Datasets:

Liu-Hy
/

GenoTEX

	# Path Configuration
	from tools.preprocess import *

	# Processing context
	trait = "Kidney_Chromophobe"
	cohort = "GSE40912"

	# Input paths
	in_trait_dir = "../DATA/GEO/Kidney_Chromophobe"
	in_cohort_dir = "../DATA/GEO/Kidney_Chromophobe/GSE40912"

	# Output paths
	out_data_file = "./output/preprocess/3/Kidney_Chromophobe/GSE40912.csv"
	out_gene_data_file = "./output/preprocess/3/Kidney_Chromophobe/gene_data/GSE40912.csv"
	out_clinical_data_file = "./output/preprocess/3/Kidney_Chromophobe/clinical_data/GSE40912.csv"
	json_path = "./output/preprocess/3/Kidney_Chromophobe/cohort_info.json"

	# Get file paths
	soft_file_path, matrix_file_path = geo_get_relevant_filepaths(in_cohort_dir)

	# Get background info and clinical data
	background_info, clinical_data = get_background_and_clinical_data(matrix_file_path)

	# Get unique values for each clinical feature
	unique_values_dict = get_unique_values_by_row(clinical_data)

	# Print background information
	print("Background Information:")
	print(background_info)
	print("\nSample Characteristics:")
	print(json.dumps(unique_values_dict, indent=2))
	# 1. Gene Expression Data Availability
	is_gene_available = True # Background info shows it's a gene expression microarray study

	# 2.1 Data Row Identification
	trait_row = 14 # 'patient status' contains binary survival outcome
	age_row = 4 # 'age at surgery' contains age data
	gender_row = 3 # Gender info available

	# 2.2 Data Type Conversion Functions
	def convert_trait(value: str) -> int:
	"""Convert patient status to binary: 0=alive, 1=dead"""
	if not value or ":" not in value:
	return None
	status = value.split(":")[1].strip().lower()
	if "death" in status:
	return 1
	elif "alive" in status:
	return 0
	return None

	def convert_age(value: str) -> float:
	"""Convert age string to float"""
	if not value or ":" not in value:
	return None
	try:
	age = float(value.split(":")[1].strip().split()[0])
	return age
	except:
	return None

	def convert_gender(value: str) -> int:
	"""Convert gender to binary: 0=female, 1=male"""
	if not value or ":" not in value:
	return None
	gender = value.split(":")[1].strip().lower()
	if "female" in gender:
	return 0
	elif "male" in gender:
	return 1
	return None

	# 3. Save Initial Metadata
	is_trait_available = trait_row is not None
	validate_and_save_cohort_info(
	is_final=False,
	cohort=cohort,
	info_path=json_path,
	is_gene_available=is_gene_available,
	is_trait_available=is_trait_available
	)

	# 4. Clinical Feature Extraction
	if trait_row is not None:
	clinical_features = geo_select_clinical_features(
	clinical_df=clinical_data,
	trait=trait,
	trait_row=trait_row,
	convert_trait=convert_trait,
	age_row=age_row,
	convert_age=convert_age,
	gender_row=gender_row,
	convert_gender=convert_gender
	)

	# Preview the extracted features
	print("Preview of clinical features:")
	print(preview_df(clinical_features))

	# Save to CSV
	clinical_features.to_csv(out_clinical_data_file)
	# Extract gene expression data from the matrix file
	genetic_data = get_genetic_data(matrix_file_path)

	# Print first 20 row IDs
	print("First 20 row IDs:")
	print(genetic_data.index[:20].tolist())
	# The row identifiers appear to be numerical indices rather than human gene symbols
	# This indicates that gene mapping will be needed to convert identifiers to gene symbols
	requires_gene_mapping = True
	# Extract gene annotation data from SOFT file
	gene_metadata = get_gene_annotation(soft_file_path)

	# Display information about the annotation data
	print("Column names:")
	print(gene_metadata.columns.tolist())

	# Look at general data statistics
	print("\nData shape:", gene_metadata.shape)

	# Preview the first few rows
	print("\nPreview of the annotation data:")
	print(json.dumps(preview_df(gene_metadata), indent=2))
	# 1. & 2. Get gene mapping dataframe from gene annotation
	# The 'ID' column in gene_metadata matches the row indices in genetic_data
	# The 'GENE_SYMBOL' column contains the gene symbols we want to map to
	mapping_df = get_gene_mapping(gene_metadata, prob_col='ID', gene_col='GENE_SYMBOL')

	# 3. Convert probe-level measurements to gene expression data
	gene_data = apply_gene_mapping(genetic_data, mapping_df)

	# Preview the results
	print("First 10 gene symbols after mapping:")
	print(gene_data.index[:10].tolist())

	print("\nShape of gene expression data before and after mapping:")
	print(f"Before: {genetic_data.shape}")
	print(f"After: {gene_data.shape}")
	# 1. Normalize gene symbols
	gene_data = normalize_gene_symbols_in_index(gene_data)
	gene_data.to_csv(out_gene_data_file)

	# Get clinical features
	clinical_features = geo_select_clinical_features(
	clinical_data,
	trait=trait,
	trait_row=trait_row,
	convert_trait=convert_trait,
	age_row=age_row,
	convert_age=convert_age,
	gender_row=gender_row,
	convert_gender=convert_gender
	)

	# 2. Link clinical and genetic data
	linked_data = geo_link_clinical_genetic_data(clinical_features, gene_data)

	# 3. Handle missing values
	linked_data = handle_missing_values(linked_data, trait)

	# Early exit if trait values are all NaN
	if linked_data[trait].isna().all():
	is_biased = True
	linked_data = None
	else:
	# 4. Judge whether features are biased and remove biased demographic features
	is_biased, linked_data = judge_and_remove_biased_features(linked_data, trait)

	# 5. Final validation and save metadata
	note = "Dataset from a cancer gene expression study using oligonucleotide microarrays, containing samples from various tissue types including kidney, lung, stomach and other organs, with both tumor and normal tissues."
	is_usable = validate_and_save_cohort_info(
	is_final=True,
	cohort=cohort,
	info_path=json_path,
	is_gene_available=True,
	is_trait_available=True,
	is_biased=is_biased,
	df=linked_data,
	note=note
	)

	# 6. Save the linked data only if it's usable
	if is_usable:
	os.makedirs(os.path.dirname(out_data_file), exist_ok=True)
	linked_data.to_csv(out_data_file)