Datasets:

Liu-Hy
/

GenoTEX

	# Path Configuration
	from tools.preprocess import *

	# Processing context
	trait = "Stomach_Cancer"
	cohort = "GSE130823"

	# Input paths
	in_trait_dir = "../DATA/GEO/Stomach_Cancer"
	in_cohort_dir = "../DATA/GEO/Stomach_Cancer/GSE130823"

	# Output paths
	out_data_file = "./output/preprocess/3/Stomach_Cancer/GSE130823.csv"
	out_gene_data_file = "./output/preprocess/3/Stomach_Cancer/gene_data/GSE130823.csv"
	out_clinical_data_file = "./output/preprocess/3/Stomach_Cancer/clinical_data/GSE130823.csv"
	json_path = "./output/preprocess/3/Stomach_Cancer/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)
	print("Background Information:")
	print(background_info)
	print("\nSample Characteristics:")

	# Get dictionary of unique values per row
	unique_values_dict = get_unique_values_by_row(clinical_data)
	for row, values in unique_values_dict.items():
	print(f"\n{row}:")
	print(values)
	# 1. Gene Expression Data Availability
	# Based on the background information mentioning "RNA expression profiles" and "Agilent Microarray",
	# this dataset contains gene expression data
	is_gene_available = True

	# 2. Variable Availability and Data Type Conversion
	# Trait: From background info, samples are gastric cancer vs control
	trait_row = 0 # 'tissue' field contains this info

	# Age: Available in row 2 with numeric values
	age_row = 2

	# Gender: Available in row 1
	gender_row = 1

	def convert_trait(value: str) -> int:
	val = value.split(':')[1].strip().lower()
	# If explicitly mentioned as cancer/lesion, it's a case
	if any(x in val for x in ['cancer', 'lesion']):
	return 1
	# Otherwise it's a control
	elif 'gastric' in val:
	return 0
	return None

	def convert_age(value: str) -> float:
	try:
	# Extract numeric value after colon
	return float(value.split(':')[1].strip())
	except:
	return None

	def convert_gender(value: str) -> int:
	val = value.split(':')[1].strip().lower()
	if val == 'female':
	return 0
	elif val == 'male':
	return 1
	return None

	# 3. Save 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 processed clinical data
	preview = preview_df(clinical_features)
	print("Preview of clinical features:")
	print(preview)

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

	# Examine data structure
	print("Data structure and head:")
	print(genetic_data.head())

	print("\nShape:", genetic_data.shape)

	print("\nFirst 20 row IDs (gene/probe identifiers):")
	print(list(genetic_data.index)[:20])

	# Get a few column names to verify sample IDs
	print("\nFirst 5 column names:")
	print(list(genetic_data.columns)[:5])
	# Based on review of the gene identifiers like "(+)E1A_r60_1", "A_19_P00315452" etc.,
	# these appear to be probe IDs rather than standardized gene symbols
	requires_gene_mapping = True
	# Extract gene annotation data
	gene_annotation = get_gene_annotation(soft_file_path)

	# Preview column names and values from annotation dataframe
	print("Gene annotation DataFrame preview:")
	print(preview_df(gene_annotation))
	# 1. After reviewing the annotation data, 'ID' column matches probe IDs in gene expression data,
	# and 'GENE_SYMBOL' contains corresponding gene symbols

	# 2. Get mapping between probe IDs and gene symbols
	mapping_data = get_gene_mapping(gene_annotation, prob_col='ID', gene_col='GENE_SYMBOL')

	# 3. Apply the mapping to convert probe-level data to gene-level data
	gene_data = apply_gene_mapping(genetic_data, mapping_data)

	# Print preview to verify the mapping result
	print("Gene expression data after mapping:")
	print(gene_data.head())
	print("\nShape after mapping:", gene_data.shape)
	# 1. Normalize gene symbols in gene expression data
	gene_data = normalize_gene_symbols_in_index(gene_data)
	os.makedirs(os.path.dirname(out_gene_data_file), exist_ok=True)
	gene_data.to_csv(out_gene_data_file)
	print("\nGene data shape (normalized gene-level):", gene_data.shape)

	# Load clinical data previously processed
	selected_clinical_df = pd.read_csv(out_clinical_data_file, index_col=0)
	print("\nClinical data shape:", selected_clinical_df.shape)

	# 2. Link clinical and genetic data using normalized gene-level data
	linked_data = geo_link_clinical_genetic_data(selected_clinical_df, gene_data)
	print("\nLinked data shape:", linked_data.shape)

	# 3. Handle missing values systematically
	if trait in linked_data.columns:
	linked_data = handle_missing_values(linked_data, trait)

	# 4. Check for bias in trait and demographic features
	trait_biased, linked_data = judge_and_remove_biased_features(linked_data, trait)

	# 5. Final validation and information saving
	note = "Data was successfully preprocessed from probe-level to gene-level expression using gene symbol normalization with NCBI Gene database."
	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=trait_biased,
	df=linked_data,
	note=note
	)

	# 6. Save linked data only if usable and not biased
	if is_usable and not trait_biased:
	os.makedirs(os.path.dirname(out_data_file), exist_ok=True)
	linked_data.to_csv(out_data_file)