Radiomics guide – Patients

Patients

What is radiomics?

Radiomics is an innovative field in medicine that utilizes advanced computer algorithms to analyze medical images such as MRI scans. This analysis goes beyond what the human eye can see, extracting hundreds of quantitative features from these images to provide a detailed and comprehensive understanding of diseases such as breast cancer, using simple imaging techniques.

Here’s how it works:

  • Image acquisition
    The first step in the radiomics workflow is acquiring high-quality medical imaging. This could be an MRI scan, a CT scan, or a PET scan.
  • Tumor delineation
    The next step is to identify the tumor on these images, which can be done through an automated segmentation method or by an experienced radiologist.
  • Feature extraction
    Once the tumor has been identified, a comprehensive set of quantitative features is extracted from it, encompassing various aspects including tumor image intensity, texture, and shape.
  • Data analysis
    The extracted data is then analyzed using machine learning algorithms. This analysis can help doctors understand more about the disease and make better treatment plans.

Clinical Collection

Clinical data collection involves gathering detailed information about your health. It is like assembling a puzzle where each piece represents a different aspect of your well-being.


The data collected includes:

  • Medical history
    Details about your past illnesses, surgeries, medications, allergies, and family medical background.
  • Current health status
    Information about your current symptoms, physical condition, and any ongoing health issues.
  • Treatment records
    Records of treatments received, such as surgeries, chemotherapy, or radiation therapy.

 

Why is it crucial?

Personalized care

Doctors require a comprehensive understanding of your health to tailor treatments specifically for you. Since no two patients are exactly alike, grasping your unique health journey aids them in making informed decisions.

 

Risk assessment
Clinical data helps evaluate your risk factors for diseases like breast cancer. For instance, awareness of your family history of cancer can inform screening recommendations.

 

Treatment planning
In breast cancer, clinical data is essential. It allows physicans to:

  • Determine the cancer stage.
  • Select the most effective treatment options (surgery, radiation, chemotherapy, immunotherapy, etc.
  • Predict how your body might respond to different treatments.
  • Monitor your progress during and after treatment.

 

Radiomics and breast cancer care

When AI algorithms analyze breast MRI images, they benefit from understanding your medical history:

  • Improved accuracy
    Understanding your health background helps AI models interpret the images more accurately.
  • Treatment decision support
    AI assists doctors in deciding the best treatment plan based on your individual case.
  • Risk assessment
    Radiomics can predict the likelihood of tumor recurrence or response to specific therapies.
  • Personalization
    Tailoring treatments to your unique needs leads to better outcomes.

Ensuring your privacy: a vital commitment

Why is privacy important?

Your health information is deeply personal, encompassing details about your medical history, treatments, and current health status. Safeguarding this information is crucial for several reasons:

  • Confidentiality: You have the right to keep your health data private.
  • Trust: Trust between patients and healthcare providers is built on confidentiality.
  • Legal and ethical obligations: Healthcare professionals are bound by legal and ethical standards to protect patient privacy.

How is privacy maintained?

  • Secure systems: Health records are stored in secure electronic systems with restricted access.
  • Informed consent: Before participating in any study or treatment, you’ll be informed about how your data will be used and asked for consent.

Radiomics and privacy

Radiomics involves analyzing medical images using AI algorithms. These algorithms require access to your health data to provide accurate insights. However, strict privacy measures are in place:

  • Anonymization: Personal identifiers (like names) are removed from images and data.
  • Aggregated data: Radiomics research often utilizes aggregated data, ensuring individual privacy.
  • Ethics committees: Research involving patient data undergoes ethical review to protect privacy.

 

Medical Imagine Acquisition

Medical Image Acquisition is the process of capturing detailed pictures of the inside of your body, typically using advanced imaging technologies like MRI (Magnetic Resonance Imaging).

The Role of MRI in Radiomics:

MRI scans play a crucial role in radiomics. They provide high-resolution images that AI algorithms use to analyze and understand breast cancer better. These images act as detailed maps, revealing tumor characteristics that are often invisible to the naked eye.

How is the MRI scan done?

  1. Preparation: You will be asked to remove any metal objects.
  2. MRI machine: This large, tube-like machine houses a movable bed. You will lie down on the bed, which slides into the tube.
  3. During the scan: Stay still while the machine captures images. The process is painless but can be noisy.
  4. Duration: The scan usually takes between 30 and 60 minutes.
  5. Safety and comfort: MRI scans are safe and do not use any harmful radiation.

Image preparation for radiomics

When it comes to radiomics analysis, image preparation plays a vital role in ensuring accurate and meaningful results. Let’s delve into the steps involved in preparing MRI images for radiomics.

Understanding image preparation

After your MRI scans are taken, they’re not immediately ready for radiomics analysis. Image preparation is like fine-tuning a photograph to get the best possible clarity and detail. It involves several steps to ensure the images are clear, accurate, and usable for radiomics.

Quality Check:

The first step is to assess the quality of the MRI images. This involves checking for clarity, resolution, and any potential errors that might have occurred during the scanning process. High-quality images are essential for reliable radiomics analysis. Clear images provide better visibility of anatomical structures and abnormalities.

Standardization:

MRI scans can vary due to differences in machines, protocols, and acquisition settings. Standardizing these images is crucial. During standardization, adjustments are made to ensure that all images adhere to a common format. This consistency simplifies subsequent analysis by minimizing variations.

Correction Techniques:

Sometimes, MRI scans exhibit small distortions or artifacts. These imperfections can affect the accuracy of radiomics features. Special correction techniques are applied to rectify these issues. By doing so, the images more accurately represent the underlying tissue characteristics.

Enhancing Image Features:

Radiomics relies on extracting quantitative features from images. Enhancing relevant features is essential. For instance, highlighting the edges of tumors or other structures of interest improves the AI’s ability to detect and analyze these regions effectively.

Image processing

Image processing is a fascinating stage where sophisticated computer techniques transform MRI images, revealing intricate details that may not be immediately visible to the human eye. Let’s explore the key steps involved:

  1. Enhancing Image Details:
  • The initial step focuses on enhancing specific features within MRI images. For instance, edges are emphasized to make critical details—such as tumor boundaries—more distinct.
  • By enhancing these features, we improve the visibility of anatomical structures and abnormalities.
  1. Noise Reduction:
  • MRI scans often contain background “noise” that can blur essential details. Image processing aims to reduce this noise, resulting in a clearer picture.
  • Noise reduction enhances the overall quality of the images, making subsequent analysis more reliable.
  1. Normalization:
  • Standardizing images is crucial for accurate comparison and analysis. Different MRI machines and settings can lead to variations.
  • Normalization adjusts the images to a common scale, ensuring consistency and facilitating meaningful comparisons.
  1. Image Segmentation:
  • By isolating specific areas (such as tumors) from the surrounding breast tissue, segmentation enables precise analysis.

 

Why does image processing matter in radiomics?

  • Precision: Well-processed images yield more accurate radiomics features, which are essential for predictive models and personalized treatment planning.
  • Consistency: Standardized images ensure consistency across patients and time points, enhancing the reliability of analysis.
  • Clinical Impact: Accurate radiomics features contribute to better clinical decision-making, whether it’s tumor characterization, treatment response assessment, or prognosis prediction.

Feature extraction

Radiomics is like deciphering a complex puzzle. It involves extracting a multitude of quantitative features from medical images using specialized algorithms. These features provide valuable information about tissue structures, textures, and intensities that might not be immediately apparent to the naked eye. Let’s break down the process:

  1. Image acquisition and preprocessing:
  • The journey begins with acquiring high-quality medical images, such as MRI scans.
  • These images undergo preprocessing steps to enhance clarity and remove noise.
  1. Segmentation:
  • Next, we identify the region of interest (ROI) within the images. For breast cancer, this would be the tumor area.
  • Accurate segmentation ensures that we focus on relevant features.
  1. Feature extraction:
  • Here’s where the magic happens! Radiomics features are extracted from the segmented ROI.
  • These features fall into several categories:
    – Shape-based features: Describing the tumor’s geometric properties (e.g., size, volume)
  • Intensity-based features: Reflecting pixel or voxel intensities (brightness) within the tumor.
  • Texture-based features: Capturing patterns, coarseness, and heterogeneity (e.g., entropy, contrast).
  • Statistical measures: Summarizing data distribution (mean, variance, skewness).
  • These features are quantified—transformed into numerical values—for further analysis.
  1. Machine learning and patterns:
  • Radiomics features serve as clues for machine learning algorithms.
  • By analyzing patterns and relationships between features, we can predict clinical outcomes (for instance, we can estimate overall survival, treatment response, and risk stratification)

 

Radiomics isn’t just about numbers – it’s about personalized medicine:

  • Tumor heterogeneity: Radiomics reveals the diverse characteristics within a tumor, impacting its behavior and response to treatment.
  • Treatment tailoring: By integrating radiomics with clinical data, we can tailor treatments to individual patients.
  • Improved outcomes: Informed decisions lead to better patient outcomes and quality of life.

Jimenez-Pastor, A., Urbanos-García, G. (2023). How to Extract Radiomic Features from Imaging. In: Alberich-Bayarri, Á., Bellvís-Bataller, F. (eds) Basics of Image Processing. Imaging Informatics for Healthcare Professionals. Springer, Cham. https://doi.org/10.1007/978-3-031-48446-9_3

Thomas, H.M.T.; Wang, H.Y.C.; Varghese, A.J.; Donovan, E.M.; South, C.P.; Saxby, H.; Nisbet, A.; Prakash, V.; Sasidharan, B.K.; Pavamani, S.P.; et al. Reproducibility in Radiomics: A Comparison of Feature Extraction Methods and Two Independent Datasets. Appl. Sci. 2023, 13, 7291. https://doi.org/10.3390/app13127291

Vial, A., Stirling, D., Field, M., Ros, M., Ritz, C., Carolan, M., Holloway, L., & Miller, A. (2018). The role of deep learning and radiomic feature extraction in cancer-specific predictive modelling: a review. Translational Cancer Research, 7(3), 803-816. doi:10.21037/tcr.2018.05.02

Feature analysis and selection

Here’s a breakdown of feature analysis and selection in radiomics:

  1. Data analysis:
  • The initial step involves using advanced algorithms to analyze the vast array of data extracted from medical images.
  • During this analysis, the algorithms search for patterns, correlations, and trends within the data.
  1. Selecting key features:
  • Not all features within the data are equally important for understanding a specific condition (such as breast cancer).
  • Feature selection aims to identify the most relevant and significant features that provide valuable insights.
  • It’s like finding the most telling clues in a complex puzzle—focusing on what truly matters.

  1. Reducing complexity:
  • By concentrating on key features, the overall complexity of the data is reduced.
  • This reduction makes the data more manageable and focused.
  • Ultimately, it enhances the accuracy and efficiency of the radiomics analysis.

 

Importance of feature analysis and selection:

  • Feature analysis and selection are critical for ensuring that radiomics analyses are not only comprehensive but also relevant and precise.
  • They contribute to creating a more accurate and detailed picture of breast cancer.
  • Informed treatment decisions can be made based on these insights.

Model validation

Model validation is akin to a rigorous examination for the AI system. It serves as a critical step to verify that the model—essentially an AI algorithm—correctly analyzes and interprets the data extracted from MRI scans. The ultimate goal? Ensuring that the model’s predictions regarding breast cancer characteristics and treatment responses are reliable and accurate.

Here’s how model validation works:

  1. Testing with real-world data:
  • The model undergoes testing using a diverse set of real-world data, including various types of breast cancer cases.
  • This comprehensive testing ensures that the model can accurately analyze and make predictions across different scenarios.
  1. Comparing predictions with actual outcomes:
  • The predictions generated by the model are meticulously compared with actual patient outcomes.
  • If the model’s predictions align with real-world results, it signifies that the model is reliable and trustworthy.
  1. Continuous assessment:
  • Model validation is not a one-time event. Instead, it involves ongoing assessment.
  • The model is regularly updated with new data, ensuring its ongoing accuracy and relevance.

 

Importance of model validation:

  • Model validation is crucial because it establishes trust in the radiomics system.
  • It ensures that the treatment recommendations based on AI analysis are dependable and can be confidently utilized by your healthcare team.

Ensuring accuracy and reliability:

  • During model validation, a combination of statistical methods and expert evaluations is employed to verify the model’s accuracy.
  • This meticulous process ensures that the radiomics approach delivers tangible benefits in real-world clinical settings.

 

Performance Evaluation

  1. Evaluating accuracy: This step focuses on assessing how accurately the radiomics model predicts various aspects of breast cancer. For instance, it examines the model’s ability to predict tumor characteristics and patient response to treatment.
  2. Assessing reliability: Consistency and reliability are crucial. The model’s predictions should remain stable over time and across different patient cases. Ensuring reliability builds trust in its clinical application.
  3. Analyzing clinical usefulness: Beyond accuracy, we evaluate the model’s practical utility in a clinical setting. Does it genuinely assist healthcare professionals in making better treatment decisions? This assessment considers real-world impact.

 

Performance evaluation serves several critical purposes:

  • Quality assurance
    It ensures that the radiomics model meets the high standards required for medical use. Think of it as the final exam for the AI system.
  • Confidence building
    Healthcare professionals and patients need confidence in AI-driven approaches. Rigorous evaluation provides evidence of the model’s reliability and effectiveness.
  • Continuous improvement
    Continuous monitoring and updates are part of the cycle. As new data and medical advancements emerge, the model adapts, staying relevant and effect