Fractures in Older Adults

Intracapsular hip fractures in older adults primarily involve the femoral neck and are classified using the Garden system, which delineates four types based on displacement: type I represents an incomplete, valgus-impacted nondisplaced fracture; type II is a complete but nondisplaced fracture; type III is partially displaced; and type IV is fully displaced. Nondisplaced fractures (types I and II) are generally managed with internal fixation to preserve the native femoral head and enable early mobilization, whereas displaced fractures (types III and IV) carry elevated risks of avascular necrosis and nonunion, prompting evaluation for fixation versus replacement in elderly patients. This classification guides treatment decisions, with internal fixation favored for stable, nondisplaced cases to avoid the morbidity of arthroplasty. Specific implants for internal fixation of these fractures include multiple parallel cannulated cancellous screws, which are inserted percutaneously to achieve compression and rotational stability, particularly effective for nondisplaced femoral neck fractures. Alternatively, sliding hip screws (dynamic hip screws) provide a more robust construct for displaced fractures by allowing controlled impaction along the fracture plane, though they may require greater soft-tissue dissection. Cannulated screws demonstrate superior outcomes in reducing avascular necrosis rates compared to sliding hip screws (8.3% versus 9.9%), with no significant differences in nonunion or revision rates, making them a preferred option for minimally invasive fixation in older adults. Osteoporosis, prevalent in this population, complicates fixation by reducing bone stock and purchase, often necessitating locking mechanisms—such as locking screws or plates—that create a fixed-angle construct to enhance stability, distribute loads evenly, and permit earlier weight-bearing without screw cutout. Despite these adaptations, internal fixation carries a high nonunion risk of 10% to 33%, exacerbated by fracture displacement, poor reduction quality, and diminished bone density in elderly patients. To optimize outcomes and reduce mortality, surgery should be performed within 24 to 48 hours of admission, aligning with evidence-based guidelines emphasizing prompt intervention after medical optimization. In cases of severe displacement or comminution, particularly in frail older adults, hemiarthroplasty emerges as a viable alternative to internal fixation, providing immediate stability and superior functional recovery with lower reoperation rates (up to 70% reduction compared to fixation). This approach is especially beneficial for active elderly patients with displaced fractures, balancing the preservation of mobility against the risks of fixation failure.

Long Bone Fractures

Internal fixation plays a crucial role in managing fractures of long bones, such as the femur, tibia, and humerus, which are frequently caused by high-energy trauma like motor vehicle accidents or falls from height. These shaft fractures, often diaphyseal, require stable alignment to restore function and prevent complications like malunion, with internal fixation providing biomechanical support through devices inserted into the medullary canal or applied to the bone surface. Intramedullary nailing is the preferred method for internal fixation of long bone shaft fractures, particularly in polytrauma patients, as it enables rapid stabilization, minimizes surgical time, and allows early mobilization. This technique involves inserting a metal rod into the bone marrow cavity, which is especially beneficial for femoral and tibial fractures in unstable patients, promoting load-sharing and reducing soft tissue disruption compared to plating. A key consideration in intramedullary nailing is the reaming debate: reamed nailing, which enlarges the medullary canal before nail insertion, enhances bone union rates and mechanical stability by improving nail fit and increasing endosteal blood flow, but it carries a theoretical risk of fat embolism due to intramedullary pressure elevation. In contrast, unreamed nailing avoids reaming to reduce embolization risks, particularly in patients with pulmonary compromise, though it may result in higher rates of delayed union and implant failure. Meta-analyses indicate that reamed techniques achieve union in shorter times without significantly increasing fat embolism incidence in most cases. In pediatric patients, flexible intramedullary nails are adapted for long bone fractures to preserve physeal growth and avoid damage to open growth plates, offering elastic stability that accommodates remodeling in children aged 5-16 years. These nails, often titanium elastic stable intramedullary nails, are inserted percutaneously away from the physis, providing three-point fixation for diaphyseal fractures of the femur, tibia, and humerus while minimizing stiffness that could cross growth plates. With proper internal fixation, union rates for long bone shaft fractures exceed 90-95%, reflecting high success in achieving radiographic and clinical healing, particularly with intramedullary nailing in appropriately selected cases. These outcomes underscore the versatility of internal fixation for restoring limb integrity in active populations.

Complications and Outcomes

Intraoperative and Postoperative Risks

Internal fixation procedures carry several intraoperative risks that can arise during the surgical reduction and stabilization of fractures. Bleeding is a common concern due to the vascularity of fracture sites, particularly in pelvic or long bone surgeries, where significant intraoperative blood loss may necessitate transfusion. Nerve and vessel injuries occur from direct trauma during dissection or hardware placement, with reported incidences varying by anatomical location; for instance, iatrogenic femoral nerve injury has been documented in pelvic fixations. Malreduction, defined as inadequate alignment of fracture fragments, affects 5-10% of cases overall, though rates can reach 25-52% in syndesmotic ankle fractures, often due to challenges in intraoperative assessment. Postoperative risks primarily involve infection and implant-related issues. Surgical site infections occur in 1-5% of closed fracture fixations but rise to 8% or higher in open wounds, driven by contamination and impaired soft tissue coverage. Implant failure, such as screw loosening or breakage, manifests early in 4-10% of cases depending on the site, leading to loss of fixation and potential reoperation; this is exacerbated by poor bone quality or excessive mechanical stress. Key risk factors for these complications include smoking, which increases deep wound infections and dehiscence by impairing vascularity and healing (odds ratio approximately 1.6), and diabetes mellitus, which elevates overall surgical complication rates through delayed wound closure and higher infection susceptibility. Prophylactic measures mitigate these risks: perioperative antibiotics, such as cefazolin, are standard to reduce infection incidence, while deep vein thrombosis (DVT) prevention with low-molecular-weight heparin or mechanical devices is recommended for immobilized patients post-fixation. Postoperative monitoring focuses on early detection through serial X-rays to assess fracture alignment and implant position, typically at 1-2 weeks and monthly intervals initially. Vigilance for compartment syndrome involves serial clinical examinations for pain, swelling, and neurovascular deficits, as pressures exceeding 30 mmHg may require urgent fasciotomy, particularly after tibial or forearm fixations. Technique-specific differences highlight higher wound complications with open reduction internal fixation (ORIF), including dehiscence and infection rates up to 37%, compared to minimally invasive osteosynthesis (MIO), which reports lower overall complications at 14% due to reduced soft tissue disruption. These acute risks underscore the need for meticulous surgical planning, though long-term outcomes depend on subsequent healing dynamics.

Long-Term Results and Management

Long-term outcomes following internal fixation of fractures demonstrate high rates of bony union, typically ranging from 90% to 95% across various long bone fractures when stable fixation is achieved. Factors such as fracture stability, patient comorbidities, and smoking status significantly influence union success, with unstable constructs increasing the risk of nonunion to 7-10%. Time to union varies by bone type and location; for cortical bone in long bones, radiographic union generally occurs within 12-16 weeks under optimal conditions, though delayed union may extend this to 6 months or more in complex cases. Rehabilitation protocols emphasize early mobilization to optimize functional recovery and minimize complications like stiffness. Weight-bearing progression is tailored to fracture site and stability, often beginning with partial weight-bearing within 1-2 weeks post-operation for lower extremity fractures, advancing to full weight-bearing by 6-12 weeks as healing progresses. Physical therapy typically commences on postoperative day 1, focusing on range-of-motion exercises, muscle strengthening, and gait training to restore function and prevent muscle atrophy. Management of fixation failures, such as nonunion or malunion, involves revision surgery in most cases to achieve healing and restore alignment. For nonunion, which occurs in approximately 5-10% of cases, treatments include debridement, stable re-fixation with plates or intramedullary nails, and augmentation with autologous bone grafting to promote osteogenesis. Malunion, characterized by improper alignment leading to functional deficits, may require osteotomy with internal fixation to correct deformity, often combined with bone grafting for gaps greater than 1 cm. Success rates for revision procedures exceed 85% with appropriate biological enhancement. Functional outcomes are evaluated using validated scoring systems to assess patient-reported mobility and quality of life. The Disabilities of the Arm, Shoulder, and Hand (DASH) score is commonly applied for upper extremity fractures, measuring disability in daily activities with scores below 20 indicating excellent function post-recovery. For hip fractures, the Harris Hip Score (HHS) quantifies pain, function, and deformity, with postoperative averages of 80-90 points reflecting good to excellent results in mobile patients. Recent meta-analyses confirm the superiority of internal fixation over casting for displaced fractures, particularly in enhancing long-term mobility and reducing re-displacement rates. A 2025 systematic review of randomized trials reported significantly better patient-reported functional outcomes and earlier return to activity with operative management compared to nonoperative casting in adults with displaced distal radius fractures.