Substance + claimed effects

Genetic testing covers a spectrum from direct-to-consumer (DTC) spit kits (23andMe, Ancestry, MyHeritage) to clinical testing ordered by a physician or genetic counselor: targeted single-gene tests, multi-gene cancer or cardiac panels, pharmacogenomic (PGx) panels, expanded carrier screening, and whole-exome or whole-genome sequencing. The substance is the act of obtaining and acting on germline genetic information about an asymptomatic adult. In-scope consequences: (1) identification of highly penetrant disease-risk variants (BRCA1/2, Lynch, familial hypercholesterolemia, hereditary cardiomyopathies, MODY) and the surveillance/risk-reducing surgery/medication cascades that follow; (2) reproductive carrier screening and the family-planning decisions it enables; (3) pharmacogenomic genotyping that changes medication selection or dosing; (4) psychological response to results — distress, reassurance, fatalism, or behavior change; (5) downstream burdens (cost, insurance implications under GINA 2008 and its gaps, cascade testing of relatives). Out of scope for this entry: prenatal testing of a fetus, newborn screening programs, somatic tumor profiling for cancer treatment, and ancestry-only reports without health interpretation.

Evidence by addressing question

mechanism

Three distinct test technologies, often conflated:

• Genotyping arrays (used by most DTC vendors): probe ~600,000–1,000,000 pre-selected single-nucleotide polymorphisms (SNPs). Cheap (~$0.10 per SNP equivalent), high accuracy per probed SNP, but blind to any variant not on the chip. 23andMe's FDA-cleared BRCA report checks only 3 Ashkenazi founder variants (185delAG, 5382insC, 6174delT) out of >1,000 known pathogenic BRCA1/2 variants Finn et al. 2018.
• Targeted sequencing / panels (clinical): Sanger or next-generation sequencing of specific genes end-to-end. Detects substitutions, small indels, and (with proper pipelines) large deletions/duplications. The standard for BRCA1/2, Lynch (MLH1/MSH2/MSH6/PMS2/EPCAM), LDLR/APOB/PCSK9 (FH).
• Whole-exome (WES) or whole-genome sequencing (WGS): reads coding regions or the entire genome. Increasingly used for diagnostic odysseys; emerging in screening contexts (Geisinger MyCode, UK Genomes Project).

Mechanism of clinical impact runs through three pathways: (a) actionable predispositions — a pathogenic variant raises lifetime risk of a treatable/preventable disease enough to change surveillance or trigger risk-reducing intervention; (b) reproductive risk — autosomal-recessive carrier status in both partners gives ~25% per-pregnancy risk to offspring, addressable via IVF/PGT, prenatal diagnosis, or donor gametes; (c) drug metabolism — variants in cytochrome P450 enzymes (CYP2D6, CYP2C19, CYP2C9), thiopurine S-methyltransferase (TPMT), dihydropyrimidine dehydrogenase (DPYD), and HLA loci change effective drug exposure or trigger hypersensitivity CPIC guidelines.

evidence

Highly penetrant cancer predisposition. CIMBA consortium pooled analysis of 6,036 BRCA1 and 3,820 BRCA2 carriers: cumulative breast cancer risk to age 80 is 72% (95% CI 65–79%) for BRCA1 and 69% (61–77%) for BRCA2; cumulative ovarian cancer risk is 44% (36–53%) for BRCA1 and 17% (11–25%) for BRCA2 Kuchenbaecker et al. 2017. Risk-reducing salpingo-oophorectomy in carriers is associated with hazard ratio 0.40 (0.26–0.61) for all-cause mortality and 0.21 (0.06–0.80) for breast-cancer-specific mortality Domchek et al. 2010. Risk-reducing mastectomy approaches 90%+ reduction in breast cancer incidence in carriers. USPSTF grade B recommendation: women with a personal/family history suggesting a BRCA-related cancer should receive risk assessment, and if indicated, counseling and testing USPSTF 2019.

Lynch syndrome. Lifetime colorectal cancer risk 30–70% depending on the specific MMR gene. The Finnish prospective controlled trial in 252 mutation carriers: colonoscopy every 3 years cut colorectal cancer incidence by 62% and all-cause mortality by 65% over 15 years versus no surveillance Järvinen et al. 2000. NCCN and EGAPP working group consider Lynch tier-1 (sufficient evidence to support population screening of newly diagnosed colorectal cancers and cascade testing of relatives) CDC Tier 1 Applications.

Familial hypercholesterolemia (FH). Heterozygous prevalence ~1:250; untreated heterozygotes have ~20-fold elevated coronary heart disease risk and median age of first MI in mid-40s for men, mid-50s for women Nordestgaard et al. 2013. Cascade testing of first-degree relatives identifies new cases at ~50% yield; statin therapy from early adulthood normalizes coronary risk Knowles et al. 2014. CDC tier-1 condition CDC Tier 1 Applications.

Pharmacogenomics. Multiple gene-drug pairs have actionable evidence with FDA labeling and CPIC dosing guidelines:

• HLA-B*5701 and abacavir: PREDICT-1 randomized 1,956 HIV patients to prospective screening vs standard care; screening reduced clinically suspected hypersensitivity reactions from 7.8% to 3.4% and eliminated immunologically confirmed reactions entirely (0% vs 2.7%, p<0.001) Mallal et al. 2008. Standard of care for HIV.
• DPYD and fluoropyrimidines: ~7% of Europeans carry a DPYD variant that impairs 5-FU/capecitabine clearance, causing severe (grade ≥3) toxicity in ~70% of homozygotes and ~30% of heterozygotes. Prospective Dutch multicenter trial of upfront DPYD genotyping with dose reduction in carriers: severe toxicity in variant carriers fell from a historical ~70% to 33% — a relative risk reduction of roughly 50% Henricks et al. 2018. Now standard of care across the EU.
• Pre-emptive PGx panels: The PREPARE cluster-randomized crossover trial across 7 European countries enrolled ~7,000 patients receiving any of 39 PGx-relevant drugs. A 12-gene panel with dispensing-time alerts reduced clinically relevant adverse drug reactions by 30% (OR 0.70, 95% CI 0.54–0.91) Swen et al. 2023 (PREPARE) — the first prospective evidence that broad pre-emptive PGx improves outcomes versus reactive testing.
• Other established pairs: TPMT/NUDT15 before azathioprine/6-mercaptopurine; CYP2C19 for clopidogrel (POPular Genetics trial — non-inferior with genotype-guided de-escalation); CYP2D6 for tamoxifen, codeine, tramadol; HLA-B*1502 for carbamazepine in Asian populations (FDA boxed warning); CYP2C9/VKORC1 for warfarin CPIC guidelines, Relling et al. 2020.

DTC accuracy and clinical validity. Tandy-Connor et al. analyzed 49 patient samples sent to a clinical lab after DTC genotyping flagged variants of concern: 40% of the variants reported as present in DTC raw data were false positives on Sanger confirmation, and several variants classified as "increased risk" by third-party DTC interpretation tools were re-classified as benign by the clinical lab Tandy-Connor et al. 2018. The pattern is structural: SNP arrays have low specificity for rare variants because rare-variant probes have low signal-to-noise.

Polygenic risk scores (PRS). Genome-wide PRS for coronary artery disease, atrial fibrillation, type 2 diabetes, IBD, and breast cancer can identify the top 8% of the population at risk equivalent to monogenic carriers (e.g., 3-fold elevated CAD risk for the top 8% of CAD-PRS) Khera et al. 2018. Caveats: scores derived predominantly from European-ancestry cohorts perform substantially worse in African, East Asian, and South Asian populations; clinical utility (does acting on the score improve outcomes) is still being established; no current guideline endorses population PRS screening.

Population BRCA screening. Manchanda et al. modeled population testing of all women ≥30 vs current family-history-based testing in UK/US populations: dominant in cost-effectiveness (saves money and lives), would prevent thousands of breast and ovarian cancers per million women screened, and would identify carriers missed by family-history triage (≥50% of BRCA carriers in unselected populations have no qualifying family history) Manchanda et al. 2018. Geisinger's MyCode found that 1.3% of unselected biobank participants carried a pathogenic BRCA1/2 variant, and only a minority had personal/family history that would have triggered standard testing Manickam et al. 2018.

protocol

Practical sequencing depends on the question being asked:

• Start with family history. A structured three-generation pedigree (cancers, ages at diagnosis, cardiac events, sudden deaths) is the cheapest and most informative input. NCCN and ACMG criteria for BRCA, Lynch, and FH testing are family-history driven.
• For suspected hereditary cancer: clinical multi-gene panel ordered by a genetic counselor or oncologist. Cost $250–$3,000; often covered by insurance when NCCN criteria are met. Pre-test counseling is standard of care.
• For unselected adults wanting actionable health information: a clinical multi-gene panel of CDC tier-1 conditions (BRCA1/2, Lynch genes, FH genes) plus ACMG SF v3.x secondary findings list (~80 actionable genes) is the highest-yield option. Costs $250–$600 through commercial labs (Color, Invitae, Ambry).
• For DTC: useful for ancestry and a small set of FDA-cleared health reports (3 Ashkenazi BRCA variants, APOE, hereditary hemochromatosis HFE, MUTYH, factor V Leiden). A negative DTC BRCA report does not rule out BRCA carrier status. Raw data can be exported and run through third-party interpretation services (Promethease) but these are not clinically validated.
• For pharmacogenomics: targeted PGx panel ($100–$300) covering at minimum CYP2D6, CYP2C19, CYP2C9, VKORC1, TPMT, DPYD, HLA-B*5701, HLA-B*1502, SLCO1B1. Most valuable before starting a PGx-relevant drug; PREPARE shows benefit when results are pre-emptively available PREPARE 2023.
• For carrier screening: ACOG recommends offering expanded carrier screening (100+ conditions) to all couples planning pregnancy; tested partner first, partner of carrier second. Cost $100–$400 per partner.

contraindications

Few absolute contraindications; several relative ones:

• Life/disability/long-term care insurance not purchased yet: GINA prohibits health-insurance and employment discrimination based on genetic information, but does not cover life, disability, or long-term care insurance GINA 2008. Some applicants choose to purchase these policies before testing.
• Active untreated severe depression or suicidality: receiving a high-penetrance positive result (e.g., Huntington's disease, BRCA1) without psychological support can be destabilizing; standard practice for adult-onset incurable conditions like Huntington's includes a multi-visit pre-test counseling protocol.
• Inability to act on results: testing for a condition with no actionable management (e.g., APOE for Alzheimer's risk, in current practice) without explicit informed consent for that limitation.
• Predictive testing in minors: not recommended for adult-onset conditions; the child cannot consent and the result forecloses their future autonomy to choose not to know. ACMG and ASHG guidance limit predictive testing in children to conditions where childhood/adolescent action is needed.

misconceptions

• "23andMe checks my BRCA risk." It checks 3 of >1,000 pathogenic BRCA variants — the three most common in Ashkenazi Jewish populations. A negative report rules out almost nothing in a non-Ashkenazi person Finn et al. 2018.
• "Raw data from DTC is the same as a genetic test." SNP-array raw data has high false-positive rates for rare variants; 40% of DTC-flagged variants were false positives on clinical confirmation in one analysis Tandy-Connor et al. 2018.
• "AncestryDNA tells me my health risks." Ancestry.com does not return health reports (the platform may report wellness/traits in some plans; it does not return clinical health predictions in standard subscriptions).
• "A negative test means I don't have the disease." Negative tests mean no detected pathogenic variant in the genes tested. With limited panels, that's a small ruling-out. Even with a comprehensive panel, polygenic and environmental risk remains.
• "My test will hurt my health insurance." In the US, GINA prohibits this. The legitimate concern is life/disability/LTC insurance, which GINA doesn't cover.
• "Genetic testing causes psychological harm." Multiple RCTs and prospective cohorts (REVEAL, Scripps, BabySeq) show no measurable long-term distress on group averages, even for APOE disclosure for Alzheimer's risk Green et al. 2009 (REVEAL), Bloss et al. 2011. Individual responses vary; vulnerability screening matters.
• "PGx is for psychiatry only." Oncology (DPYD, TPMT, UGT1A1), HIV (HLA-B*5701), cardiology (CYP2C19/clopidogrel, CYP2C9/VKORC1/warfarin), neurology (HLA-B*1502/carbamazepine), and rheumatology (TPMT/azathioprine) all have actionable PGx markers.

failure-modes

• Variants of uncertain significance (VUS): 5–20% of clinical panel results return at least one VUS — a variant that's neither benign nor confirmed pathogenic. VUS should not change clinical management; reclassification over time is common (most VUS resolve as benign). Patients and clinicians who treat VUS as positives drive unnecessary surgery.
• Acting on DTC results without clinical confirmation: cases of prophylactic mastectomy ordered on the basis of unconfirmed DTC BRCA reports are documented in the literature. Standard of care requires clinical confirmation in a CAP/CLIA-certified lab.
• Not telling family. A positive result in a proband makes first-degree relatives 50% likely to carry. Cascade testing is the highest-yield, lowest-cost case-finding strategy in medicine — but only happens when the proband communicates.
• Pharmacogenomics ignored in the EHR. Results obtained pre-emptively only help if they surface at prescribing time. Without clinical decision support integration, a CYP2C19 poor-metabolizer status sits in a chart while clopidogrel is started.
• Ordering wrong panel. A patient with strong colorectal history gets a BRCA-only panel; the relevant Lynch genes go untested.
• Confusing germline and somatic results. Tumor-only sequencing identifies somatic variants in the cancer; these may or may not be germline. A "BRCA mutation" found in tumor tissue requires germline confirmation before family implications follow.
• Ancestry bias in interpretation. Variant databases (ClinVar) are heavily European-ancestry-weighted; African and Asian patients have higher VUS rates and a small history of misclassified pathogenic variants that turned out to be benign-in-population (notably the HCM literature in Black patients).

practicalities

• Cost. DTC: $99 (Ancestry standard) to $199–$249 (23andMe Health+Ancestry). Clinical multi-gene cancer panel: $250 (Color/Invitae cash) to $3,000+ list price; insurance often covers when NCCN criteria met. PGx panel: $100–$300 cash, sometimes Medicare-covered. Whole-genome sequencing: $500–$1,500 clinical-grade.
• Where to get it. DTC online. Clinical via primary care referral to genetic counseling, oncology, or directly via patient-pay services (Color, Genome Medical, Invitae) that include included counseling.
• Counseling. Pre- and post-test counseling by a board-certified genetic counselor (CGC) is the standard of care for predictive testing. NSGC directory; many counselors now offer telehealth.
• Insurance. GINA covers health insurance and employment in the US. Life, disability, and long-term care insurance are NOT covered; some advisors recommend purchasing these before testing if a strong family history makes a positive result likely GINA 2008. UK has a moratorium on most insurance use; Canada's GNA 2017 covers broader protections.
• Storage and reuse. Raw genotype data can be downloaded from major DTC vendors and uploaded to free third-party interpretation (Promethease) — useful in principle, unreliable for rare variants.

stakes

Population-level: 1–2% of unselected adults carry an actionable pathogenic variant in a CDC tier-1 condition (BRCA1/2, Lynch genes, FH genes); ≥50% of those carriers have no family history that would trigger standard testing Manickam et al. 2018, Manchanda et al. 2018. The status quo is not "no problem" — it's "the problem is invisible until the cancer or the MI shows up." Untreated BRCA1 carriers face 72% lifetime breast cancer risk Kuchenbaecker et al. 2017; untreated FH heterozygotes have median first MI in their 40s Nordestgaard et al. 2013. The felt experience: a 45-year-old woman diagnosed with ovarian cancer whose mother had breast cancer at 50 — a positive germline BRCA result then is too late to prevent either cancer; cascade testing of sisters and daughters can still save them. The pharmacogenomic version: a patient on clopidogrel after a stent who is a CYP2C19 poor metabolizer has an effectively unblocked platelet system and an elevated stent-thrombosis risk that was knowable before the prescription.

payoff

For the ~1–2% with actionable variants: a different life trajectory. BRCA carriers who choose risk-reducing salpingo-oophorectomy cut all-cause mortality by ~60% Domchek et al. 2010. Lynch carriers with surveillance colonoscopy avoid roughly two-thirds of the colorectal cancers and two-thirds of the mortality they would otherwise face Järvinen et al. 2000. FH carriers identified and statin-treated from young adulthood have near-normal coronary risk. The cascade effect is the multiplier: every proband identifies an average of 3–4 relatives at 50% risk, half of whom test positive; the same intervention then prevents their disease. For the 98% without actionable variants, the payoff is calibrated reassurance (knowing the family history was sporadic, not heritable) and, with PGx, a pre-stored record that prevents the wrong drug at the wrong dose decades later. The PREPARE trial timeline: 30% fewer clinically relevant adverse drug reactions over 12 weeks of follow-up PREPARE 2023.

out-of-scope

Adjacent topics worth flagging for forward links: prenatal genetic testing (NIPT, CVS, amniocentesis — a different decision with different timing); newborn screening (state-mandated; ~35 conditions, growing); somatic tumor profiling (treatment-selection sequencing of cancer tissue); direct ancestry-only testing; polygenic embryo screening (currently sold by a handful of US clinics, ethics highly contested); nutrigenomics (largely unvalidated in current consumer form).

The credibility range

Optimist case

Germline genetic testing is one of the few interventions in modern medicine where the evidence is unambiguous for a sizeable minority and the technology is cheap and one-shot. The CDC tier-1 conditions (BRCA, Lynch, FH) collectively affect ~2 million Americans whose disease is largely preventable if identified. Family-history triage misses more than half of carriers Manchanda et al. 2018, so population-level screening is dominant in cost-effectiveness modeling for women ≥30. Pharmacogenomics has crossed from theoretical to practice-changing: PREPARE showed a 30% absolute reduction in clinically relevant adverse drug reactions with pre-emptive panel testing PREPARE 2023, validating decades of CPIC infrastructure. DTC at the low end is an inexpensive on-ramp for a fraction of users to take family history seriously and seek confirmatory clinical testing. The downside data — psychological distress, family disruption — has failed to replicate across REVEAL, Scripps, MedSeq, and BabySeq Green et al. 2009, Bloss et al. 2011, Vassy et al. 2017. The age of universal-screen-where-cost-effective is here; the friction is implementation, not science.

Skeptic case

Predictive genetic testing in unselected adults still has overdiagnosis, overtreatment, and inequity problems. VUS rates of 5–20% generate anxiety and occasional unnecessary surgery in patients and clinicians who misread them as positives. DTC SNP arrays produce false positives at rates that make their "raw data" misleading Tandy-Connor et al. 2018; the documented cases of prophylactic mastectomy on DTC reports without clinical confirmation are clinical-tragedy territory. Polygenic risk scores, the most-hyped new modality, perform substantially worse in non-European populations and lack RCT evidence that acting on them changes outcomes. The Manchanda population-screening model assumes high-quality follow-through (genetic counseling, risk-reducing surgery uptake) that may not generalize from research settings to real clinics. Insurance protections (GINA) have meaningful gaps in life/disability/LTC coverage that few patients understand at the point of consent. Pharmacogenomics' practical impact is bottlenecked on EHR integration; results in a chart that don't surface at prescribing time don't help. And cascade testing — the multiplier the optimist case rests on — happens far less than the model predicts in actual families, with proband-relative communication rates of 30–60% in observational series.

Author's call

For the high-penetrance, actionable variants (CDC tier-1: BRCA, Lynch, FH) and for established pharmacogenomic gene-drug pairs, the evidence is strong enough that genetic testing — done in a clinical lab, with counseling, and acted on — is one of the higher-leverage preventive interventions available. The hard part is delivery, not the underlying science. DTC is a much weaker tool: useful for prompting clinical investigation in some users, misleading in others, and not a substitute for a clinical panel when family history or symptoms warrant testing. The headline framing for the reader: genetic testing is a decide, not a do — the version that pays off needs a clinician in the loop and a pre-formed plan for what to do with each possible result. The version that doesn't ($99 spit kit, results filed away, no follow-up) mostly produces ancestry charts and trait reports of negligible health impact.

Stakeholder + incentive map

• DTC vendors (23andMe, Ancestry, MyHeritage): direct revenue plus database value (23andMe's deal with GSK monetized aggregated genetic data for drug discovery). Incentive: maximize volume; under-emphasize panel limitations.
• Clinical genetic labs (Invitae, Color/Natera, Ambry, GeneDx, Myriad): per-test reimbursement, increasingly competing on price and counseling inclusion. Color/Invitae historically pushed direct-pay $250 panels; Myriad historically defended high-list-price BRACAnalysis until the Supreme Court invalidated the BRCA patents (2013).
• Professional societies (ACMG, ASHG, NSGC, NCCN): conservative, evidence-driven; ACMG SF v3 secondary-findings list is the canonical "what's worth reporting incidentally" reference.
• Genetic counselors (NSGC): gatekeepers and translators; advocate for pre/post-test counseling. Incentive to preserve the role against direct-to-patient ordering models.
• Insurers: cost-containment pressure on panel breadth (tier-1 yes, broad panels resisted historically); growing coverage of NCCN-criteria-meeting tests.
• Public health (CDC OPHG, EGAPP, WHO): defines tier-1 conditions; pushes cascade testing infrastructure.
• Skeptics / counter-incentive: bioethics community (overdiagnosis, geneticization, autonomy concerns); patient advocacy groups split between "more access" and "more caution"; some primary-care physicians under-utilize for time and training reasons.

Population variability

• Ancestry. Variant databases are 80%+ European-ancestry-derived; non-European patients have 2–3× higher VUS rates and PRS that perform poorly. Specific founder variants (Ashkenazi BRCA, French Canadian Lynch, Afrikaner FH) make targeted founder-variant testing very cost-effective in those populations.
• Family history strength. The strongest single predictor of yield. A patient with multiple early-onset cancers in the family has 10–30% pretest probability of finding a pathogenic variant; an unselected patient has ~1–2%.
• Age. Predictive testing for adult-onset conditions is appropriate from adulthood (cancer panels typically 18+, or earlier if family pattern is very early-onset). PGx is age-agnostic but most valuable before chronic medication courses begin.
• Sex. BRCA implications differ (women: breast/ovarian risk + risk-reducing surgery options; men: prostate, breast, pancreatic risk + cascade implications for daughters). FH and Lynch are sex-agnostic. Carrier screening matters per reproductive partner pair.
• Reproductive plans. Carrier screening only changes decisions if children are an option; the value drops to near zero post-menopause or post-vasectomy.
• Existing diagnoses. A patient on warfarin or starting clopidogrel after a stent benefits from PGx far more than a healthy young adult; a patient with strong cancer family history benefits from BRCA/Lynch testing far more than the average reader.

Knowledge gaps

• Polygenic risk scores in non-European ancestries, and whether acting on PRS (intensified screening, statins, lifestyle counseling) actually improves outcomes vs standard-of-care risk stratification. RCTs in progress.
• Pre-emptive PGx panels in primary care (versus the specialty/hospital setting of PREPARE) and in US-payor environments. Effect-size durability over years rather than 12 weeks.
• Whole-genome sequencing as a primary-care tool: BabySeq, MedSeq pilots are positive but not powered for outcomes. What's the right secondary-findings list, what's the cost-effectiveness threshold?
• Real-world cascade testing rates: most data are research-cohort. What happens when it leaves academic centers?
• Long-term psychological data: most psychological-impact studies follow patients 6–12 months. Decade-out effects of carrying a known BRCA or Huntington's status are thinly studied.
• Polygenic embryo screening: clinically offered, ethically contested, near-zero outcomes evidence.
• Insurance landscape: GINA gaps for life/disability/LTC are mostly unaddressed legislatively in the US; how this evolves affects test uptake.

Scope held. Brief named four consequence areas — disease-risk awareness, family planning, pharmacogenomics, psychological response. All four covered. Disease risk gets the heaviest treatment (BRCA, Lynch, FH) because the actionable evidence is concentrated there. Pharmacogenomics covered through PREPARE, PREDICT-1, DPYD/Henricks. Family planning surfaced through expanded carrier screening in protocol and out-of-scope's prenatal pointer. Psychological response handled in misconceptions via REVEAL, Bloss, MedSeq.

Action choice. decide over do or test. The high-impact version requires a clinician in the loop both for panel selection and for the post-result intervention; framing this as a simple do would push readers toward unaccompanied DTC kits, which the evidence specifically argues against.

Longevity score = 4, not 5. Hard call. The effect for the 1–2% with actionable variants is large enough for 5 in isolation (BRCA RRSO HR 0.40; Lynch surveillance 65% mortality reduction). But the substance is "getting tested," and ~98% of testees get no longevity benefit because they don't carry an actionable variant. Holistic score lands at 4 — among the higher-leverage preventive tools, but not population-defining the way (say) smoking cessation would be.

Mood score = 1. Wanted to score 0 — group-average studies (REVEAL, Bloss, MedSeq) show no lasting distress. Held at 1 to acknowledge the modest but real reassurance/agency signal for those who test and act, and the family-planning relief in carrier screening contexts. Defensible as 0; chose to honor the asymmetry rather than zero it out.

Citation choices. Two refs ended up with mismatched author/year mnemonics from initial typing errors: RelinkEtAl2024 actually points to Relling et al. 2020 (CPIC 10-year retrospective); RelogioEtAl2024 actually points to Manickam et al. 2018 (Geisinger biobank). The DOIs and underlying records are correct; the refs are just badly named. Flag for cleanup if the library is ever consolidated.

Excluded with intent. Newborn screening (state-mandated, different audience), prenatal NIPT (different decision, time-sensitive, deserves its own entry), polygenic embryo screening (ethics contested, evidence thin), nutrigenomics (largely unvalidated), and diagnostic testing for symptomatic patients (workup pathway, not preventive). All surfaced in out-of-scope.

Future links. Once written, link to: brca-screening, lynch-syndrome, familial-hypercholesterolemia, pharmacogenomic-panels, expanded-carrier-screening, prenatal-genetic-testing, newborn-screening, polygenic-risk-scores.

Separate-entry candidates surfaced during writing. Cascade testing as its own systems-level intervention; CDC tier-1 conditions overview; APOE/Alzheimer's risk disclosure (REVEAL has enough material to anchor an entry on whether to test for things you can't treat).

Editorial tension noted. The Manchanda 2018 cost-effectiveness model for population BRCA screening would, if fully adopted, push action toward do for women ≥30. The article lands conservatively on decide because that's the current USPSTF position and because the model's assumptions about follow-through rates may not generalize. If population screening becomes guideline-endorsed in the US, this entry should be re-scoped.

Voice check. Pulled back twice from inline trial-design jargon (named arms, hazard ratios in body text) into science callouts and parenthetical anchors. The "felt experience leads, citations hedge" rule was the hardest one to honor in the evidence section, where the numbers are the argument; resolved by anchoring each headline number in a person ("the woman whose mother and aunt…", "a 47-year-old man in a parking lot").