Your search keyword '"*DICOM (Computer network protocol)"' showing total 2,061 results

1. Digital design and manufacture of a stackable implant surgical guide for immediate loading in completely edentulous full-arch cases: a dental technique.

Author

Abdelaziz, Medhat Sameh and El Sattar Abd El Megid Tella, Eman Abd

Subjects

DENTAL implants, DIGITAL image processing, DENTURES, EDENTULOUS mouth, COMPLETE dentures, COSMETIC dentistry, DICOM (Computer network protocol), DENTAL fillings, PROSTHESIS design & construction, THREE-dimensional printing

Abstract

The design and manufacture of a stackable surgical guide for implant placement with immediate prosthetic loading of completely edentulous cases is described in this dental technique. To achieve this, the stackable attachment is designed using free-form designing software, which is later joined to the implant placement guide and the dental prosthesis. This technique should provide the patient with a same-day implant and an esthetic restoration accurately placed in the predesigned position of the centric occluding relationship. It also reduces the number of visits and prosthetic complications related to the improper implant position. [ABSTRACT FROM AUTHOR]

Published

2023

2. Role of diffusion tensor imaging in diagnosis of patients with carpal tunnel syndrome.

Author

Abdelghaffar, Sondos Mohamed Emad Eldin, Elkammash, Tarek Hamed, Khattab, Yara Hosny, Elshahaly, Mohsen Hassan, and Gad, Azza Abd El-Hamid

Subjects

WRIST radiography, ACADEMIC medical centers, QUALITATIVE research, T-test (Statistics), RECEIVER operating characteristic curves, SEX distribution, FISHER exact test, MAGNETIC resonance imaging, SEVERITY of illness index, AGE distribution, MEDIAN nerve, DESCRIPTIVE statistics, QUANTITATIVE research, CHI-squared test, MANN Whitney U Test, LONGITUDINAL method, CASE-control method, DICOM (Computer network protocol), COMPARATIVE studies, DATA analysis software, CARPAL tunnel syndrome, SENSITIVITY & specificity (Statistics), PREDICTIVE validity, NERVE conduction studies, ELECTROPHYSIOLOGY

Abstract

Background: Carpal tunnel syndrome is the commonest upper limb peripheral neuropathy. Diffusion tensor imaging evaluates the tissue microarchitecture and measures the movement of water protons. It is non-time-consuming, not invasive and not operator dependent. The aim of our study was to evaluate whether diffusion tensor imaging can diagnose carpal tunnel syndrome and whether DTI parameters can correlate with severity of carpal tunnel syndrome. Results: Seventy-two wrists were assessed, 36 diagnosed with carpal tunnel syndrome and 36 age and sex matched controls. FA & ADC were measured at four locations (distal radioulnar joint, proximal, middle and distal carpal tunnel), and the mean for the whole median nerve was calculated. FA & ADC showed statistically significant difference between cases and control at each of the measured four locations and the mean of the whole median nerve. FA & ADC at the hook of hamate (distal CT) showed the most significant difference between cases and control. For FA, the cut-off point at the hook of hamate was 0.5 (sensitivity 94.4%, specificity of 88.9%, positive predictive value 89.5% and negative predictive value 94.1%) and the cut-off point for the mean of the whole nerve was 0.545 (sensitivity 97.22%, specificity 77.78%, positive predictive value 81.4% and negative predictive value 96.6%). For ADC, the cut-off point at the hook of hamate was 1.44 (sensitivity 97.22%, specificity 86.11%, positive predictive value 87.5% and negative predictive value 96.9%) and the cut-off point for the mean of the whole nerve was 1.415 (sensitivity 86.11%, specificity, 83.33%, positive predictive value 83.8% and negative predictive value 85.7%). Conclusion: Diffusion tensor imaging can diagnose carpal tunnel syndrome with accuracy compared to the gold standard nerve conduction studies. Both FA and ADC showed statistically significant differences between cases & controls with FA measurements found to be more significant. [ABSTRACT FROM AUTHOR]

Published

2024

3. Reliability of inter-recti distance measurement on ultrasound images captured by novice examiners.

Author

Chmielewska, Daria, Cebula, Maciej, Gnat, Rafał, Rudek-Zeprzałka, Magdalena, Gruszczyńska, Katarzyna, Baron, Jan, and Opala-Berdzik, Agnieszka

Subjects

*CHILDBEARING age, *BODY mass index, *DESCRIPTIVE statistics, *RESEARCH bias, *NAVEL, *RECTUS abdominis muscles, *DICOM (Computer network protocol), *INTRACLASS correlation, *ANALYSIS of variance, *MUSCLE abnormalities, *CONFIDENCE intervals, *DATA analysis software, *RELIABILITY (Personality trait), *COMPUTER network protocols, RESEARCH evaluation

Abstract

Background: With the increased interest in inter-recti distance measurement using ultrasound imaging in physiotherapy, there is a question of measurement reliability, and the importance of the examiner's experience. Purpose: The study aimed to investigate the reliability of inter-recti distance measurement in a DICOM viewer software by an experienced radiologist. For the measurement, the radiologist used linea alba images captured by two physiotherapists who were novice examiners. Methods: Ultrasound images were acquired by two novice examiners on repeated occasions 7 days apart (sessions A and B) in 28 nulliparous women at supraumbilical, umbilical, and infraumbilical locations along linea alba. Results: Excellent intra-examiner reliability of inter-recti distance measurements was shown at the supraumbilical and umbilical levels (ICC2,k = 0.941–0.983) with minimal detectable change (MDC95) ranging from 1.31 mm to 2.29 mm. Infraumbilical measurements had good to excellent reliability (ICC2,k = 0.894–0.972) with MDC95 ranging from 0.33 mm to 0.72 mm. Session A inter-examiner reliability was excellent for the mean measurements of two, three, four, and five images taken at each location (ICC2,k = 0.913–0.954) with MDC95 ranging from 0.47 mm to 2.96 mm. Session B inter-examiner reliability was excellent for the mean measurements of two, three, four, and five images taken at the supraumbilical and umbilical (ICC2,k = 0.94–0.98), MDC95 ranging from 1.38 mm to 2.58 mm and good (ICC2,k ≥ 0.81) with MDC95 ranging from 0.72 mm to 0.80 mm at the infraumbilical locations. Conclusion: Novice examiners were able to capture good-quality ultrasound images of the linea alba that allowed for good to excellent intra- and inter-examiner reliability. [ABSTRACT FROM AUTHOR]

Published

2024

4. Passive fit and time efficiency for prefabricated versus conventionally constructed cobalt chromium CAD\CAM 3-unit implant supported frameworks in free end saddle models: a pilot invitro study.

Author

Kamel, Mohamed El-Sayed, Alsayed, AlHassan Alaa Eldin, ElKhashab, Mohamed Amr, Nader, Nancy, and Radi, Iman AbdelWahab

Subjects

DENTAL implants, IN vitro studies, DENTAL radiography, DENTAL resins, MATERIALS testing, DENTAL abutments, COMPUTER-aided design, BRIDGES (Dentistry), DENTAL materials, PILOT projects, PROBABILITY theory, DENTAL casting, COMPUTED tomography, COBALT, DESCRIPTIVE statistics, CHI-squared test, CHROMIUM, DICOM (Computer network protocol), PROSTHODONTICS, DATA analysis software, THREE-dimensional printing, PROSTHESIS design & construction

Abstract

Background: The passive fit of 3-unit implant supported prefabricated metal screw-retained prosthesis before implant placement might be difficult. Hence, we aim to evaluate the passive fit and time efficiency of CAD/CAM 3-unit implant supported fixed prostheses that were constructed based on virtual versus those based on actual implant positions in Kennedy Class I models. Methods: A sample of 5 Kennedy class I models with thin wiry ridges were restored by 20 frameworks bilaterally, 10 based on actual (group A) and 10 based on virtual (group V) implant positions. The models were imaged using cone beam computed tomography and scanned using an intraoral scanner. The STL (Standard Tessellation Language files) and the DICOM (Digital Imaging and Communications in Medicine) files were registered on a 3D planning software. A CAD/CAM surgical guide was planned, resin printed and used for installing 6 implants bilaterally. In group V, the framework was designed based on the virtual scan bodies and virtual multi-unit abutments, while in group A intra-oral scanning of the model after attaching the scan bodies was necessary. Frameworks of both groups were milled and tested for passive fit using 8 clinical tests. McNemar and Wilcoxon signed rank tests were used to study the effect of the group on passive fit and time efficiency, respectively. The significance level was set at P ≤ 0.05. Results: No statistically significant difference was found between group V and group A frameworks regarding passive fit (p-value = 1, OR = 0.5) and time efficiency (P = 0.179, Effect size = 0.948). Conclusion: Within the limitations of this study, it can be concluded that in free end saddle cases, prefabricated CAD\CAM 3-unit implant-supported cobalt chromium screw retained prostheses can achieve an adequate passive fit. However, their fit might be negatively affected in thin ridges and they might require some adjustments. [ABSTRACT FROM AUTHOR]

Published

2024

5. Three-Dimensional Evaluation of the Accuracy of Zygomatic Implant Placement Through an In-House Fully Guided Approach.

Author

Hernández-Alfaro, Federico, Bertos-Quílez, Jorge, Valls-Ontañón, Adaia, Paternostro-Betancourt, Daniel, Pindaros-Georgios, Foskolos, and Maria Ragucci, Gian

Subjects

MAXILLA surgery, DENTAL implants, DIGITAL image processing, COMPUTER-assisted surgery, JAW diseases, ZYGOMA, PREOPERATIVE period, DICOM (Computer network protocol), TREATMENT effectiveness, POSTOPERATIVE period, DESCRIPTIVE statistics, THREE-dimensional printing, COMPUTED tomography

Abstract

Purpose: To validate guided surgery for zygomatic implants (ZIs) by analyzing the final position of the implants relative to the preoperatively planned position. Material and Methods: Five patients with fully edentulous atrophic maxillae treated with four ZIs through a fully guided implant surgical approach were evaluated. The preoperative phase included digital planning, through which the surgical guide was designed and created. Analysis of the guided surgery accuracy was carried out by superimposing the digital planning over the final position of the implants using preoperative and postoperative CBCT. The radiologic evaluation included implant angular deviation, entrance deviation, exit deviation, platform deviation, and apex apicocoronal and mesiodistal deviation. Results: All five patients (two men and three women; mean age: 61.8 ± 3 years) were each treated with four ZIs using a fully guided approach with an extrasinusal path, obtaining ideal emergence of the implants. Superimposition comparison found a mean axial angular implant deviation of 0.79 ± 0.41 degrees and a mean implant entrance deviation of 0.95 ± 0.26 degrees. The platform deviation was 0.62 ± 0.19 mm buccopalatally and 0.76 ± 0.14 mm mesiodistally, while the apical deviation was 0.42 ± 0.13 mm buccopalatally and 1.06 ± 0.37 mm mesiodistally. Conclusions: Guided surgery in zygomatic implants appears to be sufficiently accurate to make it a safe and predictable technique. [ABSTRACT FROM AUTHOR]

Published

2023

6. Cone-beam CT landmark detection for measuring basal bone width: a retrospective validation study.

Author

Dai, Juan, Guo, Xinge, Zhang, Hongyuan, Xie, Haoyu, Huang, Jiahui, Huang, Qiangtai, and Huang, Bingsheng

Subjects

MALOCCLUSION, DENTAL radiography, STATISTICAL correlation, T-test (Statistics), DIFFUSION of innovations, RESEARCH funding, COMPUTED tomography, RESEARCH evaluation, DESCRIPTIVE statistics, MAGNETIC resonance imaging, CORRECTIVE orthodontics, RETROSPECTIVE studies, LONGITUDINAL method, DEEP learning, COMPUTER-aided diagnosis, RESEARCH methodology, DICOM (Computer network protocol), MAXILLA, AUTOMATION, MANDIBLE, CONFIDENCE intervals, COMPARATIVE studies

Abstract

Background: Accurate assessment of basal bone width is essential for distinguishing individuals with normal occlusion from patients with maxillary transverse deficiency who may require maxillary expansion. Herein, we evaluated the effectiveness of a deep learning (DL) model in measuring landmarks of basal bone width and assessed the consistency of automated measurements compared to manual measurements. Methods: Based on the U-Net algorithm, a coarse-to-fine DL model was developed and trained using 80 cone-beam computed tomography (CBCT) images. The model's prediction capabilities were validated on 10 CBCT scans and tested on an additional 34. To evaluate the performance of the DL model, its measurements were compared with those taken manually by one junior orthodontist using the concordance correlation coefficient (CCC). Results: It took approximately 1.5 s for the DL model to perform the measurement task in only CBCT images. This framework showed a mean radial error of 1.22 ± 1.93 mm and achieved successful detection rates of 71.34%, 81.37%, 86.77%, and 91.18% in the 2.0-, 2.5-, 3.0-, and 4.0-mm ranges, respectively. The CCCs (95% confidence interval) of the maxillary basal bone width and mandibular basal bone width distance between the DL model and manual measurement for the 34 cases were 0.96 (0.94–0.97) and 0.98 (0.97–0.99), respectively. Conclusion: The novel DL framework developed in this study improved the diagnostic accuracy of the individual assessment of maxillary width. These results emphasize the potential applicability of this framework as a computer-aided diagnostic tool in orthodontic practice. [ABSTRACT FROM AUTHOR]

Published

2024

7. Development and validation of predictive models for skeletal malocclusion classification using airway and cephalometric landmarks.

Author

Marya, Anand, Inglam, Samroeng, Chantarapanich, Nattapon, Wanchat, Sujin, Rithvitou, Horn, and Naronglerdrit, Prasitthichai

Subjects

MALOCCLUSION, RANDOM forest algorithms, PREDICTION models, THREE-dimensional imaging, COMPUTED tomography, ARTIFICIAL intelligence, CEPHALOMETRY, RETROSPECTIVE studies, DEEP learning, DICOM (Computer network protocol), HUMAN body, PREDICTIVE validity, SENSITIVITY & specificity (Statistics)

Abstract

Objective: This study aimed to develop a deep learning model to predict skeletal malocclusions with an acceptable level of accuracy using airway and cephalometric landmark values obtained from analyzing different CBCT images. Background: In orthodontics, multitudinous studies have reported the correlation between orthodontic treatment and changes in the anatomy as well as the functioning of the airway. Typically, the values obtained from various measurements of cephalometric landmarks are used to determine skeletal class based on the interpretation an orthodontist experiences, which sometimes may not be accurate. Methods: Samples of skeletal anatomical data were retrospectively obtained and recorded in Digital Imaging and Communications in Medicine (DICOM) file format. The DICOM files were used to reconstruct 3D models using 3DSlicer (slicer.org) by thresholding airway regions to build up 3D polygon models of airway regions for each sample. The 3D models were measured for different landmarks that included measurements across the nasopharynx, the oropharynx, and the hypopharynx. Male and female subjects were combined as one data set to develop supervised learning models. These measurements were utilized to build 7 artificial intelligence-based supervised learning models. Results: The supervised learning model with the best accuracy was Random Forest, with a value of 0.74. All the other models were lower in terms of their accuracy. The recall scores for Class I, II, and III malocclusions were 0.71, 0.69, and 0.77, respectively, which represented the total number of actual positive cases predicted correctly, making the sensitivity of the model high. Conclusion: In this study, it is observed that the Random Forest model was the most accurate model for predicting the skeletal malocclusion based on various airway and cephalometric landmarks. [ABSTRACT FROM AUTHOR]

Published

2024

8. Lumbar multifidus layers stiffness at L5-S1 level in prone and sitting posture measured by shear wave elastography.

Author

Bastos de Oliveira, Viviane, Albuquerque Brandão, Maria Clara, Coelho de Albuquerque Pereira, Wagner, and Fernandes de Oliveira, Liliam

Subjects

*MYALGIA, *RESEARCH funding, *ERGONOMICS, *LYING down position, *QUESTIONNAIRES, *BACK muscles, *DESCRIPTIVE statistics, *MANN Whitney U Test, *LUMBAR vertebrae, *SITTING position, *DICOM (Computer network protocol), *INFERENTIAL statistics, *SACRUM, *POSTURE, *DIGITAL image processing, *DATA analysis software, *NONPARAMETRIC statistics, *LUMBAR pain

Abstract

BACKGROUND: Multifidus is an important lumbar muscle with distinct superficial and deep fibers responsible for torque production and stabilization, respectively. Its mechanical properties change when transitioning from lying to sitting positions, necessitating enhanced stability. It holds crucial clinical relevance to assess these layers separately, especially in the sitting posture, which demands increased neuromuscular control compared to the prone position. OBJECTIVE: To compare lumbar multifidus stiffness in lying versus sitting postures, analyzing both superficial and deep layers. METHODS: Supersonic Shear Imaging captured elastographic images from 26 asymptomatic volunteers in prone and seated positions. RESULTS: Left multifidus shear modulus in lying: 5.98 ± 1.80/7.96 ± 1.59 kPa (deep/superficial) and sitting: 12.58 ± 4.22/16.04 ± 6.65 kPa. Right side lying: 6.08 ± 1.97/7.80 ± 1.76 kPa and sitting: 13.25 ± 4.61/17.95 ± 7.12 kPa. No side differences (lying p = 0.99, sitting p = 0.43). However, significant inter-postural differences occurred. CONCLUSION: Lumbar multifidus exhibits increased stiffness in sitting, both layers affected, with superior stiffness in superficial versus deep fibers. Applying these findings could enhance assessing multifidus stiffness changes, for classifying tension-induced low back pain stages. [ABSTRACT FROM AUTHOR]

Published

2024

9. Deep Learning–based Segmentation of Computed Tomography Scans Predicts Disease Progression and Mortality in Idiopathic Pulmonary Fibrosis.

Author

Thillai, Muhunthan, Oldham, Justin M., Ruggiero, Alessandro, Kanavati, Fahdi, McLellan, Tom, Saini, Gauri, Johnson, Simon R., Ble, Francois-Xavier, Azim, Adnan, Ostridge, Kristoffer, Platt, Adam, Belvisi, Maria, Maher, Toby M., and Molyneaux, Philip L.

Subjects

COMPUTED tomography, DISEASE progression, LUNG volume, PROGRESSION-free survival, MORTALITY, CAUSE of death statistics, IDIOPATHIC pulmonary fibrosis, DICOM (Computer network protocol)

Abstract

Rationale: Despite evidence demonstrating a prognostic role for computed tomography (CT) scans in idiopathic pulmonary fibrosis (IPF), image-based biomarkers are not routinely used in clinical practice or trials. Objectives: To develop automated imaging biomarkers using deep learning–based segmentation of CT scans. Methods: We developed segmentation processes for four anatomical biomarkers, which were applied to a unique cohort of treatment-naive patients with IPF enrolled in the PROFILE (Prospective Observation of Fibrosis in the Lung Clinical Endpoints) study and tested against a further United Kingdom cohort. The relationships among CT biomarkers, lung function, disease progression, and mortality were assessed. Measurements and Main Results: Data from 446 PROFILE patients were analyzed. Median follow-up duration was 39.1 months (interquartile range, 18.1–66.4 mo), with a cumulative incidence of death of 277 (62.1%) over 5 years. Segmentation was successful on 97.8% of all scans, across multiple imaging vendors, at slice thicknesses of 0.5–5 mm. Of four segmentations, lung volume showed the strongest correlation with FVC (r = 0.82; P < 0.001). Lung, vascular, and fibrosis volumes were consistently associated across cohorts with differential 5-year survival, which persisted after adjustment for baseline gender, age, and physiology score. Lower lung volume (hazard ratio [HR], 0.98 [95% confidence interval (CI), 0.96–0.99]; P = 0.001), increased vascular volume (HR, 1.30 [95% CI, 1.12–1.51]; P = 0.001), and increased fibrosis volume (HR, 1.17 [95% CI, 1.12–1.22]; P < 0.001) were associated with reduced 2-year progression-free survival in the pooled PROFILE cohort. Longitudinally, decreasing lung volume (HR, 3.41 [95% CI, 1.36–8.54]; P = 0.009) and increasing fibrosis volume (HR, 2.23 [95% CI, 1.22–4.08]; P = 0.009) were associated with differential survival. Conclusions: Automated models can rapidly segment IPF CT scans, providing prognostic near and long-term information, which could be used in routine clinical practice or as key trial endpoints. [ABSTRACT FROM AUTHOR]

Published

2024

10. Deep Learning for Automatic Gross Tumor Volumes Contouring in Esophageal Cancer Based on Contrast-Enhanced Computed Tomography Images: A Multi-Institutional Study.

Author

Zhang, Shuaitong, Li, Kunwei, Sun, Yuchen, Wan, Yun, Ao, Yong, Zhong, Yinghua, Liang, Mingzhu, Wang, Lizhu, Chen, Xiangmeng, Pei, Xiaofeng, Hu, Yi, Chen, Duanduan, Li, Man, and Shan, Hong

Subjects

*DEEP learning, *RADIOTHERAPY treatment planning, *PATHOLOGIC complete response, *ESOPHAGEAL cancer, *DICOM (Computer network protocol), *RADIOMICS, *AORTIC valve insufficiency

Abstract

To develop and externally validate an automatic artificial intelligence (AI) tool for delineating gross tumor volume (GTV) in patients with esophageal squamous cell carcinoma (ESCC), which can assist in neo-adjuvant or radical radiation therapy treatment planning. In this multi-institutional study, contrast-enhanced CT images from 580 eligible ESCC patients were retrospectively collected. The GTV contours delineated by 2 experts via consensus were used as ground truth. A 3-dimensional deep learning model was developed for GTV contouring in the training cohort and internally and externally validated in 3 validation cohorts. The AI tool was compared against 12 board-certified experts in 25 patients randomly selected from the external validation cohort to evaluate its assistance in improving contouring performance and reducing variation. Contouring performance was measured using dice similarity coefficient (DSC) and average surface distance. Additionally, our previously established radiomics model for predicting pathologic complete response was used to compare AI-generated and ground truth contours, to assess the potential of the AI contouring tool in radiomics analysis. The AI tool demonstrated good GTV contouring performance in multicenter validation cohorts, with median DSC values of 0.865, 0.876, and 0.866 and median average surface distance values of 0.939, 0.789, and 0.875 mm, respectively. Furthermore, the AI tool significantly improved contouring performance for half of 12 board-certified experts (DSC values, 0.794-0.835 vs 0.856-0.881, P =.003-0.048), reduced the intra- and interobserver variations by 37.4% and 55.2%, respectively, and saved contouring time by 77.6%. In the radiomics analysis, 88.7% of radiomic features from ground truth and AI-generated contours demonstrated stable reproducibility, and similar pathologic complete response prediction performance for these contours (P =.430) was observed. Our AI contouring tool can improve GTV contouring performance and facilitate radiomics analysis in ESCC patients, which indicates its potential for GTV contouring during radiation therapy treatment planning and radiomics studies. [ABSTRACT FROM AUTHOR]

Published

2024

11. Low-contrast lesion detection in neck CT: a multireader study comparing deep learning, iterative, and filtered back projection reconstructions using realistic phantoms.

Author

Bellmann, Quirin, Peng, Yang, Genske, Ulrich, Yan, Li, Wagner, Moritz, and Jahnke, Paul

Subjects

DEEP learning, REAR-screen projection, RECEIVER operating characteristic curves, COMPUTED tomography, NECK, DICOM (Computer network protocol)

Abstract

Background: Computed tomography (CT) reconstruction algorithms can improve image quality, especially deep learning reconstruction (DLR). We compared DLR, iterative reconstruction (IR), and filtered back projection (FBP) for lesion detection in neck CT. Methods: Nine patient-mimicking neck phantoms were examined with a 320-slice scanner at six doses: 0.5, 1, 1.6, 2.1, 3.1, and 5.2 mGy. Each of eight phantoms contained one circular lesion (diameter 1 cm; contrast -30 HU to the background) in the parapharyngeal space; one phantom had no lesions. Reconstruction was made using FBP, IR, and DLR. Thirteen readers were tasked with identifying and localizing lesions in 32 images with a lesion and 20 without lesions for each dose and reconstruction algorithm. Receiver operating characteristic (ROC) and localization ROC (LROC) analysis were performed. Results: DLR improved lesion detection with ROC area under the curve (AUC) 0.724 ± 0.023 (mean ± standard error of the mean) using DLR versus 0.696 ± 0.021 using IR (p = 0.037) and 0.671 ± 0.023 using FBP (p < 0.001). Likewise, DLR improved lesion localization, with LROC AUC 0.407 ± 0.039 versus 0.338 ± 0.041 using IR (p = 0.002) and 0.313 ± 0.044 using FBP (p < 0.001). Dose reduction to 0.5 mGy compromised lesion detection in FBP-reconstructed images compared to doses ≥ 2.1 mGy (p ≤ 0.024), while no effect was observed with DLR or IR (p ≥ 0.058). Conclusion: DLR improved the detectability of lesions in neck CT imaging. Dose reduction to 0.5 mGy maintained lesion detectability when denoising reconstruction was used. Relevance statement: Deep learning enhances lesion detection in neck CT imaging compared to iterative reconstruction and filtered back projection, offering improved diagnostic performance and potential for x-ray dose reduction. Key Points: Low-contrast lesion detectability was assessed in anatomically realistic neck CT phantoms. Deep learning reconstruction (DLR) outperformed filtered back projection and iterative reconstruction. Dose has little impact on lesion detectability against anatomical background structures. [ABSTRACT FROM AUTHOR]

Published

2024

12. Parkinson's image detection and classification based on deep learning.

Author

Li, Hui, Yang, Zixuan, Qi, Weimin, Yu, Xinchen, Wu, Jiaying, and Li, Haining

Subjects

PARKINSON'S disease, IMAGE recognition (Computer vision), DEEP learning, MAGNETIC resonance imaging, SIGNAL convolution, DICOM (Computer network protocol), EARLY diagnosis

Abstract

Objective: There are two major issues in the MRI image diagnosis task for Parkinson's disease. Firstly, there are slight differences in MRI images between healthy individuals and Parkinson's patients, and the medical field has not yet established precise lesion localization standards, which poses a huge challenge for the effective prediction of Parkinson's disease through MRI images. Secondly, the early diagnosis of Parkinson's disease traditionally relies on the subjective judgment of doctors, which leads to insufficient accuracy and consistency. This article proposes an improved YOLOv5 detection algorithm based on deep learning for predicting and classifying Parkinson's images. Methods: This article improves the YOLOv5s network as the basic framework. Firstly, the CA attention mechanism was introduced to enable the model to dynamically adjust attention based on local features of the image, significantly enhancing the sensitivity of the model to PD related small pathological features; Secondly, replace the dynamic full dimensional convolution module to optimize the multi-level extraction of image features; Finally, the coupling head strategy is adopted to improve the execution efficiency of classification and localization tasks separately. Results: We validated the effectiveness of the proposed method using a dataset of 582 MRI images from 108 patients. The results show that the proposed method achieves 0.961, 0.974, and 0.986 in Precision, Recall, and mAP, respectively, and the experimental results are superior to other algorithms. Conslusion: The improved model has achieved high accuracy and detection accuracy, and can accurately detect and recognize complex Parkinson's MRI images. Significance: This algorithm has shown good performance in the early diagnosis of Parkinson's disease and can provide clinical assistance for doctors in early diagnosis. It compensates for the limitations of traditional methods. [ABSTRACT FROM AUTHOR]

Published

2024

13. Deep Learning Auto-Segmentation Network for Pediatric Computed Tomography Data Sets: Can We Extrapolate From Adults?

Author

Kumar, Kartik, Yeo, Adam U., McIntosh, Lachlan, Kron, Tomas, Wheeler, Greg, and Franich, Rick D.

Subjects

*COMPUTED tomography, *DEEP learning, *ADULTS, *IMAGE analysis, *AGE groups, *AUTOETHNOGRAPHY, *DICOM (Computer network protocol)

Abstract

Artificial intelligence (AI)–based auto-segmentation models hold promise for enhanced efficiency and consistency in organ contouring for adaptive radiation therapy and radiation therapy planning. However, their performance on pediatric computed tomography (CT) data and cross-scanner compatibility remain unclear. This study aimed to evaluate the performance of AI-based auto-segmentation models trained on adult CT data when applied to pediatric data sets and explore the improvement in performance gained by including pediatric training data. It also examined their ability to accurately segment CT data acquired from different scanners. Using the nnU-Net framework, segmentation models were trained on data sets of adult, pediatric, and combined CT scans for 7 pelvic/thoracic organs. Each model was trained on 290 to 300 cases per category and organ. Training data sets included a combination of clinical data and several open repositories. The study incorporated a database of 459 pediatric (0-16 years) CT scans and 950 adults (>18 years), ensuring all scans had human expert ground-truth contours of the selected organs. Performance was evaluated based on Dice similarity coefficients (DSC) of the model-generated contours. AI models trained exclusively on adult data underperformed on pediatric data, especially for the 0 to 2 age group: mean DSC was below 0.5 for the bladder and spleen. The addition of pediatric training data demonstrated significant improvement for all age groups, achieving a mean DSC of above 0.85 for all organs in every age group. Larger organs like the liver and kidneys maintained consistent performance for all models across age groups. No significant difference emerged in the cross-scanner performance evaluation, suggesting robust cross-scanner generalization. For optimal segmentation across age groups, it is important to include pediatric data in the training of segmentation models. The successful cross-scanner generalization also supports the real-world clinical applicability of these AI models. This study emphasizes the significance of data set diversity in training robust AI systems for medical image interpretation tasks. [ABSTRACT FROM AUTHOR]

Published

2024

14. Artificial intelligence-based graded training of pulmonary nodules for junior radiology residents and medical imaging students.

Author

Lyu, Xiaohong, Dong, Liang, Fan, Zhongkai, Sun, Yu, Zhang, Xianglin, Liu, Ning, and Wang, Dongdong

Subjects

RESIDENTS (Medicine), ARTIFICIAL intelligence, COMPUTER-assisted image analysis (Medicine), RADIOLOGY, DIAGNOSTIC imaging, PULMONARY nodules, DICOM (Computer network protocol)

Abstract

Background: To evaluate the efficiency of artificial intelligence (AI)-assisted diagnosis system in the pulmonary nodule detection and diagnosis training of junior radiology residents and medical imaging students. Methods: The participants were divided into three groups. Medical imaging students of Grade 2020 in the Jinzhou Medical University were randomly divided into Groups 1 and 2; Group 3 comprised junior radiology residents. Group 1 used the traditional case-based teaching mode; Groups 2 and 3 used the 'AI intelligent assisted diagnosis system' teaching mode. All participants performed localisation, grading and qualitative diagnosed of 1,057 lung nodules in 420 cases for seven rounds of testing after training. The sensitivity and number of false positive nodules in different densities (solid, pure ground glass, mixed ground glass and calcification), sizes (less than 5 mm, 5–10 mm and over 10 mm) and positions (subpleural, peripheral and central) of the pulmonary nodules in the three groups were detected. The pathological results and diagnostic opinions of radiologists formed the criteria. The detection rate, diagnostic compliance rate, false positive number/case, and kappa scores of the three groups were compared. Results: There was no statistical difference in baseline test scores between Groups 1 and 2, and there were statistical differences with Group 3 (P = 0.036 and 0.011). The detection rate of solid, pure ground glass and calcified nodules; small-, medium-, and large-diameter nodules; and peripheral nodules were significantly different among the three groups (P<0.05). After seven rounds of training, the diagnostic compliance rate increased in all three groups, with the largest increase in Group 2. The average kappa score increased from 0.508 to 0.704. The average kappa score for Rounds 1–4 and 5–7 were 0.595 and 0.714, respectively. The average kappa scores of Groups 1,2 and 3 increased from 0.478 to 0.658, 0.417 to 0.757, and 0.638 to 0.791, respectively. Conclusion: The AI assisted diagnosis system is a valuable tool for training junior radiology residents and medical imaging students to perform pulmonary nodules detection and diagnosis. [ABSTRACT FROM AUTHOR]

Published

2024

15. Evaluating Deep Learning Techniques for Detecting Aneurysmal Subarachnoid Hemorrhage: A Comparative Analysis of Convolutional Neural Network and Transfer Learning Models.

Author

Etli, Mustafa Umut, Başarslan, Muhammet Sinan, Varol, Eyüp, Sarıkaya, Hüseyin, Çakıcı, Yunus Emre, Öndüç, Gonca Gül, Bal, Fatih, Kayalar, Ali Erhan, and Aykılıç, Ömer

Subjects

*CONVOLUTIONAL neural networks, *DEEP learning, *SUBARACHNOID hemorrhage, *DICOM (Computer network protocol), *DIGITAL subtraction angiography, *MACHINE learning

Abstract

Machine learning and deep learning techniques offer a promising multidisciplinary solution for subarachnoid hemorrhage (SAH) detection. The novel transfer learning approach mitigates the time constraints associated with the traditional techniques and demonstrates a superior performance. This study aims to evaluate the effectiveness of convolutional neural networks (CNNs) and CNN-based transfer learning models in differentiating between aneurysmal SAH and nonaneurysmal SAH. Data from Istanbul Ümraniye Training and Research Hospital, which included 15,600 digital imaging and communications in medicine images from 123 patients with aneurysmal SAH and 7793 images from 80 patients with nonaneurysmal SAH, were used. The study employed 4 models: Inception-V3, EfficientNetB4, single-layer CNN, and three-layer CNN. Transfer learning models were customized by modifying the last 3 layers and using the Adam optimizer. The models were trained on Google Collaboratory and evaluated based on metrics such as F-score, precision, recall, and accuracy. EfficientNetB4 demonstrated the highest accuracy (99.92%), with a better F-score (99.82%), recall (99.92%), and precision (99.90%) than the other methods. The single- and three-layer CNNs and the transfer learning models produced comparable results. No overfitting was observed, and robust models were developed. CNN-based transfer learning models can accurately diagnose the etiology of SAH from computed tomography images and is a valuable tool for clinicians. This approach could reduce the need for invasive procedures such as digital subtraction angiography, leading to more efficient medical resource utilization and improved patient outcomes. [ABSTRACT FROM AUTHOR]

Published

2024

16. Prediction of disease severity in COPD: a deep learning approach for anomaly-based quantitative assessment of chest CT.

Author

Almeida, Silvia D., Norajitra, Tobias, Lüth, Carsten T., Wald, Tassilo, Weru, Vivienn, Nolden, Marco, Jäger, Paul F., von Stackelberg, Oyunbileg, Heußel, Claus Peter, Weinheimer, Oliver, Biederer, Jürgen, Kauczor, Hans-Ulrich, and Maier-Hein, Klaus

Subjects

*COMPUTED tomography, *DEEP learning, *CHRONIC obstructive pulmonary disease, *SPEECH processing systems, *DICOM (Computer network protocol)

Abstract

Objectives: To quantify regional manifestations related to COPD as anomalies from a modeled distribution of normal-appearing lung on chest CT using a deep learning (DL) approach, and to assess its potential to predict disease severity. Materials and methods: Paired inspiratory/expiratory CT and clinical data from COPDGene and COSYCONET cohort studies were included. COPDGene data served as training/validation/test data sets (N = 3144/786/1310) and COSYCONET as external test set (N = 446). To differentiate low-risk (healthy/minimal disease, [GOLD 0]) from COPD patients (GOLD 1–4), the self-supervised DL model learned semantic information from 50 × 50 × 50 voxel samples from segmented intact lungs. An anomaly detection approach was trained to quantify lung abnormalities related to COPD, as regional deviations. Four supervised DL models were run for comparison. The clinical and radiological predictive power of the proposed anomaly score was assessed using linear mixed effects models (LMM). Results: The proposed approach achieved an area under the curve of 84.3 ± 0.3 (p < 0.001) for COPDGene and 76.3 ± 0.6 (p < 0.001) for COSYCONET, outperforming supervised models even when including only inspiratory CT. Anomaly scores significantly improved fitting of LMM for predicting lung function, health status, and quantitative CT features (emphysema/air trapping; p < 0.001). Higher anomaly scores were significantly associated with exacerbations for both cohorts (p < 0.001) and greater dyspnea scores for COPDGene (p < 0.001). Conclusion: Quantifying heterogeneous COPD manifestations as anomaly offers advantages over supervised methods and was found to be predictive for lung function impairment and morphology deterioration. Clinical relevance statement: Using deep learning, lung manifestations of COPD can be identified as deviations from normal-appearing chest CT and attributed an anomaly score which is consistent with decreased pulmonary function, emphysema, and air trapping. Key Points: • A self-supervised DL anomaly detection method discriminated low-risk individuals and COPD subjects, outperforming classic DL methods on two datasets (COPDGene AUC = 84.3%, COSYCONET AUC = 76.3%). • Our contrastive task exhibits robust performance even without the inclusion of expiratory images, while voxel-based methods demonstrate significant performance enhancement when incorporating expiratory images, in the COPDGene dataset. • Anomaly scores improved the fitting of linear mixed effects models in predicting clinical parameters and imaging alterations (p < 0.001) and were directly associated with clinical outcomes (p < 0.001). [ABSTRACT FROM AUTHOR]

Published

2024

17. Deep learning for malignancy risk estimation of incidental sub-centimeter pulmonary nodules on CT images.

Author

Zhang, Rui, Wei, Ying, Wang, Denian, Chen, Bojiang, Sun, Huaiqiang, Lei, Yi, Zhou, Qing, Luo, Zhuang, Jiang, Li, Qiu, Rong, Shi, Feng, and Li, Weimin

Subjects

*DEEP learning, *PULMONARY nodules, *COMPUTED tomography, *MACHINE learning, *DELAYED diagnosis, *DICOM (Computer network protocol), *SIGNAL convolution, *MEDICAL personnel

Abstract

Objectives: To establish deep learning models for malignancy risk estimation of sub-centimeter pulmonary nodules incidentally detected by chest CT and managed in clinical settings. Materials and methods: Four deep learning models were trained using CT images of sub-centimeter pulmonary nodules from West China Hospital, internally tested, and externally validated on three cohorts. The four models respectively learned 3D deep features from the baseline whole lung region, baseline image patch where the nodule located, baseline nodule box, and baseline plus follow-up nodule boxes. All regions of interest were automatically segmented except that the nodule boxes were additionally manually checked. The performance of models was compared with each other and that of three respiratory clinicians. Results: There were 1822 nodules (981 malignant) in the training set, 806 (416 malignant) in the testing set, and 357 (253 malignant) totally in the external sets. The area under the curve (AUC) in the testing set was 0.754, 0.855, 0.928, and 0.942, respectively, for models derived from baseline whole lung, image patch, nodule box, and the baseline plus follow-up nodule boxes. When baseline models externally validated (follow-up images not available), the nodule-box model outperformed the other two with AUC being 0.808, 0.848, and 0.939 respectively in the three external datasets. The resident, junior, and senior clinicians achieved an accuracy of 67.0%, 82.5%, and 90.0%, respectively, in the testing set. The follow-up model performed comparably to the senior clinician. Conclusion: The deep learning algorithms solely mining nodule information can efficiently predict malignancy of incidental sub-centimeter pulmonary nodules. Clinical relevance statement: The established models may be valuable for supporting clinicians in routine clinical practice, potentially reducing the number of unnecessary examinations and also delays in diagnosis. Key Points: • According to different regions of interest, four deep learning models were developed and compared to evaluate the malignancy of sub-centimeter pulmonary nodules by CT images. • The models derived from baseline nodule box or baseline plus follow-up nodule boxes demonstrated sufficient diagnostic accuracy (86.4% and 90.4% in the testing set), outperforming the respiratory resident (67.0%) and junior clinician (82.5%). • The proposed deep learning methods may aid clinicians in optimizing follow-up recommendations for sub-centimeter pulmonary nodules and may lead to fewer unnecessary diagnostic interventions. [ABSTRACT FROM AUTHOR]

Published

2024

18. Cyber attacks on radiological systems.

Author

Viculin, Davor and Mihanović, Frane

Subjects

COMPUTER networking equipment, EMAIL software, SOFTWARE maintenance, DICOM (Computer network protocol), CYBERTERRORISM

Abstract

Copyright of Radiology News Journal / Radiološki Vjesnik is the property of Croatian Association of Radiation Technology and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2024

19. Multimodality imaging for intraprocedural guidance of a transcatheter tricuspid valve replacement.

Author

Willemen, Yannick, Møller, Jacob E, Nejjari, Mohammed, Linde, Jesper J, Vejlstrup, Niels G, Bardeleben, Ralph S von, Latib, Azeem, Modine, Thomas, and Backer, Ole De

Subjects

TRICUSPID valve, TRANSESOPHAGEAL echocardiography, AORTIC valve, COMPUTED tomography, TREATMENT effectiveness, HEART valve prosthesis implantation, CATHETERS, DICOM (Computer network protocol), DIGITAL image processing, ECHOCARDIOGRAPHY, FLUOROSCOPY

Published

2024

20. Deep learning image reconstruction generates thinner slice iodine maps with improved image quality to increase diagnostic acceptance and lesion conspicuity: a prospective study on abdominal dual-energy CT.

Author

Zhong, Jingyu, Wang, Lingyun, Yan, Chao, Xing, Yue, Hu, Yangfan, Ding, Defang, Ge, Xiang, Li, Jianying, Lu, Wei, Shi, Xiaomeng, Yuan, Fei, Yao, Weiwu, and Zhang, Huan

Subjects

IMAGE reconstruction, DEEP learning, STAB wounds, IODINE, MULTIDETECTOR computed tomography, LONGITUDINAL method, DICOM (Computer network protocol)

Abstract

Background: To assess the improvement of image quality and diagnostic acceptance of thinner slice iodine maps enabled by deep learning image reconstruction (DLIR) in abdominal dual-energy CT (DECT). Methods: This study prospectively included 104 participants with 136 lesions. Four series of iodine maps were generated based on portal-venous scans of contrast-enhanced abdominal DECT: 5-mm and 1.25-mm using adaptive statistical iterative reconstruction-V (Asir-V) with 50% blending (AV-50), and 1.25-mm using DLIR with medium (DLIR-M), and high strength (DLIR-H). The iodine concentrations (IC) and their standard deviations of nine anatomical sites were measured, and the corresponding coefficient of variations (CV) were calculated. Noise-power-spectrum (NPS) and edge-rise-slope (ERS) were measured. Five radiologists rated image quality in terms of image noise, contrast, sharpness, texture, and small structure visibility, and evaluated overall diagnostic acceptability of images and lesion conspicuity. Results: The four reconstructions maintained the IC values unchanged in nine anatomical sites (all p > 0.999). Compared to 1.25-mm AV-50, 1.25-mm DLIR-M and DLIR-H significantly reduced CV values (all p < 0.001) and presented lower noise and noise peak (both p < 0.001). Compared to 5-mm AV-50, 1.25-mm images had higher ERS (all p < 0.001). The difference of the peak and average spatial frequency among the four reconstructions was relatively small but statistically significant (both p < 0.001). The 1.25-mm DLIR-M images were rated higher than the 5-mm and 1.25-mm AV-50 images for diagnostic acceptability and lesion conspicuity (all P < 0.001). Conclusions: DLIR may facilitate the thinner slice thickness iodine maps in abdominal DECT for improvement of image quality, diagnostic acceptability, and lesion conspicuity. [ABSTRACT FROM AUTHOR]

Published

2024

21. Development and validation of radiomic signature for predicting overall survival in advanced-stage cervical cancer.

Author

Jha, Ashish Kumar, Mithun, Sneha, Sherkhane, Umeshkumar B., Jaiswar, Vinay, Shah, Sneha, Purandare, Nilendu, Prabhash, Kumar, Maheshwari, Amita, Gupta, Sudeep, Wee, Leonard, Rangarajan, V., and Dekker, Andre

Subjects

RANDOM forest algorithms, SQUAMOUS cell carcinoma, CERVIX uteri tumors, PREDICTION models, DATA analysis, RESEARCH funding, RADIOMICS, LOGISTIC regression analysis, DIGITAL signatures, CHEMORADIOTHERAPY, POSITRON emission tomography computed tomography, RETROSPECTIVE studies, DESCRIPTIVE statistics, RADIOISOTOPE brachytherapy, SUPPORT vector machines, STATISTICS, DICOM (Computer network protocol), COMPARATIVE studies, MACHINE learning, DATA analysis software, CONFIDENCE intervals, OVERALL survival, ALGORITHMS

Abstract

Background: The role of artificial intelligence and radiomics in prediction model development in cancer has been increasing every passing day. Cervical cancer is the 4th most common cancer in women worldwide, contributing to 6.5% of all cancer types. The treatment outcome of cervical cancer patients varies and individualized prediction of disease outcome is of paramount importance. Purpose: The purpose of this study is to develop and validate the digital signature for 5-year overall survival prediction in cervical cancer using robust CT radiomic and clinical features. Materials and Methods: Pretreatment clinical features and CT radiomic features of 68 patients, who were treated with chemoradiation therapy in our hospital, were used in this study. Radiomic features were extracted using an in-house developed python script and pyradiomic package. Clinical features were selected by the recursive feature elimination technique. Whereas radiomic feature selection was performed using a multi-step process i.e., step-1: only robust radiomic features were selected based on our previous study, step-2: a hierarchical clustering was performed to eliminate feature redundancy, and step-3: recursive feature elimination was performed to select the best features for prediction model development. Four machine algorithms i.e., Logistic regression (LR), Random Forest (RF), Support vector classifier (SVC), and Gradient boosting classifier (GBC), were used to develop 24 models (six models using each algorithm) using clinical, radiomic and combined features. Models were compared based on the prediction score in the internal validation. Results: The average prediction accuracy was found to be 0.65 (95% CI: 0.60– 0.70), 0.72 (95% CI: 0.63–0.81), and 0.77 (95% CI: 0.72–0.82) for clinical, radiomic, and combined models developed using four prediction algorithms respectively. The average prediction accuracy was found to be 0.69 (95% CI: 0.62–0.76), 0.79 (95% CI: 0.72–0.86), 0.71 (95% CI: 0.62–0.80), and 0.72 (95% CI: 0.66–0.78) for LR, RF, SVC and GBC models developed on three datasets respectively. Conclusion: Our study shows the promising predictive performance of a robust radiomic signature to predict 5-year overall survival in cervical cancer patients. [ABSTRACT FROM AUTHOR]

Published

2024

22. Appropriateness and imaging outcomes of ultrasound, CT, and MR in the emergency department: a retrospective analysis from an urban academic center.

Author

Francisco, Martina Zaguini, Altmayer, Stephan, Carlesso, Lucas, Zanon, Matheus, Eymael, Thales, Lima, Jose Eduardo, Watte, Guilherme, and Hochhegger, Bruno

Subjects

*ULTRASONIC imaging, *HOSPITAL emergency services, *RETROSPECTIVE studies, *DIAGNOSTIC imaging, *MAGNETIC resonance, *DICOM (Computer network protocol), *IMPOTENCE

Abstract

Purpose: To evaluate the appropriateness and outcomes of ultrasound (US), computed tomography (CT), and magnetic resonance (MR) orders in the ED. Methods: We retrospectively reviewed consecutive US, CT, and MR orders for adult ED patients at a tertiary care urban academic center from January to March 2019. The American College of Radiology Appropriateness Criteria (ACRAC) guidelines were primarily used to classify imaging orders as "appropriate" or "inappropriate". Two radiologists in consensus judged specific clinical scenarios that were unavailable in the ACRAC. Final imaging reports were compared with the initial clinical suspicion for imaging and categorized into "normal", "compatible with initial diagnosis", "alternative diagnosis", or "inconclusive". The sample was powered to show a prevalence of inappropriate orders of 30% with a margin of error of 5%. Results: The rate of inappropriate orders was 59.4% for US, 29.1% for CT, and 33.3% for MR. The most commonly imaged systems for each modality were neuro (130/330) and gastrointestinal (95/330) for CT, genitourinary (132/330) and gastrointestinal (121/330) for US, neuro (273/330) and gastrointestinal (37/330) for MR. Compared to inappropriately ordered tests, the final reports of appropriate orders were nearly three times more likely to demonstrate findings compatible with the initial diagnosis for all modalities: US (45.5 vs. 14.3%, p < 0.001), CT (46.6 vs. 14.6%, p < 0.001), and MR (56.3 vs. 21.8%, p < 0.001). Inappropriate orders were more likely to show no abnormalities compared to appropriate orders: US (65.8 vs. 38.8%, p < 0.001), CT (62.5 vs. 34.2%, p < 0.001), and MR (61.8 vs. 38.7%, p < 0.001). Conclusion: The prevalence of inappropriate imaging orders in the ED was 59.4% for US, 29.1% for CT, and 33.3% for MR. Appropriately ordered imaging was three times more likely to yield findings compatible with the initial diagnosis across all modalities. [ABSTRACT FROM AUTHOR]

Published

2024

23. CT-derived pectoralis composition and incident pneumonia hospitalization using fully automated deep-learning algorithm: multi-ethnic study of atherosclerosis.

Author

Ibad, Hamza A., Hathaway, Quincy A., Bluemke, David A., Kasaeian, Arta, Klein, Joshua G., Budoff, Matthew J., Barr, R. Graham, Allison, Matthew, Post, Wendy S., Lima, João A. C., and Demehri, Shadpour

Subjects

*CONVOLUTIONAL neural networks, *PECTORALIS muscle, *CHRONIC obstructive pulmonary disease, *PNEUMONIA, *PROPORTIONAL hazards models, *DICOM (Computer network protocol)

Abstract

Background: Pneumonia-related hospitalization may be associated with advanced skeletal muscle loss due to aging (i.e., sarcopenia) or chronic illnesses (i.e., cachexia). Early detection of muscle loss may now be feasible using deep-learning algorithms applied on conventional chest CT. Objectives: To implement a fully automated deep-learning algorithm for pectoralis muscle measures from conventional chest CT and investigate longitudinal associations between these measures and incident pneumonia hospitalization according to Chronic Obstructive Pulmonary Disease (COPD) status. Materials and methods: This analysis from the Multi-Ethnic Study of Atherosclerosis included participants with available chest CT examinations between 2010 and 2012. We implemented pectoralis muscle composition measures from a fully automated deep-learning algorithm (Mask R-CNN, built on the Faster Region Proposal Network (R-) Convolutional Neural Network (CNN) with an extension for mask identification) for two-dimensional segmentation. Associations between CT-derived measures and incident pneumonia hospitalizations were evaluated using Cox proportional hazards models adjusted for multiple confounders which include but are not limited to age, sex, race, smoking, BMI, physical activity, and forced-expiratory-volume-at-1 s-to-functional-vital-capacity ratio. Stratification analyses were conducted based on baseline COPD status. Results: This study included 2595 participants (51% female; median age: 68 (IQR: 61, 76)) CT examinations for whom we implemented deep learning–derived measures for longitudinal analyses. Eighty-six incident pneumonia hospitalizations occurred during a median 6.67-year follow-up. Overall, pectoralis muscle composition measures did not predict incident pneumonia. However, in fully-adjusted models, only among participants with COPD (N = 507), CT measures like extramyocellular fat index (hazard ratio: 1.98, 95% CI: 1.22, 3.21, p value: 0.02), were independently associated with incident pneumonia. Conclusion: Reliable deep learning–derived pectoralis muscle measures could predict incident pneumonia hospitalization only among participants with known COPD. Clinical relevance statement: Pectoralis muscle measures obtainable at zero additional cost or radiation exposure from any chest CT may have independent predictive value for clinical outcomes in chronic obstructive pulmonary disease patients. Key Points: •Identification of independent and modifiable risk factors of pneumonia can have important clinical impact on patients with chronic obstructive pulmonary disease. •Opportunistic CT measures of adipose tissue within pectoralis muscles using deep-learning algorithms can be quickly obtainable at zero additional cost or radiation exposure. •Deep learning–derived pectoralis muscle measurements of intermuscular fat and its subcomponents are independently associated with subsequent incident pneumonia hospitalization. [ABSTRACT FROM AUTHOR]

Published

2024

24. Apriori prediction of chemotherapy response in locally advanced breast cancer patients using CT imaging and deep learning: transformer versus transfer learning.

Author

Moslemi, Amir, Osapoetra, Laurentius Oscar, Dasgupta, Archya, Alberico, David, Trudeau, Maureen, Gandhi, Sonal, Eisen, Andrea, Wright, Frances, Look-Hong, Nicole, Curpen, Belinda, Kolios, Michael C., and Czarnota, Gregory J.

Subjects

CANCER patients, DEEP learning, TRANSFORMER models, COMPUTED tomography, METASTATIC breast cancer, DICOM (Computer network protocol), DEATH forecasting

Abstract

Objective: Neoadjuvant chemotherapy (NAC) is a key element of treatment for locally advanced breast cancer (LABC). Predicting the response to NAC for patients with Locally Advanced Breast Cancer (LABC) before treatment initiation could be beneficial to optimize therapy, ensuring the administration of effective treatments. The objective of the work here was to develop a predictive model to predict tumor response to NAC for LABC using deep learning networks and computed tomography (CT). Materials and methods: Several deep learning approaches were investigated including ViT transformer and VGG16, VGG19, ResNet-50, Res-Net-101, Res-Net-152, InceptionV3 and Xception transfer learning networks. These deep learning networks were applied on CT images to assess the response to NAC. Performance was evaluated based on balanced_accuracy, accuracy, sensitivity and specificity classification metrics. A ViT transformer was applied to utilize the attention mechanism in order to increase the weight of important part image which leads to better discrimination between classes. Results: Amongst the 117 LABC patients studied, 82 (70%) had clinical- pathological response and 35 (30%) had no response to NAC. The ViT transformer obtained the best performance range (accuracy = 71 ± 3% to accuracy = 77 ± 4%, specificity = 86 ± 6% to specificity = 76 ± 3%, sensitivity = 56 ± 4% to sensitivity = 52 ± 4%, and balanced_accuracy=69 ± 3% to balanced_accuracy=69 ± 3%) depending on the split ratio of train-data and test¬data. Xception network obtained the second best results (accuracy = 72 ± 4% to accuracy = 65 ± 4, specificity = 81 ± 6% to specificity = 73 ± 3%, sensitivity = 55 ± 4% to sensitivity = 52 ± 5%, and balanced_accuracy = 66 ± 5% to balanced_accuracy = 60 ± 4%). The worst results were obtained using VGG-16 transfer learning network. Conclusion: Deep learning networks in conjunction with CT imaging are able to predict the tumor response to NAC for patients with LABC prior to start. A ViT transformer could obtain the best performance, which demonstrated the importance of attention mechanism. [ABSTRACT FROM AUTHOR]

Published

2024

25. Deep Learning Classification of Usual Interstitial Pneumonia Predicts Outcomes.

Author

Humphries, Stephen M., Thieke, Devlin, Baraghoshi, David, Strand, Matthew J., Swigris, Jeffrey J., Chae, Kum Ju, Hwang, Hye Jeon, Oh, Andrea S., Flaherty, Kevin R., Adegunsoye, Ayodeji, Jablonski, Renea, Lee, Cathryn T., Husain, Aliya N., Chung, Jonathan H., Strek, Mary E., and Lynch, David A.

Subjects

IDIOPATHIC pulmonary fibrosis, DEEP learning, MACHINE learning, INTERSTITIAL lung diseases, PULMONARY fibrosis, RECEIVER operating characteristic curves, NONINVASIVE diagnostic tests, DICOM (Computer network protocol)

Abstract

Rationale: Computed tomography (CT) enables noninvasive diagnosis of usual interstitial pneumonia (UIP), but enhanced image analyses are needed to overcome the limitations of visual assessment. Objectives: Apply multiple instance learning (MIL) to develop an explainable deep learning algorithm for prediction of UIP from CT and validate its performance in independent cohorts. Methods: We trained an MIL algorithm using a pooled dataset (n = 2,143) and tested it in three independent populations: data from a prior publication (n = 127), a single-institution clinical cohort (n = 239), and a national registry of patients with pulmonary fibrosis (n = 979). We tested UIP classification performance using receiver operating characteristic analysis, with histologic UIP as ground truth. Cox proportional hazards and linear mixed-effects models were used to examine associations between MIL predictions and survival or longitudinal FVC. Measurements and Main Results: In two cohorts with biopsy data, MIL improved accuracy for histologic UIP (area under the curve, 0.77 [n = 127] and 0.79 [n = 239]) compared with visual assessment (area under the curve, 0.65 and 0.71). In cohorts with survival data, MIL-UIP classifications were significant for mortality (n = 239, mortality to April 2021: unadjusted hazard ratio, 3.1; 95% confidence interval [CI], 1.96–4.91; P < 0.001; and n = 979, mortality to July 2022: unadjusted hazard ratio, 3.64; 95% CI, 2.66–4.97; P < 0.001). Individuals classified as UIP positive by the algorithm had a significantly greater annual decline in FVC than those classified as UIP negative (−88 ml/yr vs. −45 ml/yr; n = 979; P < 0.01), adjusting for extent of lung fibrosis. Conclusions: Computerized assessment using MIL identifies clinically significant features of UIP on CT. Such a method could improve confidence in radiologic assessment of patients with interstitial lung disease, potentially enabling earlier and more precise diagnosis. [ABSTRACT FROM AUTHOR]

Published

2024

26. Deep learning-assisted diagnosis of large vessel occlusion in acute ischemic stroke based on four-dimensional computed tomography angiography.

Author

Yuling Peng, Jiayang Liu, Rui Yao, Jiajing Wu, Jing Li, Linquan Dai, Sirun Gu, Yunzhuo Yao, Yongmei Li, Shanxiong Chen, and Jingjie Wang

Subjects

ISCHEMIC stroke, COMPUTED tomography, ANGIOGRAPHY, ARTIFICIAL neural networks, DEEP learning, DICOM (Computer network protocol)

Abstract

Purpose: To develop deep learning models based on four-dimensional computed tomography angiography (4D-CTA) images for automatic detection of large vessel occlusion (LVO) in the anterior circulation that cause acute ischemic stroke. Methods: This retrospective study included 104 LVO patients and 105 non-LVO patients for deep learning models development. Another 30 LVO patients and 31 non-LVO patients formed the time-independent validation set. Four phases of 4D-CTA (arterial phase P1, arterial-venous phase P2, venous phase P3 and late venous phase P4) were arranged and combined and two input methods was used: combined input and superimposed input. Totally 26 models were constructed using a modified HRNet network. Assessment metrics included the areas under the curve (AUC), accuracy, sensitivity, specificity and F1 score. Kappa analysis was performed to assess inter-rater agreement between the best model and radiologists of different seniority. Results: The P1 + P2 model (combined input) had the best diagnostic performance. In the internal validation set, the AUC was 0.975 (95%CI: 0.878-0.999), accuracy was 0.911, sensitivity was 0.889, specificity was 0.944, and the F1 score was 0.909. In the time-independent validation set, the model demonstrated consistently high performance with an AUC of 0.942 (95%CI: 0.851-0.986), accuracy of 0.902, sensitivity of 0.867, specificity of 0.935, and an F1 score of 0.901. The best model showed strong consistency with the diagnostic efficacy of three radiologists of different seniority (k = 0.84, 0.80, 0.70, respectively). Conclusion: The deep learning model, using combined arterial and arterial-venous phase, was highly effective in detecting LVO, alerting radiologists to speed up the diagnosis. [ABSTRACT FROM AUTHOR]

Published

2024

27. Deep Learning Prediction of Axillary Lymph Node Metastasis in Breast Cancer Patients Using Clinical Implication-Applied Preprocessed CT Images.

Author

Park, Tae Yong, Kwon, Lyo Min, Hyeon, Jini, Cho, Bum-Joo, and Kim, Bum Jun

Subjects

*METASTATIC breast cancer, *DEEP learning, *LYMPHATIC metastasis, *COMPUTED tomography, *CONVOLUTIONAL neural networks, *DICOM (Computer network protocol), *DEATH forecasting

Abstract

Background: Accurate detection of axillary lymph node (ALN) metastases in breast cancer is crucial for clinical staging and treatment planning. This study aims to develop a deep learning model using clinical implication-applied preprocessed computed tomography (CT) images to enhance the prediction of ALN metastasis in breast cancer patients. Methods: A total of 1128 axial CT images of ALN (538 malignant and 590 benign lymph nodes) were collected from 523 breast cancer patients who underwent preoperative CT scans between January 2012 and July 2022 at Hallym University Medical Center. To develop an optimal deep learning model for distinguishing metastatic ALN from benign ALN, a CT image preprocessing protocol with clinical implications and two different cropping methods (fixed size crop [FSC] method and adjustable square crop [ASC] method) were employed. The images were analyzed using three different convolutional neural network (CNN) architectures (ResNet, DenseNet, and EfficientNet). Ensemble methods involving and combining the selection of the two best-performing CNN architectures from each cropping method were applied to generate the final result. Results: For the two different cropping methods, DenseNet consistently outperformed ResNet and EfficientNet. The area under the receiver operating characteristic curve (AUROC) for DenseNet, using the FSC and ASC methods, was 0.934 and 0.939, respectively. The ensemble model, which combines the performance of the DenseNet121 architecture for both cropping methods, delivered outstanding results with an AUROC of 0.968, an accuracy of 0.938, a sensitivity of 0.980, and a specificity of 0.903. Furthermore, distinct trends observed in gradient-weighted class activation mapping images with the two cropping methods suggest that our deep learning model not only evaluates the lymph node itself, but also distinguishes subtler changes in lymph node margin and adjacent soft tissue, which often elude human interpretation. Conclusions: This research demonstrates the promising performance of a deep learning model in accurately detecting malignant ALNs in breast cancer patients using CT images. The integration of clinical considerations into image processing and the utilization of ensemble methods further improved diagnostic precision. [ABSTRACT FROM AUTHOR]

Published

2024

28. Opportunistic Screening for Acute Vertebral Fractures on a Routine Abdominal or Chest Computed Tomography Scans Using an Automated Deep Learning Model.

Author

Kim, Ye Rin, Yoon, Yu Sung, and Cha, Jang Gyu

Subjects

*VERTEBRAL fractures, *MACHINE learning, *DEEP learning, *COMPUTED tomography, *DICOM (Computer network protocol)

Abstract

Objectives: To develop an opportunistic screening model based on a deep learning algorithm to detect recent vertebral fractures in abdominal or chest CTs. Materials and Methods: A total of 1309 coronal reformatted images (504 with a recent fracture from 119 patients, and 805 without fracture from 115 patients), from torso CTs, performed from September 2018 to April 2022, on patients who also had a spine MRI within two months, were included. Two readers participated in image selection and manually labeled the fractured segment on each selected image with Neuro-T (version 2.3.3; Neurocle Inc.) software. We split the images randomly into the training and internal test set (labeled: unlabeled = 480:700) and the secondary interval validation set (24:105). For the observer study, three radiologists reviewed the CT images in the external test set with and without deep learning assistance and scored the likelihood of an acute fracture in each image independently. Results: For the training and internal test sets, the AI achieved a 99.86% test accuracy, 91.22% precision, and 89.18% F1 score for detection of recent fracture. Then, in the secondary internal validation set, it achieved 99.90%, 74.93%, and 78.30%, respectively. In the observer study, with the assistance of the deep learning algorithm, a significant improvement was observed in the radiology resident's accuracy, from 92.79% to 98.2% (p = 0.04). Conclusion: The model showed a high level of accuracy in the test set and also the internal validation set. If this algorithm is applied opportunistically to daily torso CT evaluation, it will be helpful for the early detection of fractures that require treatment. [ABSTRACT FROM AUTHOR]

Published

2024

29. Low-dose liver CT: image quality and diagnostic accuracy of deep learning image reconstruction algorithm.

Author

Caruso, Damiano, De Santis, Domenico, Del Gaudio, Antonella, Guido, Gisella, Zerunian, Marta, Polici, Michela, Valanzuolo, Daniela, Pugliese, Dominga, Persechino, Raffaello, Cremona, Antonio, Barbato, Luca, Caloisi, Andrea, Iannicelli, Elsa, and Laghi, Andrea

Subjects

*IMAGE reconstruction algorithms, *DEEP learning, *IMAGE quality analysis, *COMPUTED tomography, *ELECTRICAL impedance tomography, *DIAGNOSTIC imaging, *DICOM (Computer network protocol)

Abstract

Objectives: To perform a comprehensive within-subject image quality analysis of abdominal CT examinations reconstructed with DLIR and to evaluate diagnostic accuracy compared to the routinely applied adaptive statistical iterative reconstruction (ASiR-V) algorithm. Materials and methods: Oncologic patients were prospectively enrolled and underwent contrast-enhanced CT. Images were reconstructed with DLIR with three intensity levels of reconstruction (high, medium, and low) and ASiR-V at strength levels from 10 to 100% with a 10% interval. Three radiologists characterized the lesions and two readers assessed diagnostic accuracy and calculated signal-to-noise ratio (SNR), contrast-to-noise ratio (CNR), figure of merit (FOM), and subjective image quality, the latter with a 5-point Likert scale. Results: Fifty patients (mean age: 70 ± 10 years, 23 men) were enrolled and 130 liver lesions (105 benign lesions, 25 metastases) were identified. DLIR_H achieved the highest SNR and CNR, comparable to ASiR-V 100% (p ≥.051). DLIR_M returned the highest subjective image quality (score: 5; IQR: 4–5; p ≤.001) and significant median increase (29%) in FOM (p <.001). Differences in detection were identified only for lesions ≤ 0.5 cm: 32/33 lesions were detected with DLIR_M and 26 lesions were detected with ASiR-V 50% (p =.031). Lesion accuracy of was 93.8% (95% CI: 88.1, 97.3; 122 of 130 lesions) for DLIR and 87.7% (95% CI: 80.8, 92.8; 114 of 130 lesions) for ASiR-V 50%. Conclusions: DLIR yields superior image quality and provides higher diagnostic accuracy compared to ASiR-V in the assessment of hypovascular liver lesions, in particular for lesions ≤ 0.5 cm. Clinical relevance statement: Deep learning image reconstruction algorithm demonstrates higher diagnostic accuracy compared to iterative reconstruction in the identification of hypovascular liver lesions, especially for lesions ≤ 0.5 cm. Key Points: • Iterative reconstruction algorithm impacts image texture, with negative effects on diagnostic capabilities. • Medium-strength deep learning image reconstruction algorithm outperforms iterative reconstruction in the diagnostic accuracy of ≤ 0.5 cm hypovascular liver lesions (93.9% vs 78.8%), also granting higher objective and subjective image quality. • Deep learning image reconstruction algorithm can be safely implemented in routine abdominal CT protocols in place of iterative reconstruction. [ABSTRACT FROM AUTHOR]

Published

2024

30. Classification of Chest CT Lung Nodules Using Collaborative Deep Learning Model.

Author

Alshamrani, Khalaf and Alshamrani, Hassan A

Subjects

PULMONARY nodules, COMPUTED tomography, DEEP learning, LUNG cancer, COLLABORATIVE learning, DICOM (Computer network protocol)

Abstract

Background: Early detection of lung cancer through accurate diagnosis of malignant lung nodules using chest CT scans offers patients the highest chance of successful treatment and survival. Despite advancements in computer vision through deep learning algorithms, the detection of malignant nodules faces significant challenges due to insufficient training datasets. Methods: This study introduces a model based on collaborative deep learning (CDL) to differentiate between cancerous and non-cancerous nodules in chest CT scans with limited available data. The model dissects a nodule into its constituent parts using six characteristics, allowing it to learn detailed features of lung nodules. It utilizes a CDL submodel that incorporates six types of feature patches to fine-tune a network previously trained with ResNet-50. An adaptive weighting method learned through error backpropagation enhances the process of identifying lung nodules, incorporating these CDL submodels for improved accuracy. Results: The CDL model demonstrated a high level of performance in classifying lung nodules, achieving an accuracy of 93.24%. This represents a significant improvement over current state-of-the-art methods, indicating the effectiveness of the proposed approach. Conclusion: The findings suggest that the CDL model, with its unique structure and adaptive weighting method, offers a promising solution to the challenge of accurately detecting malignant lung nodules with limited data. This approach not only improves diagnostic accuracy but also contributes to the early detection and treatment of lung cancer, potentially saving lives. [ABSTRACT FROM AUTHOR]

Published

2024

31. Assessment of the correlation between supracrestal gingival tissue dimensions and other periodontal phenotypes components via the digital registration method: a cross‑sectional study in a Chinese population.

Author

Lin, Kaijin, Wang, Siyi, Xu, Xiaofeng, Yu, Lu, Pan, Rui, Zheng, Minqian, Yang, Jin, and Guo, Jianbin

Subjects

CROSS-sectional method, ACADEMIC medical centers, RESEARCH funding, GINGIVA, COMPUTED tomography, COSMETIC dentistry, DIGITAL diagnostic imaging, DENTAL crowns, DESCRIPTIVE statistics, DICOM (Computer network protocol), DATA analysis software, PHENOTYPES

Abstract

Background: Supracrestal gingival tissue dimensions (SGTDs) has been considered to be an essential element of periodontal phenotype (PP) components. This study aimed to explore the relationship between SGTDs and other PP components by digital superposition method that integrated cone beam computed tomography (CBCT) with intraoral scanning. Methods: This cross-sectional study was conducted at the Stomatology Hospital of Fujian Medical University. Participants were recruited based on the inclusion and exclusion criteria. The data obtained from the digital scanner (TRIOS 3, 3Shape, Denmark) and CBCT images were imported into the TRIOS software (Implant Studio, 3Shape, Denmark) for computing relevant parameters. The significant level was set at 0.05. Results: A total of 83 participants with 498 maxillary anterior teeth were finally included. The mean values of supracrestal gingival height (SGH) and the distance from the cementoenamel junction (CEJ) to the crest of the alveolar ridge (CEJ-ABC) on the buccal site were significantly higher than palatal SGH (SGH-p) and palatal CEJ-ABC (CEJ-ABC-p). Men exhibited taller CEJ-ABC and SGH-p than women. Additionally, tooth type was significantly associated with the SGH, SGH-p and CEJ-ABC-p. Taller SGH was associated with wider crown, smaller papilla height (PH), flatter gingival margin, thicker bone thickness (BT) and gingival thickness (GT) at CEJ, the alveolar bone crest (ABC), and 2 mm apical to the ABC. Smaller SGH-p displayed thicker BT and GT at CEJ, the ABC, and 2 and 4 mm apical to the ABC. Higher CEJ-ABC showed lower interproximal bone height, smaller PH, flatter gingival margin, thinner GT and BT at CEJ, and 2 mm apical to the ABC. Smaller CEJ-ABC-p displayed thicker BT at CEJ and 2 and 4 mm apical to the ABC. On the buccal, thicker GT was correlated with thicker BT at 2 and 4 mm below the ABC. Conclusion: SGTDs exhibited a correlation with other PP components, especially crown shape, gingival margin and interdental PH. The relationship between SGTDs and gingival and bone phenotypes depended on the apico-coronal level evaluated. Trial registration: This study was approved by the Biomedical Research Ethics Committee of Stomatology Hospital of Fujian Medical University (approval no. 2023-24). [ABSTRACT FROM AUTHOR]

Published

2024

32. Measuring Up.

Author

Barnett, Chris

Subjects

MEDICAL information storage & retrieval systems, AUTOMATIC speech recognition, LABOR productivity, HOSPITAL radiological services, ULTRASONIC imaging, WORK design, WORKFLOW, MEDICAL radiology, DICOM (Computer network protocol), AUTOMATION, MERGERS & acquisitions, USER interfaces, EMPLOYEES' workload

Published

2024

33. Simultaneous Assessment of Soft and Hard Tissue Behaviors After Alveolar Ridge Preservation Using Bone Substitutes.

Author

Romito, Giuseppe Alexandre, Marques Sapata, Vítor, Batista Cesar Neto, João, Llanos, Alexandre Hugo, Jung, Ronald Ernst, and Mendes Pannuti, Claudio

Subjects

SOFT tissue injuries, ALVEOLAR process surgery, BONE substitutes, BONE resorption, PERIODONTITIS, DICOM (Computer network protocol), COMPUTED tomography, THREE-dimensional printing

Abstract

This study aimed to simultaneously assess hard and soft tissues alterations and their proportions after alveolar ridge preservation (ARP). Participants (n = 65) who were previously enrolled in a clinical trial investigating ARP healing were selected. The CBCT DICOM (Digital Imaging and Communications in Medicine) and the cast STL (stereolithographic) files of each subject were imported, segmented, and superimposed. A cross-section view of the superimposed image presented the outlines from each DICOM and STL file. The center of preserved ridge was selected in the superimposed image and used to draw the reference lines to realize the measurements. Horizontal linear measurements determined ridge width (RW) and its respective hard/soft tissue proportion (H:S) at 1, 3, 5, and 7 mm below the buccal bone crest immediately after ARP and at the 4-month follow-up. At 1 mm, the baseline RW was 11.6 mm and reduced to 10 mm after 4 months. The baseline H:S was 65%:35% and was 43%:57% at the 4-month follow-up. Considering only the buccal half of the ridge, baseline H:S was 77%:23%, while after 4 months it shifted to 58%:42%. A similar pattern was observed at 3, 5, and 7 mm but with decreased resorption degree. The present study showed that hard tissue is mostly responsible for RW loss after healing, especially in the first 3 mm below the buccal bone crest. Soft tissue partially compensated for the hard tissue shrinkage, gaining thickness in the analyzed areas. [ABSTRACT FROM AUTHOR]

Published

2022

34. A New Deep Learning Algorithm for Detecting Spinal Metastases on Computed Tomography Images.

Author

Masataka Motohashi, Yuki Funauchi, Takuya Adachi, Tomoyuki Fujioka, Naoya Otaka, Yuka Kamiko, Takashi Okada, Ukihide Tateishi, Atsushi Okawa, Toshitaka Yoshii, and Shingo Sato

Subjects

*MACHINE learning, *COMPUTED tomography, *DEEP learning, *COMPUTER-aided diagnosis, *BONE metastasis, *DICOM (Computer network protocol), *WHEELCHAIR sports

Abstract

Study Design. Retrospective diagnostic study. Objective. To automatically detect osteolytic bone metastasis lesions in the thoracolumbar region using conventional computed tomography (CT) scans, we developed a new deep learning (DL)-based computer-aided detection model. Summary of background data. Radiographic detection of bone metastasis is often difficult, even for orthopedic surgeons and diagnostic radiologists, with a consequent risk for pathologic fracture or spinal cord injury. If we can improve detection rates, we will be able to prevent the deterioration of patients' quality of life at the end stage of cancer. Materials and Methods. This study included CT scans acquired at Tokyo Medical and Dental University (TMDU) Hospital between 2016 and 2022. A total of 263 positive CT scans that included at least one osteolytic bone metastasis lesion in the thoracolumbar spine and 172 negative CT scans without bone metastasis were collected for the datasets to train and validate the DL algorithm. As a test data set, 20 positive and 20 negative CT scans were separately collected from the training and validation datasets. To evaluate the performance of the established artificial intelligence (AI) model, sensitivity, precision, F1-score, and specificity were calculated. The clinical utility of our AI model was also evaluated through observer studies involving six orthopaedic surgeons and six radiologists. Results. Our AI model showed a sensitivity, precision, and F1-score of 0.78, 0.68, and 0.72 (per slice) and 0.75, 0.36, and 0.48 (per lesion), respectively. The observer studies revealed that our AI model had comparable sensitivity to orthopaedic or radiology experts and improved the sensitivity and F1-score of residents. Conclusion. We developed a novel DL-based AI model for detecting osteolytic bone metastases in the thoracolumbar spine. Although further improvement in accuracy is needed, the current AI model may be applied to current clinical practice. [ABSTRACT FROM AUTHOR]

Published

2024

35. Image quality and metal artifact reduction in total hip arthroplasty CT: deep learning-based algorithm versus virtual monoenergetic imaging and orthopedic metal artifact reduction.

Author

Selles, Mark, Wellenberg, Ruud H. H., Slotman, Derk J., Nijholt, Ingrid M., van Osch, Jochen A. C., van Dijke, Kees F., Maas, Mario, and Boomsma, Martijn F.

Subjects

TOTAL hip replacement, WILCOXON signed-rank test, DICOM (Computer network protocol), COMPUTED tomography, METALS, SIMULATED patients, ACETABULUM (Anatomy), PELVIC bones

Abstract

Background: To compare image quality, metal artifacts, and diagnostic confidence of conventional computed tomography (CT) images of unilateral total hip arthroplasty patients (THA) with deep learning-based metal artifact reduction (DL-MAR) to conventional CT and 130-keV monoenergetic images with and without orthopedic metal artifact reduction (O-MAR). Methods: Conventional CT and 130-keV monoenergetic images with and without O-MAR and DL-MAR images of 28 unilateral THA patients were reconstructed. Image quality, metal artifacts, and diagnostic confidence in bone, pelvic organs, and soft tissue adjacent to the prosthesis were jointly scored by two experienced musculoskeletal radiologists. Contrast-to-noise ratios (CNR) between bladder and fat and muscle and fat were measured. Wilcoxon signed-rank tests with Holm-Bonferroni correction were used. Results: Significantly higher image quality, higher diagnostic confidence, and less severe metal artifacts were observed on DL-MAR and images with O-MAR compared to images without O-MAR (p < 0.001 for all comparisons). Higher image quality, higher diagnostic confidence for bone and soft tissue adjacent to the prosthesis, and less severe metal artifacts were observed on DL-MAR when compared to conventional images and 130-keV monoenergetic images with O-MAR (p ≤ 0.014). CNRs were higher for DL-MAR and images with O-MAR compared to images without O-MAR (p < 0.001). Higher CNRs were observed on DL-MAR images compared to conventional images and 130-keV monoenergetic images with O-MAR (p ≤ 0.010). Conclusions: DL-MAR showed higher image quality, diagnostic confidence, and superior metal artifact reduction compared to conventional CT images and 130-keV monoenergetic images with and without O-MAR in unilateral THA patients. Relevance statement: DL-MAR resulted into improved image quality, stronger reduction of metal artifacts, and improved diagnostic confidence compared to conventional and virtual monoenergetic images with and without metal artifact reduction, bringing DL-based metal artifact reduction closer to clinical application. Key points: • Metal artifacts introduced by total hip arthroplasty hamper radiologic assessment on CT. • A deep-learning algorithm (DL-MAR) was compared to dual-layer CT images with O-MAR. • DL-MAR showed best image quality and diagnostic confidence. • Highest contrast-to-noise ratios were observed on the DL-MAR images. [ABSTRACT FROM AUTHOR]

Published

2024

36. "sCT-Feasibility" - a feasibility study for deep learning-based MRI-only brain radiotherapy.

Author

Grigo, Johanna, Szkitsak, Juliane, Höfler, Daniel, Fietkau, Rainer, Putz, Florian, and Bert, Christoph

Subjects

*MAGNETIC resonance imaging, *RADIOTHERAPY, *DICOM (Computer network protocol), *RADIATION doses, *LINEAR accelerators, *FEASIBILITY studies

Abstract

Background: Radiotherapy (RT) is an important treatment modality for patients with brain malignancies. Traditionally, computed tomography (CT) images are used for RT treatment planning whereas magnetic resonance imaging (MRI) images are used for tumor delineation. Therefore, MRI and CT need to be registered, which is an error prone process. The purpose of this clinical study is to investigate the clinical feasibility of a deep learning-based MRI-only workflow for brain radiotherapy, that eliminates the registration uncertainty through calculation of a synthetic CT (sCT) from MRI data. Methods: A total of 54 patients with an indication for radiation treatment of the brain and stereotactic mask immobilization will be recruited. All study patients will receive standard therapy and imaging including both CT and MRI. All patients will receive dedicated RT-MRI scans in treatment position. An sCT will be reconstructed from an acquired MRI DIXON-sequence using a commercially available deep learning solution on which subsequent radiotherapy planning will be performed. Through multiple quality assurance (QA) measures and reviews during the course of the study, the feasibility of an MRI-only workflow and comparative parameters between sCT and standard CT workflow will be investigated holistically. These QA measures include feasibility and quality of image guidance (IGRT) at the linear accelerator using sCT derived digitally reconstructed radiographs in addition to potential dosimetric deviations between the CT and sCT plan. The aim of this clinical study is to establish a brain MRI-only workflow as well as to identify risks and QA mechanisms to ensure a safe integration of deep learning-based sCT into radiotherapy planning and delivery. Discussion: Compared to CT, MRI offers a superior soft tissue contrast without additional radiation dose to the patients. However, up to now, even though the dosimetrical equivalence of CT and sCT has been shown in several retrospective studies, MRI-only workflows have still not been widely adopted. The present study aims to determine feasibility and safety of deep learning-based MRI-only radiotherapy in a holistic manner incorporating the whole radiotherapy workflow. Trial registration: NCT06106997. [ABSTRACT FROM AUTHOR]

Published

2024

37. Open RT Structures: A Solution for TG-263 Accessibility.

Author

Anderson, Brian M., Padilla, Laura, Ryckman, Jeffrey M., Covington, Elizabeth, Hong, David S., Woods, Kaley, Katz, Matthew S., Zuhour, Raed, Estes, Chris, Moore, Kevin L., and Bojechko, Casey

Subjects

*MEDICAL communication, *DICOM (Computer network protocol), *ESOPHAGOGASTRIC junction, *LOW dose rate brachytherapy, *ONLINE databases, *INFORMATION sharing, *ACCELERATED partial breast irradiation

Abstract

Consistency of nomenclature within radiation oncology is increasingly important as big data efforts and data sharing become more feasible. Automation of radiation oncology workflows depends on standardized contour nomenclature that enables toxicity and outcomes research, while also reducing medical errors and facilitating quality improvement activities. Recommendations for standardized nomenclature have been published in the American Association of Physicists in Medicine (AAPM) report from Task Group 263 (TG-263). Transitioning to TG-263 requires creation and management of structure template libraries and retraining of staff, which can be a considerable burden on clinical resources. Our aim is to develop a program that allows users to create TG-263–compliant structure templates in English, Spanish, or French to facilitate data sharing. Fifty-three premade structure templates were arranged by treated organ based on an American Society for Radiation Oncology (ASTRO) consensus paper. Templates were further customized with common target structures, relevant organs at risk (OARs) (eg, spleen for anatomically relevant sites such as the gastroesophageal junction or stomach), subsite- specific templates (eg, partial breast, whole breast, intact prostate, postoperative prostate, etc) and brachytherapy templates. An informal consensus on OAR and target coloration was also achieved, although color selections are fully customizable within the program. The resulting program is usable on any Windows system and generates template files in practice-specific Digital Imaging and Communications In Medicine (DICOM) or XML formats, extracting standardized structure nomenclature from an online database maintained by members of the TG-263U1, which ensures continuous access to up-to-date templates. We have developed a tool to easily create and name DICOM radiation therapy (DICOM-RT) structures sets that are TG-263–compliant for all planning systems using the DICOM standard. The program and source code are publicly available via GitHub to encourage feedback from community users for improvement and guide further development. [ABSTRACT FROM AUTHOR]

Published

2024

38. Machine learning and deep learning enabled age estimation on medial clavicle CT images.

Author

Qiu, Lirong, Liu, Anjie, Dai, Xinhua, Liu, Guangfeng, Peng, Zhao, Zhan, Mengjun, Liu, Junhong, Gui, Yufan, Zhu, Haozhe, Chen, Hu, Deng, Zhenhua, and Fan, Fei

Subjects

*DEEP learning, *MACHINE learning, *CLAVICLE, *COMPUTED tomography, *SUPPORT vector machines, *DICOM (Computer network protocol)

Abstract

The medial clavicle epiphysis is a crucial indicator for bone age estimation (BAE) after hand maturation. This study aimed to develop machine learning (ML) and deep learning (DL) models for BAE based on medial clavicle CT images and evaluate the performance on normal and variant clavicles. This study retrospectively collected 1049 patients (mean± SD: 22.50±4.34 years) and split them into normal training and test sets, and variant training and test sets. An additional 53 variant clavicles were incorporated into the variant test set. The development stages of normal MCE were used to build a linear model and support vector machine (SVM) for BAE. The CT slices of MCE were automatically segmented and used to train DL models for automated BAE. Comparisons were performed by linear versus ML versus DL, and normal versus variant clavicles. Mean absolute error (MAE) and classification accuracy was the primary parameter of comparison. For BAE, the SVM had the best MAE of 1.73 years, followed by the commonly-used CNNs (1.77–1.93 years), the linear model (1.94 years), and the hybrid neural network CoAt Net (2.01 years). In DL models, SE Net 18 was the best-performing DL model with similar results to SVM in the normal test set and achieved an MAE of 2.08 years in the external variant test. For age classification, all the models exhibit superior performance in the classification of 18-, 20-, 21-, and 22-year thresholds with limited value in the 16-year threshold. Both ML and DL models produce desirable performance in BAE based on medial clavicle CT. [ABSTRACT FROM AUTHOR]

Published

2024

39. Deep learning reconstruction vs standard reconstruction for abdominal CT: the influence of BMI.

Author

Wang, Huixia, Yue, Songwei, Liu, Nana, Chen, Yan, Zhan, Pengchao, Liu, Xing, Shang, Bo, Wang, Luotong, Li, Zhen, Gao, Jianbo, and Lyu, Peijie

Subjects

*DEEP learning, *IMAGE reconstruction algorithms, *DICOM (Computer network protocol), *IMAGE reconstruction, *BODY mass index, *REAR-screen projection

Abstract

Objective: This study aimed to evaluate the image quality and lesion conspicuity of the deep learning image reconstruction (DLIR) algorithm compared with standard image reconstruction algorithms on abdominal enhanced computed tomography (CT) scanning with a wide range of body mass indexes (BMIs). Methods: A total of 112 participants who underwent contrast-enhanced abdominal CT scans were divided into three groups according to BMIs: the 80-kVp group (BMI ≤ 23.9 kg/m2), 100-kVp group (BMI 24–28.9 kg/m2), and 120-kVp group (BMI ≥ 29 kg/m2). All images were reconstructed using filtered back projection (FBP), adaptive statistical iterative reconstruction-V of 50% level (IR), and DLIR at low, medium, and high levels (DL, DM, and DH, respectively). Subjective noise, artifact, overall image quality, and low- and high-contrast hepatic lesion conspicuity were all graded on a 5-point scale. The CT attenuation value (in HU), image noise, and contrast-to-noise ratio (CNR) were quantified and compared. Results: DM and DH improved the qualitative and quantitative parameters compared with FBP and IR for all three BMI groups. DH had the lowest image noise and highest CNR value, while DM had the highest subjective overall image quality and low- and high-contrast lesion conspicuity scores for the three BMI groups. Based on the FBP, the improvement in image quality and lesion conspicuity of DM and DH images was greater in the 80-kVp group than in the 100-kVp and 120-kVp groups. Conclusion: For all BMIs, DLIR improves both image quality and hepatic lesion conspicuity, of which DM would be the best choice to balance both. Clinical relevance statement: The study suggests that utilizing DLIR, particularly at the medium level, can significantly enhance image quality and lesion visibility on abdominal CT scans across a wide range of BMIs. Key Points: • DLIR improved the image quality and lesion conspicuity across a wide range of BMIs. • DLIR at medium level had the highest subjective parameters and lesion conspicuity scores among all reconstruction levels. • On the basis of the FBP, the 80-kVp group had improved image quality and lesion conspicuity more than the 100-kVp and 120-kVp groups. [ABSTRACT FROM AUTHOR]

Published

2024

40. Improving radiomics reproducibility using deep learning-based image conversion of CT reconstruction algorithms in hepatocellular carcinoma patients.

Author

Lee, Heejin, Chang, Won, Kim, Hae Young, Sung, Pamela, Cho, Jungheum, Lee, Yoon Jin, and Kim, Young Hoon

Subjects

*RADIOMICS, *CONVOLUTIONAL neural networks, *HEPATOCELLULAR carcinoma, *COMPUTED tomography, *FEATURE extraction, *DICOM (Computer network protocol), *SIGNAL convolution

Abstract

Objectives: CT reconstruction algorithms affect radiomics reproducibility. In this study, we evaluate the effect of deep learning–based image conversion on CT reconstruction algorithms. Methods: This study included 78 hepatocellular carcinoma (HCC) patients who underwent four-phase liver CTs comprising non-contrast, late arterial (LAP), portal venous (PVP), and delayed phase (DP), reconstructed using both filtered back projection (FBP) and advanced modeled iterative reconstruction (ADMIRE). PVP images were used to train a convolutional neural network (CNN) model to convert images from FBP to ADMIRE and vice versa. LAP, PVP, and DP images were used for validation and testing. Radiomic features were extracted for each patient with a semi-automatic segmentation tool. We used concordance correlation coefficients (CCCs) to evaluate the radiomics reproducibility for original FBP (oFBP) vs. original ADMIRE (oADMIRE), oFBP vs. converted FBP (cFBP), and oADMIRE vs. converted ADMIRE (cADMIRE). Results: In the test group including 30 patients, the CCC and proportion of reproducible features (CCC ≥ 0.85) for oFBP vs. oADMIRE were 0.65 and 32.9% (524/1595) for LAP, 0.65 and 35.9% (573/1595) for PVP, and 0.69 and 43.8% (699/1595) for DP. For oFBP vs. cFBP, the values increased to 0.92 and 83.9% (1339/1595) for LAP, 0.89 and 71.0% (1133/1595) for PVP, and 0.90 and 79.7% (1271/1595) for DP. Similarly, for oADMIRE vs. cADMIRE, the values increased to 0.87 and 68.1% (1086/1595) for LAP, 0.91 and 82.1% (1309/1595) for PVP, and 0.89 and 76.2% (1216/1595) for DP. Conclusions: CNN-based image conversion between CT reconstruction algorithms improved the radiomics reproducibility of HCCs. Clinical relevance statement: This study demonstrates that using a CNN-based image conversion technique significantly improves the reproducibility of radiomic features in HCCs, highlighting its potential for enhancing radiomics research in HCC patients. Key Points: Radiomics reproducibility of HCC was improved via CNN-based image conversion between two different CT reconstruction algorithms. This is the first clinical study to demonstrate improvements across a range of radiomic features in HCC patients. This study promotes the reproducibility and generalizability of different CT reconstruction algorithms in radiomics research. [ABSTRACT FROM AUTHOR]

Published

2024

41. Deep learning-enabled detection of hypoxic–ischemic encephalopathy after cardiac arrest in CT scans: a comparative study of 2D and 3D approaches.

Author

Molinski, Noah S., Kenda, Martin, Leithner, Christoph, Nee, Jens, Storm, Christian, Scheel, Michael, and Meddeb, Aymen

Subjects

CEREBRAL anoxia-ischemia, COMPUTED tomography, CARDIAC arrest, DEEP learning, THREE-dimensional imaging, SIGNAL convolution, DICOM (Computer network protocol)

Abstract

Objective: To establish a deep learning model for the detection of hypoxic– ischemic encephalopathy (HIE) features on CT scans and to compare various networks to determine the best input data format. Methods: 168 head CT scans of patients after cardiac arrest were retrospectively identified and classified into two categories: 88 (52.4%) with radiological evidence of severe HIE and 80 (47.6%) without signs of HIE. These images were randomly divided into a training and a test set, and five deep learning models based on based on Densely Connected Convolutional Networks (DenseNet121) were trained and validated using different image input formats (2D and 3D images). Results: All optimized stacked 2D and 3D networks could detect signs of HIE. The networks based on the data as 2D image data stacks provided the best results (S100: AUC: 94%, ACC: 79%, S50: AUC: 93%, ACC: 79%). We provide visual explainability data for the decision making of our AI model using Gradient weighted Class Activation Mapping. Conclusion: Our proof-of-concept deep learning model can accurately identify signs of HIE on CT images. Comparing different 2D- and 3D-based approaches, most promising results were achieved by 2D image stack models. After further clinical validation, a deep learning model of HIE detection based on CT images could be implemented in clinical routine and thus aid clinicians in characterizing imaging data and predicting outcome. [ABSTRACT FROM AUTHOR]

Published

2024

42. An Innovative and Efficient Diagnostic Prediction Flow for Head and Neck Cancer: A Deep Learning Approach for Multi-Modal Survival Analysis Prediction Based on Text and Multi-Center PET/CT Images.

Author

Wang, Zhaonian, Zheng, Chundan, Han, Xu, Chen, Wufan, and Lu, Lijun

Subjects

*HEAD & neck cancer, *SURVIVAL analysis (Biometry), *COMPUTED tomography, *DEEP learning, *DICOM (Computer network protocol), *IMAGE fusion

Abstract

Objective: To comprehensively capture intra-tumor heterogeneity in head and neck cancer (HNC) and maximize the use of valid information collected in the clinical field, we propose a novel multi-modal image–text fusion strategy aimed at improving prognosis. Method: We have developed a tailored diagnostic algorithm for HNC, leveraging a deep learning-based model that integrates both image and clinical text information. For the image fusion part, we used the cross-attention mechanism to fuse the image information between PET and CT, and for the fusion of text and image, we used the Q-former architecture to fuse the text and image information. We also improved the traditional prognostic model by introducing time as a variable in the construction of the model, and finally obtained the corresponding prognostic results. Result: We assessed the efficacy of our methodology through the compilation of a multicenter dataset, achieving commendable outcomes in multicenter validations. Notably, our results for metastasis-free survival (MFS), recurrence-free survival (RFS), overall survival (OS), and progression-free survival (PFS) were as follows: 0.796, 0.626, 0.641, and 0.691. Our results demonstrate a notable superiority over the utilization of CT and PET independently, and exceed the result derived without the clinical textual information. Conclusions: Our model not only validates the effectiveness of multi-modal fusion in aiding diagnosis, but also provides insights for optimizing survival analysis. The study underscores the potential of our approach in enhancing prognosis and contributing to the advancement of personalized medicine in HNC. [ABSTRACT FROM AUTHOR]

Published

2024

43. Synergizing photon-counting CT with deep learning: potential enhancements in medical imaging.

Author

Mese, Ismail, Altintas Taslicay, Ceylan, and Sivrioglu, Ali Kemal

Subjects

*COMPUTER-assisted image analysis (Medicine), *DEEP learning, *MACHINE learning, *DIAGNOSTIC imaging, *IMAGE intensifiers, *DICOM (Computer network protocol)

Abstract

This review article highlights the potential of integrating photon-counting computed tomography (CT) and deep learning algorithms in medical imaging to enhance diagnostic accuracy, improve image quality, and reduce radiation exposure. The use of photon-counting CT provides superior image quality, reduced radiation dose, and material decomposition capabilities, while deep learning algorithms excel in automating image analysis and improving diagnostic accuracy. The integration of these technologies can lead to enhanced material decomposition and classification, spectral image analysis, predictive modeling for individualized medicine, workflow optimization, and radiation dose management. However, data requirements, computational resources, and regulatory and ethical concerns remain challenges that need to be addressed to fully realize the potential of this technology. The fusion of photon-counting CT and deep learning algorithms is poised to revolutionize medical imaging and transform patient care. [ABSTRACT FROM AUTHOR]

Published

2024

44. Pulmonary MRI with ultra-short TE using single- and dual-echo methods: comparison of capability for quantitative differentiation of non- or minimally invasive adenocarcinomas from other lung cancers with that of standard-dose thin-section CT.

Author

Ohno, Yoshiharu, Yui, Masao, Yamamoto, Kaori, Ikedo, Masato, Oshima, Yuka, Hamabuchi, Nayu, Hanamatsu, Satomu, Nagata, Hiroyuki, Ueda, Takahiro, Ikeda, Hirotaka, Takenaka, Daisuke, Yoshikawa, Takeshi, Ozawa, Yoshiyuki, and Toyama, Hiroshi

Subjects

*LUNG cancer, *ECHO-planar imaging, *ADENOCARCINOMA, *RECEIVER operating characteristic curves, *MAGNETIC resonance imaging, *CANCER invasiveness, *DICOM (Computer network protocol)

Abstract

Objective: The purpose of this study was thus to compare capabilities for quantitative differentiation of non- and minimally invasive adenocarcinomas from other of pulmonary MRIs with ultra-short TE (UTE) obtained with single- and dual-echo techniques (UTE-MRISingle and UTE-MRIDual) and thin-section CT for stage IA lung cancer patients. Methods: Ninety pathologically diagnosed stage IA lung cancer patients who underwent thin-section standard-dose CT, UTE-MRISingle, and UTE-MRIDual, surgical treatment and pathological examinations were included in this retrospective study. The largest dimension (Dlong), solid portion (solid Dlong), and consolidation/tumor (C/T) ratio of each nodule were assessed. Two-tailed Student's t-tests were performed to compare all indexes obtained with each method between non- and minimally invasive adenocarcinomas and other lung cancers. Receiver operating characteristic (ROC)-based positive tests were performed to determine all feasible threshold values for distinguishing non- or minimally invasive adenocarcinoma (MIA) from other lung cancers. Sensitivity, specificity, and accuracy were then compared by means of McNemar's test. Results: Each index showed significant differences between the two groups (p < 0.0001). Specificities and accuracies of solid Dlong for UTE-MRIDual2nd echo and CTMediastinal were significantly higher than those of solid Dlong for UTE-MRISingle and UTE-MRIDual1st echo and all C/T ratios except CTMediastinal (p < 0.05). Moreover, the specificities and accuracies of solid Dlong and C/T ratio were significantly higher than those of Dlong for each method (p < 0.05). Conclusion: Pulmonary MRI with UTE is considered at least as valuable as thin-section CT for quantitative differentiation of non- and minimally invasive adenocarcinomas from other stage IA lung cancers. Clinical relevance statement: Pulmonary MRI with UTE's capability for quantitative differentiation of non- and minimally invasive adenocarcinomas from other lung cancers in stage IA lung cancer patients is equal or superior to that of thin-section CT. Key Points: • Correlations were excellent for pathologically examined nodules with the largest dimensions (Dlong) and a solid component (solid Dlong) for all indexes (0.95 ≤ r ≤ 0.99, p < 0.0001). • Pathologically examined Dlong and solid Dlong obtained with all methods showed significant differences between non- and minimally invasive adenocarcinomas and other lung cancers (p < 0.0001). • Solid tumor components are most accurately measured by UTE-MRIDual2nd echo and CTMediastinal, whereas the ground-glass component is imaged by UTE-MRIDual1st echo and CTlung with high accuracy. UTE-MRIDual predicts tumor invasiveness with 100% sensitivity and 87.5% specificity at a C/T threshold of 0.5. [ABSTRACT FROM AUTHOR]

Published

2024

45. Value of deep learning reconstruction of chest low-dose CT for image quality improvement and lung parenchyma assessment on lung window.

Author

Wang, Jinhua, Sui, Xin, Zhao, Ruijie, Du, Huayang, Wang, Jiaru, Wang, Yun, Qin, Ruiyao, Lu, Xiaoping, Ma, Zhuangfei, Xu, Yinghao, Jin, Zhengyu, Song, Lan, and Song, Wei

Subjects

*COMPUTED tomography, *DEEP learning, *LUNGS, *PULMONARY emphysema, *LUNG diseases, *DICOM (Computer network protocol)

Abstract

Objectives: To explore the performance of low-dose computed tomography (LDCT) with deep learning reconstruction (DLR) for the improvement of image quality and assessment of lung parenchyma. Methods: Sixty patients underwent chest regular-dose CT (RDCT) followed by LDCT during the same examination. RDCT images were reconstructed with hybrid iterative reconstruction (HIR) and LDCT images were reconstructed with HIR and DLR, both using lung algorithm. Radiation exposure was recorded. Image noise, signal-to-noise ratio, and subjective image quality of normal and abnormal CT features were evaluated and compared using the Kruskal–Wallis test with Bonferroni correction. Results: The effective radiation dose of LDCT was significantly lower than that of RDCT (0.29 ± 0.03 vs 2.05 ± 0.65 mSv, p < 0.001). The mean image noise ± standard deviation was 33.9 ± 4.7, 39.6 ± 4.3, and 31.1 ± 3.2 HU in RDCT, LDCT HIR-Strong, and LDCT DLR-Strong, respectively (p < 0.001). The overall image quality of LDCT DLR-Strong was significantly better than that of LDCT HIR-Strong (p < 0.001) and comparable to that of RDCT (p > 0.05). LDCT DLR-Strong was comparable to RDCT in evaluating solid nodules, increased attenuation, linear opacity, and airway lesions (all p > 0.05). The visualization of subsolid nodules and decreased attenuation was better with DLR than with HIR in LDCT but inferior to RDCT (all p < 0.05). Conclusion: LDCT DLR can effectively reduce image noise and improve image quality. LDCT DLR provides good performance for evaluating pulmonary lesions, except for subsolid nodules and decreased lung attenuation, compared to RDCT-HIR. Clinical relevance statement: The study prospectively evaluated the contribution of DLR applied to chest low-dose CT for image quality improvement and lung parenchyma assessment. DLR can be used to reduce radiation dose and keep image quality for several indications. Key Points: • DLR enables LDCT maintaining image quality even with very low radiation doses. • Chest LDCT with DLR can be used to evaluate lung parenchymal lesions except for subsolid nodules and decreased lung attenuation. • Diagnosis of pulmonary emphysema or subsolid nodules may require higher radiation doses. [ABSTRACT FROM AUTHOR]

Published

2024

46. Comparison of deep learning networks for fully automated head and neck tumor delineation on multi-centric PET/CT images.

Author

Wang, Yiling, Lombardo, Elia, Huang, Lili, Avanzo, Michele, Fanetti, Giuseppe, Franchin, Giovanni, Zschaeck, Sebastian, Weingärtner, Julian, Belka, Claus, Riboldi, Marco, Kurz, Christopher, and Landry, Guillaume

Subjects

*NECK tumors, *HEAD tumors, *COMPUTED tomography, *DEEP learning, *POSITRON emission tomography, *AUTOETHNOGRAPHY, *HEAD & neck cancer, *DICOM (Computer network protocol)

Abstract

Objectives: Deep learning-based auto-segmentation of head and neck cancer (HNC) tumors is expected to have better reproducibility than manual delineation. Positron emission tomography (PET) and computed tomography (CT) are commonly used in tumor segmentation. However, current methods still face challenges in handling whole-body scans where a manual selection of a bounding box may be required. Moreover, different institutions might still apply different guidelines for tumor delineation. This study aimed at exploring the auto-localization and segmentation of HNC tumors from entire PET/CT scans and investigating the transferability of trained baseline models to external real world cohorts. Methods: We employed 2D Retina Unet to find HNC tumors from whole-body PET/CT and utilized a regular Unet to segment the union of the tumor and involved lymph nodes. In comparison, 2D/3D Retina Unets were also implemented to localize and segment the same target in an end-to-end manner. The segmentation performance was evaluated via Dice similarity coefficient (DSC) and Hausdorff distance 95th percentile (HD95). Delineated PET/CT scans from the HECKTOR challenge were used to train the baseline models by 5-fold cross-validation. Another 271 delineated PET/CTs from three different institutions (MAASTRO, CRO, BERLIN) were used for external testing. Finally, facility-specific transfer learning was applied to investigate the improvement of segmentation performance against baseline models. Results: Encouraging localization results were observed, achieving a maximum omnidirectional tumor center difference lower than 6.8 cm for external testing. The three baseline models yielded similar averaged cross-validation (CV) results with a DSC in a range of 0.71–0.75, while the averaged CV HD95 was 8.6, 10.7 and 9.8 mm for the regular Unet, 2D and 3D Retina Unets, respectively. More than a 10% drop in DSC and a 40% increase in HD95 were observed if the baseline models were tested on the three external cohorts directly. After the facility-specific training, an improvement in external testing was observed for all models. The regular Unet had the best DSC (0.70) for the MAASTRO cohort, and the best HD95 (7.8 and 7.9 mm) in the MAASTRO and CRO cohorts. The 2D Retina Unet had the best DSC (0.76 and 0.67) for the CRO and BERLIN cohorts, and the best HD95 (12.4 mm) for the BERLIN cohort. Conclusion: The regular Unet outperformed the other two baseline models in CV and most external testing cohorts. Facility-specific transfer learning can potentially improve HNC segmentation performance for individual institutions, where the 2D Retina Unets could achieve comparable or even better results than the regular Unet. [ABSTRACT FROM AUTHOR]

Published

2024

47. Diagnostic value of chest computed tomography scan based on artificial intelligence and deep learning in children with lobar pneumonia and analysis of image features before and after treatment: A retrospective cohort study.

Author

Chen, L., Dong, S., Chen, Y., Tian, L., He, C., and Tao, S.

Subjects

*PNEUMOCOCCAL pneumonia, *IMAGE analysis, *ARTIFICIAL intelligence, *DEEP learning, *COMPUTED tomography, *DICOM (Computer network protocol), *SIGNAL convolution

Abstract

Background: A retrospective cohort study was conducted to analyze the diagnostic value and image features of chest computed tomography (CT) scan in children with lobar pneumonia (LP) before and after treatment. Materials and Methods: 172 children with lobar pneumonia treated from January 2016 to December 2021 were selected. The patients who underwent plain X-ray scan were divided into control group (n = 72) and the patients who underwent chest CT scan as study group (n = 100). The diagnostic value and image characteristics before and after treatment were compared between the two groups. Results: After treatment, the lesion area of the patient was absorbed in varying degrees, and the CT plain scan indicated that the solid shadow density decreased until it was completely absorbed. The sensitivity, specificity, accuracy, positive predictive value and negative predictive value of chest X-ray were 66.67%, 58.33%, 63.89%, 76.19% and 46.67% respectively; and chest CT scan were 82.98%, 67.92%, 75.00%, 69.64% and 81.82%. The sensitivity, specificity, accuracy, and negative predictive value of chest CT plain scan were higher, and the positive predictive value was lower compared to those of chest X-ray plain film. The results of ROC curve study indicated that the AUC of chest CT plain scan was 0.755 (95%CI=0.657 -0.852), and the AUC of chest X-ray film was 0.625 (95%CI= 0.489-0.744). Conclusion: Chest CT has high sensitivity and specificity in the diagnosis of LP in children, which can clearly demonstrate the imaging features of LP before and after treatment. [ABSTRACT FROM AUTHOR]

Published

2024

48. Validation of a Deep Learning Chest X-ray Interpretation Model: Integrating Large-Scale AI and Large Language Models for Comparative Analysis with ChatGPT.

Author

Lee, Kyu Hong, Lee, Ro Woon, and Kwon, Ye Eun

Subjects

*LANGUAGE models, *CHATGPT, *DEEP learning, *ARTIFICIAL intelligence, *DATABASES, *DICOM (Computer network protocol), *PICTURE archiving & communication systems

Abstract

This study evaluates the diagnostic accuracy and clinical utility of two artificial intelligence (AI) techniques: Kakao Brain Artificial Neural Network for Chest X-ray Reading (KARA-CXR), an assistive technology developed using large-scale AI and large language models (LLMs), and ChatGPT, a well-known LLM. The study was conducted to validate the performance of the two technologies in chest X-ray reading and explore their potential applications in the medical imaging diagnosis domain. The study methodology consisted of randomly selecting 2000 chest X-ray images from a single institution's patient database, and two radiologists evaluated the readings provided by KARA-CXR and ChatGPT. The study used five qualitative factors to evaluate the readings generated by each model: accuracy, false findings, location inaccuracies, count inaccuracies, and hallucinations. Statistical analysis showed that KARA-CXR achieved significantly higher diagnostic accuracy compared to ChatGPT. In the 'Acceptable' accuracy category, KARA-CXR was rated at 70.50% and 68.00% by two observers, while ChatGPT achieved 40.50% and 47.00%. Interobserver agreement was moderate for both systems, with KARA at 0.74 and GPT4 at 0.73. For 'False Findings', KARA-CXR scored 68.00% and 68.50%, while ChatGPT scored 37.00% for both observers, with high interobserver agreements of 0.96 for KARA and 0.97 for GPT4. In 'Location Inaccuracy' and 'Hallucinations', KARA-CXR outperformed ChatGPT with significant margins. KARA-CXR demonstrated a non-hallucination rate of 75%, which is significantly higher than ChatGPT's 38%. The interobserver agreement was high for KARA (0.91) and moderate to high for GPT4 (0.85) in the hallucination category. In conclusion, this study demonstrates the potential of AI and large-scale language models in medical imaging and diagnostics. It also shows that in the chest X-ray domain, KARA-CXR has relatively higher accuracy than ChatGPT. [ABSTRACT FROM AUTHOR]

Published

2024

49. Morphometric study of incisive canal and its anatomic variations in brazilian individuals.

Author

Aranha Neto, Idalisio Soares, Cruz, Wiler Henrique Souza, Ribeiro, Isabela de Castro, Oliveira Coutinho, Danielle Carvalho, Ladeira Vidigal, Bruno César, Carmelo, Juliana De Carvalho, Martins-Júnior, Paulo Antônio, Vespasiano Silva, Amaro Ilídio, Manzi, Flávio Ricardo, and Alves e Silva, Micena Roberta Miranda

Subjects

DICOM (Computer network protocol), COMPUTED tomography, BRAZILIANS, DATA visualization, DIAGNOSTIC imaging

Abstract

To conduct a morphometric evaluation of the incisive canal, adjacent structures, and their anatomic variations in Brazilian individuals. A retrospective study was conducted using a sample of 157 multislice computed tomography images of adult Brazilian individuals of both sexes (20–96 years). The exam was performed with the RadiAnt DICOM Viewer 4.0.1 (64-bit) software that uses the DICOM PACS standard for visualization of medical and dental images. The values for length and height of the canal, thickness of the palatine bone plate, and latero-lateral diameter of the incisive foramen were higher in men than in women (p < 0.05). The findings of this study demonstrated morphometric differences for the following parameters: latero-lateral diameter; width of canals at all levels measured; palatine bone plate height; canal length and palatine bone plate thickness in relation to the male and female sexes in the Brazilian population. [ABSTRACT FROM AUTHOR]

Published

2024

50. Influence of second premolar extractions on the volume of the oral cavity proper: a control comparative cone-beam computed tomography volumetric analysis study.

Author

Mladenovic, Miodrag, Freezer, Simon, Dreyer, Craig, and Meade, Maurice J.

Subjects

CONE beam computed tomography, VOLUMETRIC analysis, DENTAL extraction, BICUSPIDS, MEDICAL sciences, DENTAL arch, DICOM (Computer network protocol)

Abstract

The article informs about a study comparing pre- and post-treatment volumetric changes in the oral cavity proper (OCP) in orthodontic patients with and without second premolar extractions, analyzing influencing variables. Topics include the use of cone-beam computed tomography (CBCT) for three-dimensional assessment, statistical analyses revealing increased OCP volume in both extraction and nonextraction groups, and factors such as gender, age, and arch length changes affecting OCP volume.

Published

2024