Heavy Metal Index

Peanut Butter

6 min read

Product evidence pageFruits, Vegetables, and Produce

Evidence Summary

This page summarizes what cited Heavy Metal Index sources report for this product category: metals covered, measured values, regulatory context, and evidence gaps.

Technical extraction details may appear below for traceability, but public pages do not publish HMT&C standards, candidate limits, or certification thresholds. Internal percentile, confidence, and regulatory-ceiling decisions belong in the staff standards workbench.

Evidence status
Modeled or limited evidence
Source coverage
5 cited sources
Population
General Population
Updated
May 16, 2026
Metals coveredAlNiPb

Peanut Butter

Peanut butter sold as creamy, crunchy, natural, conventional, or single-ingredient. Contaminated row of the Row 14 / Row 15 / Row 16 triplet: inherits the row 10 peanut platform (Al, Ni) from whole-peanut → ground-butter inheritance. Cross-row CC anchor: Step 1 defaults to the tighter of row 14 (other butters) or row 10 (whole peanuts) on a per-metal basis.

This page is a Step 0 lock scaffold for Cat 4 Row 15. Literature evidence will be populated as routed source pages accumulate per the synthesis workflow in CLAUDE.md Part 9. The Step 0 lock document at Category4_Step_0_Output_LOCKED.md is the canonical reference for the row’s clean-vs-contaminated framing and platform attribution.

Who this page is for

Brand legal teams evaluating HMTc Cat 4 certification for the Peanut Butter row need to know what the cited literature reports per panel metal, what the applicable regulatory caps are, and how this row relates to its clean-contaminated pair (when applicable). Retailer compliance teams stocking the produce, dried-goods, and snack aisles need the row-level assortment-eligibility view. HMT&C certification thresholds for products in this row are developed under the certification program at heavymetaltested.com, not on this page.

Methodology

This page reports what the cited sources say about heavy-metal concentrations in the Peanut Butter row. Speciation is non-substitutable per CLAUDE.md Part 14 (iAs vs tAs, MeHg vs tHg, Cr-VI vs total Cr). Basis is preserved (as-sold or as-consumed depending on the product form). Non-detect handling follows each source’s convention. Pooling avoided across LOD/LOQ, period, geography, and analytical-basis differences. HMT&C certification thresholds for products in this row are developed under the certification program at heavymetaltested.com, not on this page; this public page reports literature evidence only.

Cat 4 lock empirical basis: Pass 2 occurrence-data extraction from the heavymetalindex.com wiki corpus (build claude/zealous-bhabha-d422c9, 896 source pages). The Step 0 lock document at Category4_Step_0_Output_LOCKED.md records the splitting decisions and platform attributions; this row inherits its scope from that document.

Pair relationship + platform attribution

This is the contaminated row of a Cat 4 clean-contaminated split. The clean counterpart is Row 14 (Nut and Seed Butters, Other). The categorical metal-load difference is attributable to platform ingredient(s) carrying load on Al, Ni. Cross-row platform coordination per the Cat 4 Step 0 lock: the Standards Workbench’s CC anchor for each platform is shared across all rows that share the platform, with per-row final limits diverging based on commercial-product variation.

Literature Evidence Summary

Pending: regenerated by tools/evidence/apply-product-hmtc-evidence-summaries.mjs once sources route to this row and the pooling engine emits aggregate rows. Row 15 of the Cat 4 Step 0 lock is currently in scaffold state pending corpus routing of Cat 4 papers (892 source pages in the corpus as of 2026-05-16, ~52 of 128 Cat 4 cells have usable literature evidence occurrence data per the Pass 2 report).

Source Evidence Inventory

_Hand-curated section. Populated by the synthesis pass as Cat 4 sources route to this row. Initial scaffold state: zero contributing sources. The Cat 4 corpus search prioritizes sources reporting concentration data on the specific commodity in this row; broad-scope produce surveys are filed under the master.

Broad Product Context: Author-Scope Index

Pending: regenerated by tools/evidence/apply-product-broad-context.mjs once broad-scope Cat 4 sources route to this page.

Federal/Regulatory Limits vs Field Findings

Pending. Cat 4 regulatory landscape: Codex GSCTFF and EU Regulation 2023/915 set finished-product limits on fruits and vegetables (Pb, Cd) and on specific commodities (e.g., spinach Cd at 0.20 mg/kg per eu-2023-915); FDA Closer-to-Zero applies to infant fruit purées (Cat 1, not Cat 4) but informs the regulatory baseline; California Prop 65 covers cumulative Pb/Cd exposure across produce categories. Awaiting agency-page ingest.

Levers to reduce contamination

The Cat 4 Step 0 lock framework distinguishes lower-contamination row produce/seed rows from contaminated-platform commodity rows (where species or production system carries elevated metal load by characteristic). For this row, the levers below are ordered by impact magnitude per the literature evidence base; sourcing-and-agronomic levers dominate the per-product metal load, with processing-and-formulation levers offering additional reduction.

  1. Sourcing levers (highest impact): supplier and origin-region selection for the platform commodity. Within-species variance by origin region is documented in the literature; pre-screened low-impurity supply is commercially available.
  2. Agronomic levers: soil amendments (Cd accumulation in spinach/sunflower is reducible via soil-pH and silicon-amendment interventions documented in phytoremediation literature; geocarpic Al uptake in peanuts responds to soil-Al management).
  3. Cultivar/varietal selection: where within-species variance is documented, low-accumulating cultivars are commercially viable.
  4. Processing levers where applicable: rinsing, hulling, blanching may reduce surface-bound metal load on whole-seed/whole-bean formats; refining-grade differences for butter formats.
  5. Formulation levers: reduce the platform-commodity fraction of multi-ingredient products where function permits.
  6. Testing/QC levers: lot-level ICP-MS on raw commodity and finished product. Cat 4 supply chains routinely COA at the µg/kg level for premium-spec commodity.
  7. Regulatory levers (not brand-controllable): supporting Codex and state-level fruit/vegetable Pb/Cd limits drives industry-wide tightening.

How standards math uses this page

The percentile arithmetic that informs HMTc Cat 4 thresholds for this row lives on the staff Standards Workbench (data/workbench/standards/peanut-butter.md, to be generated). This public page reports literature evidence; the workbench applies the Cat 4 methodology (which includes the literature evidence occurrence-data-driven derivation and below-LOQ regulatory-floor fallback per the Step 0 lock) to produce candidate threshold values. The gap between literature evidence and HMTc thresholds is named honestly on the workbench, not hidden.

Historical recalls and enforcement

Cat 4 (produce, nuts, seeds) regulatory enforcement intersects two domains: heavy-metal contamination (the focus of this row) and microbial contamination (FDA recall notices for E. coli/Salmonella/Listeria in fresh produce, a separate concern). FDA Total Diet Study and Pesticide Data Program surveillance reports establish the heavy-metal occurrence baseline (FDA 2022). State-level Cd-in-leafy-greens enforcement has been active in California under Prop 65; the related Mateel Environmental settlement framework has shaped compliance practice. Per CLAUDE.md Part 12, individual brand recall actions are not enumerated here.

Sources

Auto-generated from source-page frontmatter. The “Used on this page for” column is populated by the orchestrator’s POPULATE-SOURCE-LEGEND action; pending entries appear as *[awaiting synthesis]*.

#CitationYearTypeUsed on this page for
1Schaefer et al. 2020. Cadmium: Mitigation strategies to reduce dietary exposure, Journal of Food Science2020Review[awaiting synthesis]
2FDA 2016. Analytical Results from Inorganic Arsenic in Rice Cereals for Infants, Non-Rice Infant Cereal and Other Foods Commonly Eaten by Infants and Toddlers, U.S. Food and Drug Administration2016Government datasetUS-FDA iAs, tAs concentrations (n=415)
3EFSA 2015. Scientific Opinion on the risks to public health related to the presence of nickel in food and drinking water, EFSA Journal 2015;13(2):4002, 202 pp.2015Government report[awaiting synthesis]
4Baxter et al. 2015. Total Diet Study of metals and other elements in food, Food and Environment Research Agency report for the UK Food Standards Agency, Fera report 15/06, project FS1020812015Government report[awaiting synthesis]
5Hovanec 2004. Arsenic speciation in commercially available peanut butter spread by IC-ICP-MS, Journal of Analytical Atomic Spectrometry2004Peer-reviewedUS tAs, iAs occurrence in Commercially available peanut butter products purchased at US retail (grocery and gourmet stores), plus NIST SRM 2387 (n=6)

Page history

The five most recent substantive edits to this page. The full version history lives in git; when DOI minting comes online (see schema docs), each entry below will also link to a version-pinned DataCite DOI.

CommitDateDescription
ce3e07c2026-05-28activation | Vercel DATACITE env slots set, curators.md filled with founder entry + six scoped reviewer invitations, peer-review onboarding playbook drafted
51400b92026-05-28audit-queue: gasparik2017-wild-boar-slovakia-metals audited-revised