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Multileaf collimator

A () is a computer-controlled device integrated into linear accelerators for external , consisting of multiple pairs of leaves—typically 40 to 160 in number—that can be independently positioned to shape the high-energy or to match the three-dimensional contours of a tumor target volume while minimizing exposure to surrounding healthy tissues. This beam-shaping capability replaces traditional manual collimation methods, such as custom blocks, and enables precise conformal radiotherapy by adjusting leaf positions in real-time during treatment delivery. The leaves, usually 5 to 10 cm thick and 1.0 to 1.25 cm wide at the isocenter, are arranged in opposing banks and driven by motors for dynamic or static modulation, with transmission through leaves limited to under 2-5% to ensure beam integrity. The development of MLCs traces back to the late , with the first and patenting occurring in 1959, followed by early gravity-oriented blocking systems in the 1960s pioneered by researchers like Proimos for conformal field shaping. Commercial MLC systems emerged in the , with initial implementations by manufacturers such as Varian and , marking a shift from labor-intensive cerrobend blocks to automated, efficient beam modulation. By the early 1990s, advancements in dynamic MLC techniques—demonstrated feasible by Convery in 1992 and optimized through trajectory equations by , Svensson, and Spirou in 1994—paved the way for intensity-modulated (IMRT), where leaves slide continuously to vary beam intensity across the field. In operation, MLCs incorporate backup to shadow leaf edges and reduce interleaf leakage, along with precise control systems like linear encoders or video-optical guidance to achieve positioning accuracy within 0.3 mm and under 0.1 mm, ensuring dosimetric reliability during . Calibration involves reference measurements using arrays or , targeting leaf position errors below 1 mm, with tongue-and-groove interlock designs in modern systems minimizing leakage to 0.7-1.5%. These features not only enhance treatment efficiency by eliminating fabrication—which involves toxic materials and significant setup time—but also advanced modalities like volumetric modulated arc (VMAT) and stereotactic radiosurgery, improving tumor control while reducing side effects in organs at risk. Today, MLCs are standard on virtually all medical linear accelerators, with ongoing innovations including double-stack configurations for finer in small fields and with image-guided systems for adaptive .

History and Development

Early Concepts and Prototypes

The concept of the multileaf collimator () originated in the mid-20th century as part of efforts to achieve more precise beam shaping in radiotherapy, with foundational ideas emerging in the and 1960s. In 1959, the first multileaf collimator was invented and by W. Gscheidlen (US Patent 2,904,692), marking an early attempt to use movable metallic leaves for conformal field shaping rather than fixed blocks. This innovation built on prior manual techniques but introduced the principle of independent leaf movement to approximate irregular tumor contours. A key precursor to modern MLCs was described in 1965 by Shinji Takahashi, who proposed conformation radiotherapy using adjustable blocks arranged in a manner that prefigured leaf-based systems for rotation therapy. Takahashi's work emphasized dynamic shielding to conform the field to target volumes during arc rotations, reducing dose to surrounding tissues in . This approach highlighted the need for mechanized, adjustable collimation beyond static cerrobend blocks, influencing subsequent designs for both and beams. During the 1970s, initial prototypes of MLCs were developed, often as mechanical systems with pairs of independent leaves to enable beam shaping on units and early linear accelerators. These prototypes featured motor-driven or pneumatic leaves capable of basic field modulation, allowing for irregular apertures without manual block fabrication. Key challenges in these early systems included achieving reliable leaf alignment. By the early , foundational s advanced MLC design for integration with linear accelerators, such as Anders Brahme's 1987 for a multileaf collimator using motor-driven leaves to shape high-energy , , and beams with sub-millimeter resolution potential. This described a system of opposing leaf banks for precise, programmable field definition, addressing limitations of prior prototypes. Early U.S. s around this period, including those for motor-driven leaves, emphasized independent control to minimize interleaf leakage and improve conformational accuracy. These developments laid the groundwork for transitioning from manual to automated systems, though full computer integration occurred later.

Evolution to Modern Systems

The introduction of computer-controlled multileaf collimators (MLCs) in the early 1990s marked a significant advancement in radiotherapy, enabling precise, automated beam shaping without manual block fabrication. A seminal study by Galvin et al. in 1993 evaluated the dosimetric performance of these systems, including penumbra width, leaf transmission, interleaf leakage, and leaf positioning accuracy, establishing benchmarks for clinical implementation. This work highlighted the potential of MLCs to replace traditional cerrobend blocks, facilitating more efficient conformal treatments. Commercial adoption accelerated in the mid-1990s, with major vendors like Varian and (formerly ) integrating into their linear accelerators. Varian's systems, such as the early tertiary MLC designs on the Clinac 2100C, supported up to 80 leaves initially, evolving to 120-leaf configurations by the late 1990s to cover larger fields with finer resolution. Similarly, introduced MLCs with 52 leaves, emphasizing backup diaphragms for enhanced . These developments were driven by dosimetric validations showing comparable or superior performance to blocks in field shaping. Key milestones in the late included the enabling of dynamic operation for intensity-modulated radiotherapy (IMRT) delivery starting around 1997, as evidenced by early clinical implementations. Integration with treatment planning software, such as inverse planning algorithms, further streamlined workflows by automating leaf sequencing for complex fluence maps. By the 2000s, expanded to support high-energy beams (6-18 ) on standard linear accelerators, with dosimetric studies confirming reliable performance across energies. Adaptations for also emerged, leveraging finer leaf widths (e.g., 5 mm) for small intracranial targets, improving dose conformity over circular collimators.

Design and Components

Leaf Structure and Materials

The leaves of a multileaf collimator (MLC) are constructed primarily from due to its high , which provides effective . This typically consists of approximately 90-95% with additions of and iron, achieving a of 17.0-18.5 g/cm³. The material's and also facilitate precise shaping for clinical use. Leaf dimensions vary by manufacturer but generally feature a thickness of 5-10 cm in the beam direction to ensure sufficient blocking, a width of 0.5-1.0 cm projected at the isocenter for fine beam modulation, and a height of 7-15 cm to span the treatment field. For example, Varian systems use leaves with a 10 cm thickness and 1.0 cm width at isocenter for standard leaves, while models have outer leaves projecting a 6.5 cm width at isocenter and inner leaves 1.0 cm width, with a leaf thickness of 7.5 cm. To reduce interleaf leakage, leaves incorporate overlapping tongue-and-groove designs on their sides, with tips that are either rounded or straight, forming a truncated pie shape that minimizes transmission between adjacent leaves. Attenuation properties are critical for MLC performance, with leaves designed to block over 95% of photons, resulting in transmission through the leaf thickness of less than 2.5% for 6 MV x-rays. Specific measurements indicate direct transmission of 1.5-2.0% at 6 MV, with interleaf transmission adding 0.25-0.75% due to scattering and gaps. These values ensure low leakage while maintaining beam integrity during shaping. Design variations include single-focused and double-focused leaves to accommodate beam divergence from the linear accelerator source. Single-focused leaves, as in Varian and Philips systems, feature curved ends that match divergence in the leaf motion plane but flat sides. Double-focused designs, such as those from Siemens, curve both the ends and sides to align precisely with divergence in two planes, reducing penumbra and improving field conformity.

Mechanical and Control Systems

The mechanical systems of multileaf collimators (MLCs) primarily rely on drive mechanisms that enable precise of individual leaves. These mechanisms typically employ or motors, often one per or per leaf bank, to convert rotational motion into linear translation via lead screws or similar assemblies. For instance, commercial systems like those from Varian use analog or digital motors driving linear screw bars, while prototypes may incorporate 52 motors for positioning and additional motors for carriage movement. Typical leaf speeds range from 1 to 2 cm/s, with maximum capabilities up to 5 cm/s in some designs, ensuring efficient field shaping without compromising accuracy. Positioning accuracy is maintained below 0.5 mm through mechanical tolerances and systems, critical for conformal beam delivery. Control architectures for MLCs support both (step-and-shoot) and continuous (dynamic) leaf motion modes, allowing versatility in treatment delivery. In mode, leaves move to discrete positions with the beam off between segments, minimizing transmission errors, whereas continuous motion enables sliding techniques for intensity modulation during beam-on periods. Integration with linear accelerator (LINAC) systems occurs via DICOM-RT standards, which transfer planning data including leaf positions for real-time adjustments synchronized with rotation and dose delivery. Programmable controllers (PLCs) or dedicated microprocessors handle motion commands, often using look-up tables to compensate for mechanical backlash and ensure sub-millimeter precision. Sensors and feedback mechanisms are essential for reliable operation, incorporating optical encoders and potentiometers to leaf positions in . Linear encoders, functioning as high-precision potentiometers, provide on leaf displacement, while shaft encoders on motors detect rotational changes for closed-loop . Video-optical systems using cameras offer redundant verification in some designs, detecting positions via reflected light from leaf edges. Interlock systems, including software and hardware limits, prevent collisions by halting motion if overlaps or deviations exceed thresholds, such as 1 mm, and integrate with record-and-verify systems to enforce before beam activation. Calibration procedures for MLCs emphasize daily (QA) to verify leaf positioning accuracy, typically using electronic portal imaging devices (EPID) or radiographic films. These checks involve delivering test patterns to measure deviations, ensuring they remain below 1 mm across the leaf travel range, with automatic initialization routines like infrared beam alignment in Varian systems. EPID-based quantifies positional errors by comparing acquired images to planned fluences, while film exposures provide high-resolution validation for interleaf leakage and alignment. Such routines, performed prior to clinical use, maintain system reliability and dosimetric fidelity.

Principles of Operation

Beam Shaping Mechanisms

The multileaf collimator (MLC) shapes radiation beams by employing pairs of opposing alloy leaves that project shadows onto the treatment plane, thereby defining irregular field apertures to conform to the planning target volume (PTV) contours derived from fluence maps in treatment planning. These leaves, typically 5–10 cm thick, attenuate the photon beam while allowing precise geometric modulation of the beam's cross-section at the isocenter. Key geometric considerations in beam shaping include the leaf transmission factor, which is typically 1–2% (<2%) for clinical photon energies (6–18 MV), representing the residual radiation passing through closed leaves due to scatter and direct penetration. Additionally, penumbra broadening occurs at field edges, primarily from the leaf tip design, resulting in a 1-2 mm increase at the isocenter for standard configurations. Interleaf transmission, influenced by adjacent leaf alignment, contributes further to edge softening but is minimized in modern designs. The effective field width w projected at the isocenter is determined by the geometric divergence of the beam, given by the equation w = 2 \times \left( l \times \frac{\text{SAD}}{\text{SAD} - d} \right), where l is the leaf position from the central axis at the collimator plane, SAD is the source-axis distance (typically 100 cm), and d is the source-to-leaf distance. This projection factor accounts for the fan-like spread from the source, ensuring that leaf adjustments at the collimator translate accurately to the patient plane. In static MLC configurations, beam shaping is achieved through step-and-shoot delivery, where leaves are positioned to form discrete field segments for each angle, optimizing before beam-on exposure. This method relies on fixed leaf positions per segment, verified to within 2 mm accuracy during . Early static prototypes laid the groundwork for these techniques, demonstrating reliable formation without dynamic motion.

Dynamic and Static Modulation

In static modulation, the multileaf collimator (MLC) leaves are positioned in fixed configurations for discrete segments of the beam delivery, with each segment delivering a uniform before the leaves reposition for the next segment; the composite dose is achieved by summing the contributions from multiple (varying by plan complexity) such segments per beam angle. This step-and-shoot approach, also known as segmental MLC (SMLC), allows for modulation by varying the monitor units (MU) allocated to each static field, enabling conformal dose shaping without continuous leaf motion. Static modulation is particularly suited for simpler intensity-modulated radiotherapy (IMRT) plans where precise control over aperture shapes is prioritized over delivery efficiency. Dynamic , in contrast, involves continuous motion of the leaves during beam-on , known as dynamic MLC (DMLC) , which synchronizes leaf trajectories with the to produce varying patterns across the field. A key technique within dynamic modulation is the sliding window method for IMRT, where opposing pairs sweep unidirectionally across the treatment field at independent speeds, creating intensity gradients proportional to the time the remains open over each point; this can be further integrated with gantry rotation in volumetric modulated arc therapy (VMAT) for enhanced conformality. The continuous motion in DMLC reduces the number of interruptions compared to static methods, potentially shortening treatment times while achieving smoother dose gradients. Dose rate considerations play a critical role in dynamic , as the maximum leaf speed imposes limits on ; excessive demands can extend beam-on time (T) due to constraints on how quickly leaves can traverse required distances (\Delta l_i). One for quantifying this (M) is given by M = \frac{\sum |\Delta l_i|}{T}, where \sum |\Delta l_i| represents the total absolute leaf travel across all leaves and segments, providing a measure of the variation relative to the available duration; higher M values indicate greater demands on leaf velocity and feasibility. To ensure safe operation in dynamic modes, collision avoidance algorithms optimize leaf trajectories in real time, enforcing minimum interleaf gaps and adjusting accelerations to prevent mechanical friction or overlaps between adjacent leaves during motion. These algorithms typically incorporate predictive modeling of leaf positions and velocities, dynamically replanning paths if proximity thresholds are approached, thereby maintaining delivery accuracy without halting the beam.

Clinical Applications

Role in 3D Conformal Radiotherapy

In 3D conformal radiotherapy (3D CRT), multileaf collimators (MLCs) play a pivotal role by enabling precise shaping of radiation beams to conform to the three-dimensional contours of the planning target volume (PTV), as derived from computed tomography (CT) imaging. This allows for the delivery of therapeutic doses to irregular tumor shapes while minimizing exposure to adjacent healthy tissues. Typically, treatment plans employ 4-7 coplanar beams, particularly for concave targets such as the prostate, where MLC leaves are positioned to define field apertures that match the PTV projection in the beam's eye view (BEV), ensuring uniform intensity across the target. Dosimetrically, MLCs offer significant advantages over traditional alloy blocks, with improved conformity indices compared to blocks, as the adjustable leaves allow for tighter margins around the PTV. This enhancement results in better organ-at-risk () sparing; for instance, in treatments, MLC-based plans can reduce rectal doses compared to block-defined fields, lowering the risk of complications like . These benefits stem from the MLC's ability to create discrete, reproducible apertures that reduce penumbra and interleaf leakage, leading to more homogeneous dose distributions within the target. The planning workflow for MLC implementation in 3D CRT relies on forward planning techniques, where clinicians manually or semi-automatically adjust leaf positions using BEV visualization to align with tumor contours and exclude OARs. This process integrates CT data into treatment planning systems, generating MLC prescription files that optimize field shapes for multiple gantry angles, with iterative dose calculations to verify coverage. A representative clinical example is the use of MLC-shaped tangent fields in breast cancer radiotherapy, where leaves are adjusted to conform to the irregular breast contour, effectively excluding portions of the lung and heart to limit mean ipsilateral lung doses to 3-11 Gy (median ~7 Gy) and reduce cardiac exposure, thereby lowering pneumonitis and pericarditis risks.

Integration with IMRT and VMAT

In intensity-modulated radiotherapy (IMRT), the multileaf collimator () plays a central role by enabling the creation of multiple beam segments through sequential leaf positioning, typically generating 50-200 segments per treatment plan to approximate desired fluence patterns. This segmental approach involves inverse planning optimization, where fluence maps are convolved with leaf constraints to ensure deliverable apertures that conform to tumor geometry while sparing organs at risk. The step-and-shoot delivery method pauses the beam between segments, allowing precise reconfiguration to modulate intensity non-uniformly across the field. For volumetric modulated arc therapy (VMAT), MLC integration advances to dynamic synchronization, where leaf trajectories are optimized to move continuously with gantry rotation and varying dose rates during arc delivery, significantly reducing overall treatment times to 2-5 minutes compared to fixed-beam IMRT. This adaptation enables real-time modulation of beam fluence along the arc path through synchronized MLC aperture shapes, gantry motion, and dose rate variations. The synchronized motion minimizes inter-segment delays, enhancing efficiency for complex targets. In clinical applications, such as head-and-neck cancers treated with simultaneous integrated boost (SIB) techniques, MLC-modulated IMRT and VMAT achieve high planning target volume (PTV) coverage exceeding 95% while constraining doses to below 45 , facilitating dose escalation to tumors without excessive . These outcomes are particularly beneficial in oropharyngeal cases, where VMAT arcs provide superior conformity around irregular shapes like the . As of 2025, emerging AI-assisted tools in treatment planning systems further optimize MLC trajectories for IMRT and VMAT, improving plan efficiency and accuracy. Treatment planning systems (TPS) like Varian's Eclipse and Philips' Pinnacle incorporate MLC trajectory optimization algorithms tailored for IMRT and VMAT, automating leaf sequencing and fluence adjustments to meet clinical objectives while respecting machine constraints. These tools use iterative solvers to refine MLC positions, ensuring seamless integration from planning to delivery.

Performance and Limitations

Key Specifications and Metrics

Multileaf collimators (MLCs) are characterized by their resolution metrics, which primarily involve leaf width projections at the isocenter to enable precise beam shaping. Typical central leaf widths range from 5 to 10 mm (0.5 to 1 cm), while peripheral leaves are wider at 10 to 20 mm (1 to 2 cm) to accommodate larger field coverage. High-definition designs achieve finer central resolutions of 2.5 mm. The maximum field size supported by most MLC systems is 40 × 40 cm, allowing for broad treatment areas while maintaining collimation integrity. Speed and throughput parameters are critical for efficient delivery in techniques like intensity-modulated radiotherapy (IMRT). Maximum leaf velocities typically range from 1 to 2 cm/s in standard systems, with advanced models reaching 3 to 6.5 cm/s to support dynamic modulation without compromising dose accuracy. These speeds enable rapid reconfiguration in seconds for step-and-shoot segments and continuous motion in dynamic techniques, facilitating efficient treatment sequences. Dosimetric metrics ensure minimal unintended . Interleaf leakage is typically controlled below 2%, often achieving less than 1% through designs, while leaf transmission remains under 2%. The tongue-and-groove effect, which can cause underdosing in adjacent leaf regions during IMRT delivery, is mitigated through optimized leaf sequencing in treatment planning, with the associated geometry minimizing interleaf leakage to below 2% and residual dosimetric impact typically under 5% after compensation. These parameters are verified through standardized protocols to maintain dosimetric precision. Vendor-specific designs highlight variations in these metrics. Varian's HDMLC features 120 leaves with a 2.5 mm central width and 5 mm peripheral width, supporting high-resolution shaping for complex targets. In contrast, Elekta's Agility MLC employs 160 leaves, each 5 mm wide at isocenter, emphasizing uniformity and faster speeds up to 6.5 cm/s for volumetric modulated arc therapy (VMAT). These differences influence capabilities, with finer resolutions improving in stereotactic applications.
VendorModelNumber of LeavesLeaf Width at IsocenterMax Velocity (cm/s)Max Field Size
VarianHDMLC1202.5 mm (central), 5 mm (peripheral)2.5–340 × 40 cm
Elekta1605 mm (uniform)6.540 × 40 cm

Technical Challenges and Solutions

One significant technical challenge in multileaf collimator (MLC) operation is leaf sag due to , which can cause positional deviations of 0.5-1 over a 40 cm leaf travel distance, particularly at angles where acts parallel to the leaf motion. This sag affects the precision of beam shaping, especially in dynamic deliveries like volumetric modulated arc therapy (VMAT). Another issue is transmission through the rounded leaf tips, typically ranging from 3-5%, which contributes to unintended dose leakage and can degrade in shaped fields. Additionally, high-duty cycle operations in intensive treatments can lead to motor overheating, potentially causing mechanical failures or reduced leaf speed accuracy if not managed. To mitigate leaf sag, treatment planning systems (TPS) employ predictive modeling to compensate for gravitational effects by adjusting leaf positions during dose calculations, ensuring dosimetric accuracy within clinical tolerances. Backup jaws are integrated in many MLC designs to block transmission outside the primary field, reducing interleaf leakage to less than 0.5% of the open field dose and minimizing the impact of rounded tip transmission. For overheating, dedicated cooling systems, such as enhanced air or liquid cooling for linear motors, are implemented in high-speed MLCs to maintain performance during prolonged use. Control system feedback loops further support these solutions by providing real-time adjustments to leaf trajectories. Quality assurance (QA) protocols are essential to detect and address these challenges, with the American Association of Physicists in Medicine (AAPM) Task Group 142 recommending monthly tests, including picket-fence patterns to verify dynamic accuracy with tolerances of less than 1 mm positional error. Such errors from misalignment can result in hot or cold spots in the dose distribution, with dosimetric tolerances typically set at less than 2% deviation to ensure and .

Advancements and Future Directions

Recent Technological Improvements

In the 2010s, designs advanced toward thinner leaf widths to support high-precision techniques like and stereotactic body (SBRT). Varian's TrueBeam platform, introduced in 2010 and upgraded with the HD120 MLC, featured 60 central leaves narrowed to 2.5 mm at isocenter—half the width of standard 5 mm leaves—enabling sharper penumbras and better conformity for small targets. This configuration also incorporated faster leaf speeds of up to 2.5 cm/s for the central bank, facilitating dynamic modulation without compromising delivery efficiency. The 2020s brought software enhancements, particularly AI-assisted trajectory planning for intensity-modulated (IMRT) and volumetric modulated arc therapy (VMAT), which automate leaf sequencing and beam angle optimization to reduce planning time compared to manual methods. Integration with MRI-guided linear accelerators further refined MLC performance; the ViewRay MRIdian system, with its commercial rollout of advanced features around 2020, employs a double-stack MLC compatible with 0.35 T magnetic fields, enabling real-time tumor tracking and adaptive adjustments during treatment. Hybrid MLC configurations, merging primary MLCs with tertiary collimators, emerged as adaptations for , providing sub-millimeter lateral precision by dynamically trimming pencil beam spots and reducing penumbra broadening. These systems, often using nickel or alloys, minimize scatter and secondary production while maintaining sharp field edges. Dosimetric improvements from advanced alloy compositions, such as refined mixtures, have contributed to enhanced beam quality and reduced unintended dose to surrounding tissues. In clinical evaluations, these refinements have improved organ-at-risk (OAR) sparing in head-and-neck and thoracic cases, particularly through better low-dose tail control in modulated fields. In 2023, launched its latest generation of s with enhanced leaf speed and precision for VMAT treatments, improving workflow efficiency.

Emerging Research and Innovations

Recent advancements in multileaf collimator () research are focusing on the integration of () and () techniques to enable real-time adaptive adjustments during radiotherapy delivery. These methods leverage onboard imaging systems, such as MRI-guided platforms, to predict and compensate for intrafractional motion, allowing dynamic repositioning of MLC leaves to maintain precise beam shaping. For instance, AI-driven motion management has demonstrated sub-millimeter prediction accuracy for respiratory-induced target displacements, significantly enhancing treatment precision over traditional approaches. Similarly, models applied to intrafractional motion tracking in MRI-guided radiotherapy achieve high positional accuracy, with errors as low as 0.51 mm in tumor simulations. These innovations reduce dosimetric errors associated with organ motion, particularly in thoracic and abdominal sites, by enabling continuous MLC adaptation without interrupting beam delivery. In 2025, experimental demonstrations of MRI-guided tracking for radiotherapy on MR-linacs were reported, allowing adaptation to deformations. Innovative MLC designs, such as dual-layer configurations, are under investigation to support energy-specific beam modulation. Dual-layer MLCs, featuring stacked orthogonal leaf banks, offer improved penumbra control and reduced interleaf leakage compared to single-layer systems, facilitating finer intensity modulation for small fields. Additionally, quantum-inspired optimization algorithms are emerging for complex volumetric modulated arc therapy (VMAT) planning, where MLC trajectories must synchronize with rotation. The Quantum Tunnel Annealing (QTA) method, a quantum-inspired approach, has shown superior convergence and dosimetric quality in intensity-modulated radiotherapy optimization, with potential extension to VMAT for handling nonconvex problems efficiently. Ongoing research highlights gaps in MLC standardization for proton and ion beam therapy, where current systems face challenges in range modulation and scattering control. Prototypes and trials are addressing these issues, demonstrating efficiency gains in spot-scanning delivery through integrated MLCs that enable patient-specific collimation without additional hardware. For example, validation studies of pencil beam scanning proton therapy with MLCs report improved lateral penumbra and reduced setup times, contributing to overall workflow efficiencies in clinical settings. These efforts aim to establish unified performance metrics, such as leaf speed and transmission uniformity, to facilitate broader adoption in particle therapy. As of 2025, advancements include two-dimensional dynamic MLC techniques for enhanced head-and-neck IMRT.