Fact-checked by Grok 2 weeks ago

High-resolution computed tomography

High-resolution computed tomography (HRCT) is a specialized radiographic within computed (CT) that utilizes thin-section , typically with slice thicknesses of 0.625 to 1.25 mm, combined with high-spatial-frequency algorithms such as or sharp kernels, to produce detailed cross-sectional images of the and fine anatomical structures like bronchioles, interlobular septa, and secondary pulmonary lobules. This technique enhances spatial resolution, enabling visualization of subtle parenchymal abnormalities that are often undetectable on standard CT or chest . HRCT differs from conventional CT by prioritizing targeted, high-contrast of the lungs over broad volumetric coverage, though modern multidetector systems allow for full-chest volumetric HRCT acquisitions while maintaining high resolution. Introduced in by Todo et al., HRCT marked a significant advancement in pulmonary by improving the depiction of peripheral vessels, small airways, and changes, overcoming the partial volume effects inherent in thicker-slice protocols. Over the decades, technological evolution has included the development of ultra-high-resolution prototypes with spatial resolutions as fine as 0.12 mm, reducing noise while preserving detail for more precise nodule characterization and disease monitoring. These refinements have positioned HRCT as a cornerstone in the multidisciplinary of diffuse diseases, often serving as the primary noninvasive tool for without the need for contrast enhancement in most cases. Clinically, HRCT is indispensable for evaluating interstitial lung diseases (ILDs), including idiopathic pulmonary fibrosis, sarcoidosis, hypersensitivity pneumonitis, and lymphangitic carcinomatosis, by identifying characteristic distributions such as centrilobular, perilymphatic, or random patterns of reticulation, nodules, ground-glass opacities, or cysts. It excels in distinguishing reversible from irreversible changes, such as ground-glass versus fibrotic opacities, and supports longitudinal monitoring in conditions like cystic fibrosis or post-treatment assessments in connective tissue disease-associated ILDs. Beyond pulmonology, HRCT applications extend to high-detail imaging of bony structures, such as the temporal bone or superior semicircular canal, making it versatile for otolaryngologic and skeletal evaluations. Its high sensitivity and reproducibility have established it as a gold standard for early detection and prognostic stratification in parenchymal lung disorders, frequently guiding decisions on biopsy or therapy.

Overview and Principles

Definition and Historical Development

High-resolution computed tomography (HRCT) is a specialized modality within computed tomography that utilizes thin-section collimation, typically 1–2 mm, paired with high-spatial-frequency algorithms to achieve enhanced depiction of fine pulmonary parenchymal structures and subtle osseous details. This technique excels in non-contrast applications, particularly for evaluating diffuse diseases through visualization of interstitial patterns and for assessing the complex anatomy of the , where it reveals minute bony erosions and malformations. The origins of HRCT trace back to 1982, when Todo et al. first coined the term and demonstrated its value in delineating peripheral pulmonary abnormalities in diffuse diseases, by leveraging thin slices to surpass the limitations of standard resolution. In 1985, Naidich et al. advanced the by outlining an optimized involving targeted thin-section scans, which significantly improved the detection of pathologies compared to conventional thicker-slice imaging. HRCT rose to prominence in the as a cornerstone for diagnosing interstitial lung diseases, driven by a surge of that correlated HRCT patterns with histopathologic findings, thereby establishing its diagnostic superiority over chest in characterizing diffuse parenchymal abnormalities. This era solidified HRCT's role in clinical decision-making for conditions like , with studies highlighting its ability to guide management without invasive biopsies in many cases. A pivotal milestone occurred in the late 1990s with the advent of multi-slice CT scanners, which transitioned HRCT from sequential single-slice acquisitions to volumetric helical scanning, reducing motion artifacts and enabling comprehensive coverage in shorter times. By the , HRCT had integrated into routine radiological practice as the gold standard for evaluating diffuse lung diseases, supported by standardized protocols from the American College of Radiology that emphasize quality imaging for accurate diagnosis and monitoring.

Fundamental Principles and Comparison to Conventional CT

High-resolution computed tomography (HRCT) operates on the fundamental principle of beam attenuation, where the degree to which an beam is absorbed or scattered by tissues is measured and quantified using , a standardized scale that assigns a value of 0 HU and air -1000 HU to characterize tissue density and composition. This attenuation data is reconstructed into cross-sectional images, enabling visualization of anatomical structures based on their differential radiodensity. To achieve superior , HRCT employs reduced sizes—typically through slice thicknesses of 0.5-2 mm and smaller in-plane pixel dimensions (e.g., 0.3-0.5 mm)—which minimize partial volume averaging and allow depiction of fine details smaller than 1 mm, such as interlobular septa in secondary pulmonary lobules or trabecular microstructures. Additionally, edge-enhancing kernels, such as high-spatial-frequency algorithms (e.g., or kernels), sharpen edges by emphasizing high-frequency components in the data, further enhancing the visibility of subtle parenchymal patterns and interfaces without introducing excessive noise. In comparison to conventional CT, which typically uses thicker slices of 5-10 mm to enable rapid, comprehensive volumetric coverage of the chest, HRCT prioritizes over complete sampling, resulting in sharper delineation of microstructures at the cost of potentially missing diffuse or peripheral abnormalities. Traditional HRCT protocols sampled only 10-20% of the volume by acquiring thin sections at spaced intervals (e.g., 1-2 mm slices every 10-20 mm), which reduces patient motion artifacts—particularly from cardiac and respiratory influences—due to shorter acquisition times per slice but can introduce partial effects if intervals are not optimized for the disease pattern. Modern HRCT has evolved toward volumetric acquisition with minimal gaps, balancing gains with improved coverage, though it remains distinct from conventional CT's emphasis on broader anatomical surveying. From a radiation physics perspective, as of the early 2000s, HRCT delivered a lower effective dose, typically 1-3 mSv for limited chest protocols, compared to 5-7 mSv for full conventional chest CT, primarily because of the targeted, intermittent scanning that limits exposure while maintaining diagnostic utility for high-contrast pulmonary structures. This dose reduction stems from narrower beam collimation and fewer slices, aligning with the ALARA (as low as reasonably achievable) principle in medical imaging.

Technical Implementation

Scanning Acquisition Techniques

High-resolution computed tomography (HRCT) scanning acquisition techniques emphasize optimized scanner parameters to achieve thin-section imaging while minimizing artifacts from patient motion and physiological variability. Typically, HRCT protocols employ non-contrast scans using 0.5-1.25 mm collimation and slice thickness to enable high spatial resolution, with tube voltages of 120-140 kVp and effective milliampere-seconds (mAs) ranging from 100-200 to balance image quality and radiation exposure. High-speed gantry rotation times of 0.5-1 second are standard to reduce respiratory motion artifacts, particularly in pulmonary applications, and a targeted field of view (FOV) is applied to focus on regions such as the lungs or temporal bone, enhancing detail without unnecessary broadening of the image matrix. Traditional HRCT acquisition methods often utilize targeted, spaced-section techniques, acquiring images at 10-20 mm intervals across 10 predefined levels to sample the efficiently while limiting scan time and dose. In contrast, modern volumetric approaches leverage multi-detector row (MDCT) scanners to perform full-volume acquisitions covering the entire in under 5 seconds, allowing for comprehensive isotropic imaging that supports subsequent multiplanar reconstructions. This shift from selective to continuous scanning has become prevalent since the early , driven by advancements in detector technology that maintain through thin collimation without prolonging breath-holds. Patient preparation for HRCT focuses on optimizing physiological conditions to ensure artifact-free images, with breath-hold instructions tailored to the phase of : full for standard lung volume assessment and expiration for evaluating in obstructive diseases. positioning is routine for most scans to standardize , though prone positioning may be employed to better detect basilar by redistributing dependent . Sedation is generally not required, as the short acquisition times accommodate cooperative adults and older children without compromising image quality. These techniques rely on thin slices to achieve the sub-millimeter resolution that distinguishes HRCT from conventional , enabling detailed visualization of fine pulmonary structures.

Image Reconstruction and Processing

Image reconstruction in high-resolution computed tomography (HRCT) involves transforming raw projection data into detailed cross-sectional images, primarily using filtered back-projection (FBP) techniques tailored for high . High-frequency reconstruction kernels, often referred to as bone or sharp kernels (e.g., B60f on scanners or "" on systems), are employed to minimize blurring and enhance visualization of fine parenchymal details in the lungs. These kernels amplify high spatial frequencies, improving edge definition for structures like patterns, though they can increase if not balanced with other methods. To address noise while maintaining resolution, iterative reconstruction algorithms have become integral to HRCT processing. These techniques reduce image noise and streak artifacts without necessitating an increase in radiation dose, enabling clearer depiction of subtle lung abnormalities. For instance, model-based iterative reconstruction (MBIR) has been shown to improve overall image quality in HRCT scans of interstitial lung disease by suppressing noise levels comparable to those in conventional FBP while preserving diagnostic fidelity. Recent advancements include photon-counting (PCCT), which uses energy-resolving detectors to achieve ultra-high (up to 0.2 mm) and reduce dose by approximately 47% compared to energy-integrated , enhancing visualization of fine structures like ground-glass opacities and nodules while minimizing noise. As of 2024, PCCT has demonstrated superior image quality and morphology detail in pulmonary HRCT applications. Post-processing steps further optimize HRCT datasets for clinical interpretation. Multi-planar reformatting (MPR) generates sagittal and coronal views from axial acquisitions, facilitating comprehensive assessment of anatomy without additional scanning. Specialized projections enhance specific visualizations: minimum intensity projection (MinIP) highlights low-attenuation areas, aiding detection of and small airway diseases by projecting the lowest density voxels along rays. Conversely, maximum intensity projection (MaxIP) accentuates high-density vascular structures, improving evaluation of pulmonary vessels in HRCT datasets. Artifact management is crucial in HRCT to ensure accurate representation of lung tissue. Beam hardening correction algorithms compensate for the polychromatic nature of X-ray beams, reducing cupping and streaking artifacts caused by dense structures like bones or calcifications adjacent to the lungs. These corrections are typically integrated during reconstruction, using predefined material-specific models to normalize attenuation profiles. Motion correction algorithms, developed and refined in the 2010s, address patient-induced artifacts by aligning sequential slices or estimating displacement vectors, particularly beneficial in non-breath-hold HRCT for dynamic pulmonary evaluations. Such processing is influenced by acquisition parameters like collimation, which determine the initial raw data quality for these optimizations.

Technological Advancements

Evolution with Multi-Detector CT

The introduction of multi-detector computed tomography (MDCT) in 1998 marked a pivotal advancement in high-resolution (HRCT), transitioning from single-slice helical systems to multi-slice configurations with 4 detector rows, enabling simultaneous acquisition of multiple sections per rotation. Subsequent developments rapidly scaled this technology, with 8-slice systems available by 2000 and 64-slice detectors by 2004, allowing for isotropic voxels with resolutions as small as 0.4 mm and significantly faster scan speeds that reduced full-chest acquisition times to under 10 seconds. These MDCT innovations transformed HRCT by facilitating volumetric , which supports retrospective of high-resolution thin-slice images (typically 0.5–1 mm) from thicker source slabs, eliminating the need for prospective contiguous thin-section scanning and minimizing gaps in z-axis coverage. The isotropic nature of MDCT voxels improved z-axis resolution to match in-plane capabilities, enhancing the depiction of fine pulmonary structures such as interlobular and small airways without partial volume artifacts. Additionally, the increased speed enabled dynamic imaging techniques, including 4D-CT for assessing regional through time-resolved contrast enhancement within a single breath-hold. Despite these gains, MDCT introduced trade-offs, particularly in ; early implementations delivered doses approximately five times higher than conventional HRCT (e.g., 10.54 mGy for MDCT versus 2.17 mGy for HRCT at similar tube currents), necessitating dose-modulation strategies like to mitigate risks while preserving image quality. By 2005, MDCT had achieved widespread adoption for HRCT protocols, as reflected in contemporary guidelines from the American College of Radiology emphasizing helical multi-detector acquisition for optimal lung imaging.

Ultra-High Resolution and Quantitative Methods

Ultra-high resolution computed tomography (UHRCT) represents a significant advancement in HRCT technology, primarily enabled by photon-counting detectors (PCDs) that were first introduced commercially in 2021 with the FDA clearance of the Siemens NAEOTOM Alpha system. These detectors achieve spatial resolutions of 0.2-0.4 mm through thinner slice thicknesses and higher matrix sizes, such as 1024 × 1024 with pixel sizes around 0.34 mm, allowing for finer depiction of pulmonary structures. In lung imaging, UHRCT reduces partial voluming artifacts in small airways, improving visualization of bronchial divisions and walls by up to 0.5 segments compared to standard reconstructions, without compromising vessel sharpness or pathology detection. This builds briefly on the foundational improvements from multi-detector CT systems, but focuses on PCD's energy-resolving capabilities for enhanced contrast and reduced noise at lower doses. Quantitative HRCT shifts from subjective visual assessments to objective, automated software-based measurements, enabling precise quantification of lung parenchymal changes. Automated tools analyze lung density using thresholds like -950 Hounsfield units (HU) to delineate emphysema volume as low-attenuation areas, providing reproducible metrics of disease extent that correlate with pulmonary function decline. Texture analysis within these systems further identifies fibrosis patterns by evaluating spatial variations in attenuation, such as ground-glass opacities and reticulation, which have been validated in 2024 studies for tracking idiopathic pulmonary fibrosis (IPF) progression through serial scans showing a monthly decrease in aortic-to-sternal distance by approximately 2.45% in late-stage disease. Recent quantitative metrics emphasize lung heterogeneity via histogram analysis, which derives parameters like kurtosis (measuring distribution peakedness) and skewness (assessing asymmetry) from attenuation histograms to quantify fibrotic heterogeneity. These metrics show moderate correlations with diffusing capacity for carbon monoxide (DLCO; r=0.54 for kurtosis) and forced vital capacity (FVC; r=-0.601 for high-attenuation areas), aiding in progression prediction with areas under the curve up to 0.730. AI-derived scores, such as those from the Computer-Aided Lung Informatics for Pathology Evaluation and Rating (CALIPER) system, automate fibrosis extent measurement, correlating with expert visual scores (r=0.29–0.64) and significantly reducing inter-observer variability compared to manual methods, thereby enhancing reliability in longitudinal monitoring.

Applications in Pulmonary Imaging

Interstitial Lung Diseases

High-resolution computed tomography (HRCT) serves as the gold standard imaging modality for diagnosing and characterizing interstitial lung diseases (ILDs), enabling precise identification of parenchymal abnormalities without the need for invasive procedures in many cases. In ILDs such as (IPF), HRCT reveals key findings including reticular opacities, , and traction , which reflect progressive and architectural distortion. These features are typically distributed in a subpleural and basal predominant pattern, distinguishing the (UIP) pattern characteristic of IPF from other fibrotic ILDs. The UIP pattern on HRCT is defined by the ATS/ERS/JRS/ALAT 2018 guidelines, which categorize diagnostic confidence into UIP (definite, with and no atypical features), probable UIP (reticular abnormalities with traction but absent ), indeterminate for UIP (subtle reticular changes without clear ), and alternative (features suggesting other conditions). In contrast, nonspecific interstitial pneumonia (NSIP) exhibits a peribronchovascular distribution with more uniform ground-glass opacities and less . The Fleischner Society's 2018 criteria align closely, emphasizing these patterns for multidisciplinary , while the 2022 consensus statement standardizes for ILD reporting to improve consistency. HRCT's high specificity for UIP (90-100% predictive value for corresponding ) allows confident of IPF without surgical in approximately 50-70% of cases, particularly when clinical context supports it, reducing procedural risks. Specific ILDs demonstrate distinctive HRCT features that aid differentiation. For instance, , an asbestos-related ILD, shows subpleural reticular opacities and in lower zones, often accompanied by pleural plaques—calcified or noncalcified thickenings indicating asbestos exposure. , an immune-mediated ILD, typically presents with ill-defined centrilobular nodules of in a subacute phase, alongside mosaic attenuation from ; these nodular patterns serve as an adjunct to fibrotic changes in chronic cases. Such findings guide targeted and , underscoring HRCT's role in avoiding through .

Airway and Vascular Abnormalities

High-resolution computed tomography (HRCT) plays a crucial role in identifying and characterizing airway abnormalities, particularly in conditions like and small airway diseases. In , HRCT demonstrates bronchial dilation with a lack of tapering, often visualized as the tram-track sign, where parallel thickened bronchial s appear as longitudinal lines on cross-sectional images. This sign is especially evident in cylindrical , aiding in early and from other airway pathologies. Additionally, quantitative of airway thickness on HRCT provides objective metrics; increased relative thickness, such as a wall area percentage (WA%) greater than 15% for standardized airways (internal perimeter of 10 mm), correlates with inflammatory remodeling in diseases such as (COPD) and . Expiratory HRCT scans enhance detection of , a hallmark of small airway obstruction, appearing as regions of low due to incomplete emptying of airspaces. This finding is quantified by measuring the extent of low-attenuation areas (e.g., below -856 Hounsfield units), offering superior compared to inspiratory scans alone. In , such measurements help progression and response to in obstructive conditions. For vascular abnormalities, HRCT reveals patterns resulting from regional hypoperfusion, commonly seen in where heterogeneous blood flow creates patchy areas of decreased on inspiratory images that equalize on expiration. Indirect signs of include wedge-shaped peripheral infarcts, representing areas of due to ischemic , which HRCT detects with high specificity when correlated with central emboli. These features assist in evaluating vascular contributions to respiratory symptoms without requiring enhancement in select cases. In COPD, HRCT distinguishes emphysema subtypes, such as —characterized by focal lucencies centered on the secondary pulmonary lobule and associated with —and panlobular emphysema, involving uniform destruction across the entire lobule, often linked to . Regarding diagnostic performance, HRCT provides higher sensitivity for detecting structural changes in small airway disease compared to pulmonary function tests alone, enabling earlier identification of subtle obstructive changes before significant spirometric decline.

Nodular and Pattern Recognition

In high-resolution computed tomography (HRCT) of the lungs, nodularity is classified based on distribution patterns that help differentiate underlying pathologies. Perilymphatic nodules, which appear along pleural surfaces, interlobular septa, and bronchovascular bundles, are characteristically seen in , often with upper lobe and perihilar predominance accompanied by lymphadenopathy. Centrilobular nodules, located centrally within secondary pulmonary lobules and sparing the pleura, are typical of infectious , such as in or , and may present as ill-defined opacities. Random nodules, uniformly distributed throughout the lung parenchyma, indicate hematogenous spread, as in or metastases. Nodule size provides additional diagnostic clues; miliary nodules, measuring less than 3 mm in diameter, suggest disseminated infections like , whereas larger nodules exceeding 3 mm are more common in metastatic disease. Beyond nodularity, HRCT identifies key parenchymal patterns that reflect disease processes. (GGO) manifests as hazy increased attenuation without obscuring underlying vessels, often signaling or , such as alveolar filling from or hemorrhage. Consolidation appears as homogeneous opacities that obscure vessel contours, commonly due to or organizing pneumonia with air bronchograms. The tree-in-bud pattern, featuring centrilobular nodules with branching linear opacities, indicates endobronchial spread, as in active or mucoid impaction from . These nodular and pattern recognitions on HRCT enable differentiation of (ILD) etiologies with accuracies ranging from 77% to 93% for specific conditions like and . In ILDs, such patterns, including for advanced , provide a general framework for classification across diseases. During the (2020-2023), HRCT demonstrated high utility in identifying bilateral peripheral GGO as an early hallmark of , with studies reporting its presence in up to 86% of cases and aiding in severity assessment.

Positional and Dynamic Imaging

In high-resolution computed tomography (HRCT) of the lungs, positional imaging employs variations in patient orientation to differentiate gravity-dependent artifacts from intrinsic parenchymal , particularly in the posterior basal regions prone to . positioning is routinely used for standard inspiratory scans, allowing visualization of anterior structures and facilitating expiratory imaging to assess . In contrast, prone scans minimize dependent by shifting gravitational effects away from the dorsal lung bases, thereby enhancing the detection of subtle (ILD) in these areas. This approach is especially valuable for basilar-predominant conditions like , where prone imaging improves diagnostic sensitivity by approximately 28% compared to views alone, as it confirms persistent abnormalities rather than resolving transient collapse. Dynamic imaging extends this by incorporating paired inspiratory and expiratory acquisitions, enabling quantitative evaluation of regional ventilation and small airway function. During expiration, areas of air trapping—indicative of obstructive physiology—appear as regions of low attenuation, typically defined as voxels exceeding -850 Hounsfield units (HU) relative to inspiratory baselines, reflecting incomplete air expulsion due to narrowed or obstructed bronchioles. This technique is particularly effective in identifying obliterative bronchiolitis after lung transplantation, where mosaic attenuation and lobular air trapping on expiratory HRCT correlate with clinical decline and guide immunosuppressive adjustments. Standard protocols integrate these positional and dynamic elements to optimize diagnostic yield, recommending prone views when supine images demonstrate posterior basal opacities to exclude , which can reveal ILD in up to 28% of cases initially deemed indeterminate. Such strategies are endorsed in guidelines for fibrotic lung diseases, including the Pulmonary Fibrosis Foundation's HRCT protocol, which advises prone imaging for dependent densities and paired inspiratory-expiratory scans for suspected airway involvement to support multidisciplinary diagnosis.

Applications in Otolaryngology

Temporal Bone Disorders

High-resolution computed tomography (HRCT) plays a crucial role in evaluating disorders, particularly otologic conditions involving the and structures, by providing detailed visualization of bony essential for preoperative planning. In , HRCT excels at detecting ossicular erosion, a common complication where the , , and may be partially or completely eroded due to . For instance, studies report sensitivity rates of 92.5% for erosion and 93.5% for erosion when correlating HRCT findings with surgical observations. Cholesteatoma, often presenting as a soft-tissue mass in the attic (epitympanum) or attico-antral region, is another key indication where HRCT identifies non-dependent, homogeneous soft-tissue density associated with bony erosion in up to 85.7% of cases. This imaging modality delineates the extent of the mass-like lesion and surrounding bone destruction, aiding in surgical candidacy assessment with an overall accuracy of 95%. Congenital malformations, such as Mondini dysplasia (incomplete partition ), are also effectively diagnosed via HRCT, which reveals characteristic features like a cochlea with only 1.5 turns, a cystic apex, normal vestibule, and enlarged , facilitating decisions on interventions like cochlear implantation. HRCT is the imaging modality of choice for diagnosing superior semicircular canal dehiscence (SSCD), a condition involving thinning or absence of bone overlying the superior semicircular canal, often presenting with symptoms such as vertigo, autophony, or sound- and pressure-induced dizziness. Thin-section HRCT (0.5 mm or less) in the plane parallel to the semicircular canal demonstrates the dehiscence as a distinct defect in the otic capsule, with high sensitivity (up to 98%) for defects larger than 2 mm and aiding in distinguishing true dehiscence from thin bone. This precise depiction guides surgical repair, such as canal plugging or capping, and preoperative planning to avoid complications. Technical adaptations for HRCT of the include thin-slice imaging of 0.5-0.6 mm in axial and coronal planes to achieve submillimeter resolution, enabling visualization of fine structures such as the footplate, which measures approximately 0.3-0.6 mm in thickness. These parameters, often using a and high (e.g., 1024²), enhance depiction of osseous details critical for otologic . The diagnostic value of HRCT lies in its high accuracy for preoperative planning, with reported overall accuracy reaching 95% for conditions like , surpassing MRI in detecting subtle bony dehiscences that may be overlooked on due to its inferior bone . This precision supports surgical navigation by identifying erosion patterns and anatomical variants, though it complements MRI for soft-tissue evaluation in select cases.

Paranasal Sinuses and Adjacent Structures

High-resolution computed tomography (HRCT) plays a crucial role in evaluating for inflammatory conditions such as , where it reveals characteristic findings including mucosal thickening and air-fluid levels indicative of acute . In chronic , HRCT demonstrates as irregular bone sclerosis, , or along sinus walls, correlating with disease severity and refractoriness to treatment. These bony changes reflect underlying inflammatory remodeling rather than , and HRCT's superior allows precise assessment of extent. Neoplastic processes in the are also well-delineated by HRCT, particularly fungal balls, which appear as hyperdense, non-enhancing masses with possible calcifications causing complete sinus opacification. For adjacent structures, HRCT excels in detecting orbital wall erosion or skull base involvement in sinonasal tumors due to its high bony detail, outperforming standard for osseous evaluation while providing adequate soft-tissue contrast. Such findings guide surgical planning by identifying invasion beyond the sinuses. Clinically, HRCT is essential for preoperative assessment in (FESS), mapping disease extent, ostiomeatal complex obstruction, and anatomic variants like Haller cells or that may predispose to recurrent . These variants, such as pneumatized middle turbinates in or infraorbital ethmoidal cells in Haller cells, are reliably identified on coronal HRCT slices, aiding in avoiding surgical complications. By providing a detailed roadmap of sino-nasal , HRCT enhances the safety and efficacy of interventions for both inflammatory and neoplastic pathologies.

Emerging Techniques and Considerations

AI and Machine Learning Integration

The integration of (AI) and (ML) into high-resolution computed tomography (HRCT) has transformed image interpretation, particularly for automated detection and classification tasks in pulmonary . models, such as convolutional neural networks (CNNs), have demonstrated high sensitivity exceeding 95% for detecting pulmonary nodules on chest scans, including HRCT, while maintaining low false-positive rates of less than one per scan. For example, the FDA-cleared InferRead CT software from Infervision, enhanced in 2025 to detect nodules as small as 4 mm, supports radiologists in early identification of potential malignancies by providing automated annotations and prioritization. Similarly, ML models employing CNNs enable subtyping of interstitial lung diseases (ILDs) from HRCT images; a notable approach integrates CT features with clinical data, achieving accurate across five ILD subtypes using datasets from 449 patients and 1,822 s. These models often leverage quantitative metrics, such as texture analysis from HRCT, as inputs to enhance without relying on segmentation. Prognostic applications of AI in HRCT focus on predicting disease progression, particularly fibrosis in ILDs, through radiomics and multimodal integration. Radiomics features extracted from HRCT scans have shown promise in forecasting fibrosis progression, with models achieving an area under the curve () of 0.76 for three-year survival prediction in (IPF) cohorts. For instance, a 2025 machine learning framework combining HRCT with clinical variables effectively stratified patients at risk of progression in coal workers' , outperforming traditional scoring systems. Recent 2025 studies have applied AI-based HRCT quantification to assess ILD severity in diseases, identifying key determinants like DLCO and . Furthermore, integration of HRCT-derived AI outputs with electronic health records (EHRs) enables personalized risk scoring; joint models that fuse imaging data with longitudinal clinical information from EHRs have predicted ILD progression with improved accuracy, aiding in tailored therapeutic decisions. As of 2025, advancements in generative AI are addressing data scarcity in HRCT analysis, especially for . Studies have utilized generative models to create synthetic HRCT images for , expanding training datasets from limited real-world scans—such as augmenting 1,157 fibrotic ILD HRCTs to over 420,000 unique images—to boost model generalizability and performance in underrepresented conditions. This approach, highlighted in 2024 research on synthetic , mitigates challenges in modeling by generating diverse, realistic augmentations that preserve anatomical fidelity while enhancing AI robustness for and detection.

Limitations Including Radiation and Diagnostic Challenges

High-resolution computed tomography (HRCT) exposes patients to , with each chest HRCT scan delivering approximately 3–6 mSv, leading to cumulative doses that can approach 10 mSv annually in scenarios requiring serial imaging for monitoring conditions such as interstitial lung diseases. This cumulative exposure carries a small but significant increased of , estimated at an excess of 0.00042 per mSv, primarily affecting cancer mortality, with heightened vulnerability in younger patients, females, and those undergoing repeated scans. To mitigate these , the ALARA (as low as reasonably achievable) principle guides dose optimization in HRCT protocols. Advancements in techniques have enabled substantial dose reductions in HRCT while preserving diagnostic image quality, with reported decreases of 50–75% in chest CT applications compared to traditional filtered back projection methods, particularly since widespread adoption around 2015. Despite these improvements, remains a key limitation, especially for long-term . Diagnostic challenges in HRCT include partial volume artifacts, which can distort the accurate sizing and depiction of small structures like peripheral vessels or bronchioles due to averaging effects from adjacent tissues, even with thin-slice acquisition (0.5–1.5 mm). Additionally, overlapping patterns such as ground-glass opacities (GGO) pose difficulties in differentiation, as they appear nonspecifically in both infectious processes (e.g., ) and fibrotic conditions (e.g., ), often requiring clinical correlation for resolution. Inter-observer variability further complicates assessments, with moderate agreement (pooled κ ≈ 0.56) among expert radiologists for key features like GGO and ; while tools can mitigate this, residual variability persists. Other limitations encompass contraindications during , where HRCT is generally avoided due to fetal risks (typically <50 mGy per , below thresholds for deterministic effects but with potential concerns like a 1.5–2.0-fold increase in risk at 10–20 mGy), favoring alternatives like or MRI when feasible. HRCT also offers limited soft-tissue contrast compared to MRI, which provides superior detail for non-bony structures such as muscles and organs, restricting HRCT's utility in evaluating adjacent soft tissues.