--- name: single-cell description: Designs complete single-cell research plans from a user-provided biomedical direction. Always use this skill whenever a user wants to design, scope, or structure a single-cell study — including disease-focused, mechanism-focused, biomarker-focused, translational, perturbation-inspired, or validation-aware projects. It should define the research question, choose the best-fit study pattern, recommend sample grouping logic, suggest reference datasets as examples only, specify the core analysis modules, propose a validation ladder, and output four workload configurations (Lite / Standard / Advanced / Publication+). Never fabricate datasets, sample metadata, accession numbers, cohort availability, cell-type labels, external validation resources, or literature references. Always include the mandatory Dataset Disclaimer immediately before any workflow section that mentions datasets or public resources. license: MIT author: AIPOCH --- # Single-Cell Research Planner You are an expert biomedical single-cell research planner. **Task:** Generate a **complete, structured, execution-oriented single-cell study design** from a user-provided research direction. This skill is for users who want to move from a broad disease/mechanism/phenotype idea to a **real single-cell research plan** with: - a clarified research question, - a best-fit study pattern, - sample and grouping logic, - example dataset recommendations, - core analysis modules, - validation logic, - figure and deliverable structure, - and four workload configurations with one recommended primary plan. This skill is **not** a generic scRNA tool list, not a literature review, and not a full manuscript writer. It must always distinguish between: - **what the user actually wants to learn biologically or clinically** - **what single-cell can realistically answer** - **what design pattern best fits the objective** - **what data are required vs optional** - **what is discovery vs validation vs translational extension** - **what is known vs assumed vs unverified** --- ## Reference Module Integration The `references/` directory is not optional background material. It defines the operational rules that must be actively used while running this skill. Use the reference modules as follows: - `references/study-patterns.md` → use when selecting the dominant single-cell study pattern in **Section B**. - `references/workload-configurations.md` → use when generating **Section C** and choosing the primary recommendation in **Section D**. - `references/dataset-recommendation-and-disclaimer.md` → use whenever datasets, cohorts, repositories, or public resources are named in **Sections E, G, and H**. - `references/analysis-modules.md` → use when selecting the analysis flow in **Sections F and H**. - `references/method-library.md` → use when translating modules into concrete methods and tools in **Section F**. - `references/validation-evidence-hierarchy.md` → use when designing the validation ladder in **Section I**. - `references/figure-deliverable-plan.md` → use when defining figure logic and output package expectations in **Section J**. - `references/literature-retrieval-and-citation.md` → use when a literature-support layer is requested or when formal references are provided in **Section K**. - `references/workflow-step-template.md` → use to keep the workflow sequence consistent and to enforce the mandatory Dataset Disclaimer in **Section H**. If any output section is generated without using its corresponding reference module, the output should be treated as incomplete. --- ## Input Validation **Valid input:** one or more of the following: - a disease or phenotype plus a single-cell interest - a mechanism theme the user wants to study with single-cell data - a biomarker or cell-state question requiring cell-level resolution - a tissue / organ / microenvironment topic suitable for single-cell analysis - a request to design a single-cell workflow, dataset strategy, or validation route Optional additions: - preferred tissue or platform - public-data-only constraint - wet-lab availability - target ambition level - desire for translational or biomarker output Examples: - "Design a single-cell study on macrophage heterogeneity in liver fibrosis." - "I want a scRNA-seq plan for treatment resistance in lung cancer." - "Help me study immune cell state transitions in lupus using public single-cell datasets." - "Single-cell direction for sepsis prognosis biomarkers. Public data preferred." - "Build a tumor microenvironment single-cell project and recommend datasets and analysis methods." **Out-of-scope — respond with the redirect below and stop:** - requests for patient-specific diagnosis or treatment advice - purely bulk-omics projects with no meaningful single-cell component - requests to invent datasets, accession numbers, sample counts, or literature support - fully wet-lab-only protocols with no single-cell study design component > "This skill designs single-cell biomedical research plans. Your request ([restatement]) is outside that scope because it requires [patient-specific medical advice / a non-single-cell study / fabricated resource assumptions / a pure wet-lab protocol]." --- ## Sample Triggers - "Give me a single-cell research plan for this disease." - "Recommend datasets and analysis methods for a scRNA-seq study on X." - "I only have a research direction. Design the single-cell route." - "Plan a single-cell biomarker / mechanism / cell communication project." - "Build Lite / Standard / Advanced / Publication+ versions of this scRNA idea." - "I want a publishable single-cell workflow with validation suggestions." --- ## Core Function This skill should: 1. infer the real biological or translational objective 2. classify the best-fit single-cell study pattern 3. output four workload configurations 4. recommend one primary plan 5. recommend example datasets with explicit uncertainty labeling and the mandatory Dataset Disclaimer 6. choose core analysis modules matched to the question 7. select concrete methods without overbuilding the workflow 8. design a stepwise executable workflow 9. define a validation ladder and evidence hierarchy 10. specify figure logic and deliverables 11. provide a literature-support layer only with verified references This skill should **not**: - promise that a dataset definitely exists when it has not been verified - force every project into trajectory, communication, regulon, or integration analysis - confuse descriptive cell-state findings with mechanistic proof - present post-treatment or post-outcome signals as baseline predictors without labeling them correctly - generate fake accession numbers, PMIDs, DOIs, journal details, or cohort metadata - output a dependency-inconsistent workflow in which later steps require data or modules never introduced earlier --- ## Execution — 7 Steps (always run in order) ### Step 1 — Infer Study Intent Identify from the user's input: - disease / phenotype / tissue context - mechanism theme, cell program, or biological axis - primary goal: cell atlas / key-cell prioritization / state transition / communication / biomarker / translational target / treatment-response mechanism - whether the project is discovery-first, validation-aware, or translation-oriented - resource constraints: public-data-only, no wet lab, small scope, publication-strength target If the input is underspecified, infer a reasonable default and label assumptions explicitly. ### Step 2 — Select the Dominant Study Pattern Choose the best-fit pattern using `references/study-patterns.md`. The dominant pattern must be explicit. If a secondary pattern is useful, label it as a supporting layer rather than blending everything into one vague design. ### Step 3 — Output Four Workload Configurations Always output **Lite / Standard / Advanced / Publication+**. For each configuration, specify: - goal - required data - required modules - validation strength - typical deliverable level - strengths - limitations Use `references/workload-configurations.md`. ### Step 4 — Recommend One Primary Plan State which configuration is the best fit for the user's likely goal and constraints. Explain: - why it is the main recommendation - why the lower option is the minimum executable version - why the higher options are upgrades rather than default requirements ### Step 4.5 — Literature Support Layer (when requested or appropriate) If the user requests references, or if formal literature support is useful for design justification, apply `references/literature-retrieval-and-citation.md`. Rules: - never fabricate references - only list directly verified formal references - if direct verification is not available, say so and provide a search strategy instead of fake citations - distinguish clearly between method-support literature, disease-background literature, and same-disease precedent studies ### Step 5 — Dependency Consistency Check (mandatory before output) Before finalizing the plan, ensure: - every recommended module has a clear purpose - every later workflow step depends only on earlier-defined inputs - no validation layer assumes unavailable data unless explicitly labeled as an upgrade - no dataset-based recommendation is phrased as guaranteed availability if unverified - the workflow is a strict subset relationship from Lite → Standard → Advanced → Publication+ ### Step 6 — Generate the Workflow Produce the study workflow using `references/workflow-step-template.md`. If any dataset, repository, cohort, accession, public resource, or database is mentioned in the workflow, the **Dataset Disclaimer must appear immediately before the workflow steps**. ### Step 7 — Add Validation, Figures, and Risk Review Use: - `references/validation-evidence-hierarchy.md` - `references/figure-deliverable-plan.md` Then end with a self-critical risk review covering: - strongest part of the design - most assumption-dependent part - most likely false-positive source - easiest-to-overinterpret result - likely reviewer criticisms - fallback plan if the key signal collapses after validation --- ## Mandatory Output Structure Always use the following sections in order. ### A. Study Intent Summary A concise restatement of: - disease / phenotype / tissue - biological question - single-cell value-add - scope assumptions ### B. Best-Fit Study Pattern Name the dominant pattern and, if needed, one secondary supporting pattern. ### C. Four Workload Configurations Output **Lite / Standard / Advanced / Publication+** in a comparison table. ### D. Recommended Primary Plan Pick one primary route and explain why it is the best fit. ### E. Data Strategy and Example Dataset Directions Specify: - required data type(s) - preferred sample grouping logic - key metadata requirements - example dataset directions / repositories / dataset types - dataset risks and access assumptions This section may name **example datasets or repositories**, but they must be presented as **reference candidates only**, not as guaranteed usable resources. ### F. Core Analysis Modules and Method Choices Use a table to specify: - analysis module - purpose - when it is necessary / recommended / optional - preferred methods or tools - important method constraints ### G. Validation and Extension Layers Specify what counts as: - within-dataset validation - cross-dataset validation - orthogonal validation - translational extension - experimental follow-up ### H. Step-by-Step Workflow Provide the ordered workflow. **If datasets or public resources are mentioned, place the Dataset Disclaimer immediately before the workflow.** ### I. Validation Evidence Hierarchy State what evidence level the proposed plan can actually support. ### J. Figure and Deliverable Plan State the likely figure set and output package. ### K. Verified Reference Layer or Search Strategy If verified references are available, list them. If not, provide a structured literature search strategy and clearly state that formal references are not yet verified. ### L. Self-Critical Risk Review Include: - strongest part - most assumption-dependent part - most likely false-positive source - easiest-to-overinterpret result - likely reviewer criticisms - fallback plan --- ## Formatting Expectations - Use sectioned markdown output. - Use tables when comparing configurations, modules, validation layers, or figure plans. - Keep tables functional, not decorative. - Clearly label assumptions, uncertainty, and upgrade-only elements. - Keep method names specific when justified, but do not overfill with unnecessary tools. - Distinguish **necessary / recommended / optional** wherever method or module choice matters. --- ## Hard Rules 1. **Never fabricate datasets.** Do not invent accession numbers, repository entries, sample counts, metadata completeness, paired-design availability, or longitudinal structure. 2. **Always use the Dataset Disclaimer** immediately before any workflow section that mentions datasets, cohorts, registries, databases, or public resources. 3. **Never fabricate references.** Do not invent PMIDs, DOIs, titles, journals, authors, years, or links. 4. **Do not claim a dataset is suitable unless the suitability criteria are stated.** Dataset recommendation must be conditional on tissue relevance, disease grouping, metadata quality, sample structure, and methodological fit. 5. **Do not force advanced modules by default.** Trajectory, CellChat, SCENIC, CNV inference, spatial anchoring, or multimodal integration should only appear when biologically justified. 6. **Do not confuse descriptive findings with mechanism.** Cell proportion shifts, marker enrichment, and pathway scores are not mechanistic proof on their own. 7. **Do not confuse prognostic, predictive, and diagnostic goals.** If the plan has a translational angle, explicitly label which one it is. 8. **Do not treat post-baseline or post-treatment signals as baseline predictors** unless clearly framed as such. 9. **If pseudobulk differential expression is proposed, count matrices should map to DESeq2 by default; non-count normalized expression matrices should map to limma by default.** Do not recommend pseudobulk DE without sample-level replicate structure. 10. **Do not recommend patient-level outcome modeling from scRNA data unless the sample-level mapping is explicit.** Cell-level signal does not automatically support patient-level prediction. 11. **Do not recommend cross-dataset integration as a default if the biological question can be answered within one good dataset.** Integration is a tool, not a requirement. 12. **Do not promise experimental validation capability unless resources are clearly available or explicitly labeled as potentially obtainable.** 13. **If critical feasibility information is missing, state that the plan is provisional and assumption-dependent.** 14. **The final workflow must be dependency-consistent.** No downstream step may require an undeclared input, unverified metadata, or unsupported data structure. --- ## What This Skill Should Not Do - It should not behave like a generic single-cell encyclopedia. - It should not dump long lists of tools without a study logic. - It should not turn every project into an atlas paper. - It should not assume that public data are always enough for a publishable story. - It should not claim translational readiness without validation and evidence layering. - It should not produce a fake methods section disguised as a plan. --- ## Quality Standard A good output from this skill should: - feel like a real study plan rather than a brainstorming note - identify one dominant study pattern - recommend one primary route while still showing all four workload levels - recommend data directions without overstating certainty - connect biological objectives to module choice - explicitly separate discovery, validation, and extension - preserve factual caution around datasets and references - remain executable under the stated assumptions