Pydicom
Overview
Pydicom is a pure Python package for working with DICOM files, the standard format for medical imaging data. This skill provides guidance on reading, writing, and manipulating DICOM files, including working with pixel data, metadata, and various compression formats.
When to Use This Skill
Use this skill when working with:
- Medical imaging files (CT, MRI, X-ray, ultrasound, PET, etc.)
- DICOM datasets requiring metadata extraction or modification
- Pixel data extraction and image processing from medical scans
- DICOM anonymization for research or data sharing
- Converting DICOM files to standard image formats
- Compressed DICOM data requiring decompression
- DICOM sequences and structured reports
- Multi-slice volume reconstruction
- PACS (Picture Archiving and Communication System) integration
Installation
Install pydicom and common dependencies:
uv pip install pydicom
uv pip install pillow # For image format conversion
uv pip install numpy # For pixel array manipulation
uv pip install matplotlib # For visualization
For handling compressed DICOM files, additional packages may be needed:
uv pip install pylibjpeg pylibjpeg-libjpeg pylibjpeg-openjpeg # JPEG compression
uv pip install python-gdcm # Alternative compression handler
Core Workflows
Reading DICOM Files
Read a DICOM file using pydicom.dcmread():
import pydicom
# Read a DICOM file
ds = pydicom.dcmread('path/to/file.dcm')
# Access metadata
print(f"Patient Name: {ds.PatientName}")
print(f"Study Date: {ds.StudyDate}")
print(f"Modality: {ds.Modality}")
# Display all elements
print(ds)
Key points:
dcmread()returns aDatasetobject- Access data elements using attribute notation (e.g.,
ds.PatientName) or tag notation (e.g.,ds[0x0010, 0x0010]) - Use
ds.file_metato access file metadata like Transfer Syntax UID - Handle missing attributes with
getattr(ds, 'AttributeName', default_value)orhasattr(ds, 'AttributeName')
Working with Pixel Data
Extract and manipulate image data from DICOM files:
import pydicom
import numpy as np
import matplotlib.pyplot as plt
# Read DICOM file
ds = pydicom.dcmread('image.dcm')
# Get pixel array (requires numpy)
pixel_array = ds.pixel_array
# Image information
print(f"Shape: {pixel_array.shape}")
print(f"Data type: {pixel_array.dtype}")
print(f"Rows: {ds.Rows}, Columns: {ds.Columns}")
# Apply windowing for display (CT/MRI)
if hasattr(ds, 'WindowCenter') and hasattr(ds, 'WindowWidth'):
from pydicom.pixel_data_handlers.util import apply_voi_lut
windowed_image = apply_voi_lut(pixel_array, ds)
else:
windowed_image = pixel_array
# Display image
plt.imshow(windowed_image, cmap='gray')
plt.title(f"{ds.Modality} - {ds.StudyDescription}")
plt.axis('off')
plt.show()
Working with color images:
# RGB images have shape (rows, columns, 3)
if ds.PhotometricInterpretation == 'RGB':
rgb_image = ds.pixel_array
plt.imshow(rgb_image)
elif ds.PhotometricInterpretation == 'YBR_FULL':
from pydicom.pixel_data_handlers.util import convert_color_space
rgb_image = convert_color_space(ds.pixel_array, 'YBR_FULL', 'RGB')
plt.imshow(rgb_image)
Multi-frame images (videos/series):
# For multi-frame DICOM files
if hasattr(ds, 'NumberOfFrames') and ds.NumberOfFrames > 1:
frames = ds.pixel_array # Shape: (num_frames, rows, columns)
print(f"Number of frames: {frames.shape[0]}")
# Display specific frame
plt.imshow(frames[0], cmap='gray')
Converting DICOM to Image Formats
Use the provided dicom_to_image.py script or convert manually:
from PIL import Image
import pydicom
import numpy as np
ds = pydicom.dcmread('input.dcm')
pixel_array = ds.pixel_array
# Normalize to 0-255 range
if pixel_array.dtype != np.uint8:
pixel_array = ((pixel_array - pixel_array.min()) /
(pixel_array.max() - pixel_array.min()) * 255).astype(np.uint8)
# Save as PNG
image = Image.fromarray(pixel_array)
image.save('output.png')
Use the script: python scripts/dicom_to_image.py input.dcm output.png
Modifying Metadata
Modify DICOM data elements:
import pydicom
from datetime import datetime
ds = pydicom.dcmread('input.dcm')
# Modify existing elements
ds.PatientName = "Doe^John"
ds.StudyDate = datetime.now().strftime('%Y%m%d')
ds.StudyDescription = "Modified Study"
# Add new elements
ds.SeriesNumber = 1
ds.SeriesDescription = "New Series"
# Remove elements
if hasattr(ds, 'PatientComments'):
delattr(ds, 'PatientComments')
# Or using del
if 'PatientComments' in ds:
del ds.PatientComments
# Save modified file
ds.save_as('modified.dcm')
Anonymizing DICOM Files
Remove or replace patient identifiable information:
import pydicom
from datetime import datetime
ds = pydicom.dcmread('input.dcm')
# Tags commonly containing PHI (Protected Health Information)
tags_to_anonymize = [
'PatientName', 'PatientID', 'PatientBirthDate',
'PatientSex', 'PatientAge', 'PatientAddress',
'InstitutionName', 'InstitutionAddress',
'ReferringPhysicianName', 'PerformingPhysicianName',
'OperatorsName', 'StudyDescription', 'SeriesDescription',
]
# Remove or replace sensitive data
for tag in tags_to_anonymize:
if hasattr(ds, tag):
if tag in ['PatientName', 'PatientID']:
setattr(ds, tag, 'ANONYMOUS')
elif tag == 'PatientBirthDate':
setattr(ds, tag, '19000101')
else:
delattr(ds, tag)
# Update dates to maintain temporal relationships
if hasattr(ds, 'StudyDate'):
# Shift dates by a random offset
ds.StudyDate = '20000101'
# Keep pixel data intact
ds.save_as('anonymized.dcm')
Use the provided script: python scripts/anonymize_dicom.py input.dcm output.dcm
Writing DICOM Files
Create DICOM files from scratch:
import pydicom
from pydicom.dataset import Dataset, FileDataset
from datetime import datetime
import numpy as np
# Create file meta information
file_meta = Dataset()
file_meta.MediaStorageSOPClassUID = pydicom.uid.generate_uid()
file_meta.MediaStorageSOPInstanceUID = pydicom.uid.generate_uid()
file_meta.TransferSyntaxUID = pydicom.uid.ExplicitVRLittleEndian
# Create the FileDataset instance
ds = FileDataset('new_dicom.dcm', {}, file_meta=file_meta, preamble=b"\0" * 128)
# Add required DICOM elements
ds.PatientName = "Test^Patient"
ds.PatientID = "123456"
ds.Modality = "CT"
ds.StudyDate = datetime.now().strftime('%Y%m%d')
ds.StudyTime = datetime.now().strftime('%H%M%S')
ds.ContentDate = ds.StudyDate
ds.ContentTime = ds.StudyTime
# Add image-specific elements
ds.SamplesPerPixel = 1
ds.PhotometricInterpretation = "MONOCHROME2"
ds.Rows = 512
ds.Columns = 512
ds.BitsAllocated = 16
ds.BitsStored = 16
ds.HighBit = 15
ds.PixelRepresentation = 0
# Create pixel data
pixel_array = np.random.randint(0, 4096, (512, 512), dtype=np.uint16)
ds.PixelData = pixel_array.tobytes()
# Add required UIDs
ds.SOPClassUID = pydicom.uid.CTImageStorage
ds.SOPInstanceUID = file_meta.MediaStorageSOPInstanceUID
ds.SeriesInstanceUID = pydicom.uid.generate_uid()
ds.StudyInstanceUID = pydicom.uid.generate_uid()
# Save the file
ds.save_as('new_dicom.dcm')
Compression and Decompression
Handle compressed DICOM files:
import pydicom
# Read compressed DICOM file
ds = pydicom.dcmread('compressed.dcm')
# Check transfer syntax
print(f"Transfer Syntax: {ds.file_meta.TransferSyntaxUID}")
print(f"Transfer Syntax Name: {ds.file_meta.TransferSyntaxUID.name}")
# Decompress and save as uncompressed
ds.decompress()
ds.save_as('uncompressed.dcm', write_like_original=False)
# Or compress when saving (requires appropriate encoder)
ds_uncompressed = pydicom.dcmread('uncompressed.dcm')
ds_uncompressed.compress(pydicom.uid.JPEGBaseline8Bit)
ds_uncompressed.save_as('compressed_jpeg.dcm')
Common transfer syntaxes:
ExplicitVRLittleEndian- Uncomp