SciMiner Network Pharmacology
Build a transparent hypothesis, not a mechanism claim. Keep experimental, curated-database, predicted, literature, and computational evidence separate throughout the workflow.
Prerequisites and boundaries
- Require the SciMiner credential file at
~/.config/sciminer/credentials.json, with oneapi_keyfield, before submitting any SciMiner task. Read it only at runtime; never print, copy, or persist the key. - Resolve every SciMiner capability from the live tool-doc index at
https://sciminer.tech/tool_api_files/and read the selected*_api_doc.mdimmediately before invocation. That document is authoritative for provider/tool names, parameters, upload behavior, polling, and results. - Return each successful task's
share_url. Preserve itstask_idand source-document URL in the project manifest. - Do not use a target prediction, a network centrality score, enrichment, or docking score as proof of binding, efficacy, synergy, causality, or clinical benefit.
- Do not call a tool with guessed parameters. Ask for missing required inputs or omit the optional analysis.
Inputs and project contract
Collect or create project_manifest.json before analysis. Record the project question, date, analyst, species, disease term and ontology ID, compound source, structures, access dates, database/tool versions, thresholds, and every exclusion.
Accept one of these input shapes:
- A compound table with
compound_id,name, and SMILES/InChIKey; optionally source herb, plant part, preparation, measured abundance, and exposure evidence. - A formula/herb list. First request or retrieve a traceable compound table; never invent constituents from an herb name.
- A small molecule and disease/phenotype. Require a canonical disease term and species before disease-target analysis.
- User-provided targets, PPI edges, omics results, or docking structures. Preserve their source and identifier namespace.
Read evidence-model.md before scoring, filtering, ranking, or interpreting results. Read sciminer-tool-routing.md before selecting a SciMiner capability.
Workflow
1. Resolve entities and scope
- Canonicalize compounds by structure, not display name. Preserve original names and aliases.
- Record herb Latin name, Chinese/common name, medicinal part, preparation, and formula role separately; do not merge them into a single label.
- Normalize genes and proteins to one primary namespace and report unmapped or one-to-many mappings.
- Resolve the disease to an ontology term. State whether the question concerns therapeutic mechanism, repurposing, toxicity, or a specific phenotype.
- Define a biologically defensible universe before overlap or enrichment work; for an omics study, it is normally the tested/detectable genes, not the full genome by default.
2. Build the component evidence table
- Assign component evidence tier:
measured>curated/literature>database-listed>in-silico candidate. - Use SciMiner tools for structure conversion, Lipinski/PAINS checks, ADMET, descriptors, or pKa only when they answer the study question. Do not apply universal OB/DL cutoffs mechanically.
- Keep rejected compounds and the reason in
component_exclusions.csv. - For a formula, retain herb-to-compound provenance so that apparent multi-herb convergence can be inspected.
3. Acquire and grade target evidence
- Prefer quantitative bioactivity or curated mechanism evidence. Use target prediction only as a hypothesis-generating lane.
- Use the live SciMiner target-prediction documentation for each compound. Store input structure, returned rank/score, model name, task ID, and share URL.
- Use a separate SciMiner off-target analysis for safety or promiscuity questions; do not present its result as disease efficacy evidence.
- For disease relevance, use independent genetics, functional, expression, pathway, clinical, and literature sources where available. If the SciMiner Life-Science Database Query skill is installed, route broad database retrieval through its minimum relevant sub-skills; otherwise document the public sources actually used.
- Create
target_evidence.csvwith one row per compound–target–evidence record, not one merged opaque score.
4. Construct and analyze the evidence network
- Build typed edges:
herb→compound,compound→target,target→disease,target↔target,target→pathway, andcompound→adverse-effectwhen available. - Attach
evidence_tier,evidence_type,source,access_date,score_or_value, anddirectionto every eligible edge. Useunknownrather than inferring activation or inhibition. - Report graph size, isolated nodes, connected components, source composition, and confidence-filter sensitivity before selecting hubs or modules.
- Treat frequent network hubs (for example, TP53, AKT1, TNF, IL6) as generic candidates until disease relevance, tissue/cell context, and compound evidence justify their prioritization.
- Use render_network_report.py to make a standalone, interactive HTML report and a machine-readable JSON network. Supply node and edge tables rather than hand-drawing a network.
5. Interpret pathways and biological context
- Perform enrichment on the declared foreground against the declared background and report method, multiple-testing adjustment, annotation release/date, and gene-ID conversion losses.
- Prefer disease-relevant modules and directional evidence over long lists of generic GO terms. Explain whether each proposed effect is direct, indirect, predicted, or unknown.
- Cross-check leading targets against tissue/cell context and any supplied transcriptomic/proteomic evidence. Do not conflate disease-associated expression with a causal drug target.
6. Add computational support only when justified
- Run docking only for a short, pre-specified compound–target set with target evidence, a credible structure and binding-site rationale.
- Use live SciMiner documentation for tools such as AutoDock Vina, DiffDock, or scoring tools. Record receptor structure ID, chain, ligand/protonation state, search box/site, tool/model, and task URL.
- Inspect pose plausibility and known activity where possible. Label docking as
supporting computational evidence; never use it as standalone validation.
7. Report conclusions, negative findings, and validation
Deliver project_manifest.json, component_evidence.csv, target_evidence.csv, nodes.csv, edges.csv, network.json, network_report.html, and a concise narrative.
State separately:
- robust observations;
- ranked but unverified hypotheses;
- contradictory or missing evidence;
- negative results, including no credible target, disconnected network, non-significant enrichment, or failed docking;
- the smallest discriminating experiment for each leading hypothesis (for example, target engagement, pathway readout, gene perturbation, or exposure assay).
Minimum output schema
Use these fields unless the source lacks a value:
component_evidence.csv: compound_id,name,structure,source_herb,component_tier,source,access_date,decision,reason
target_evidence.csv: compound_id,target_id,target_symbol,evidence_tier,evidence_type,score_or_value,direction,source,access_date,task_id,share_url
nodes.csv: id,label,type,evidence_tier,score,description
edges.csv: source,target,evidence_type,evidence_tier,weight,direction,source_ref
Use type values such as herb, compound, target, disease, pathway, and adverse_effect. Do not omit rows merely because their confidence is low; encode the confidence and filter transparently in views.
Visual and writing rules
- Use the interactive report for exploration and export a filtered, legible static figure for a manuscript. Never use a dense all-entity hairball as the sole figure.
- Use color for entity type and line style/opacity for evidence tier; include a legend and source counts.
- Make titles claim only the evidence level, for example: “Predicted and curated target network for …”, not “Mechanism of …”.
- Cite database/tool documents and access dates next to conclusions. Include SciMiner share URLs for every successful task.
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