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Ingredient class — vitamin/mineral (single, multi-mineral, multi-vitamin/mineral)

This page is a scaffolded entry for HMTc Taxonomy v2.0 Category 16 (Dietary Supplements (Human)), Row 14: Ingredient class — vitamin/mineral (single, multi-mineral, multi-vitamin/mineral).

Researched by
K. Pendergrass iD
Last updated: 2026-05-17
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2 corpus sources
Reconstructable record

Ingredient class — vitamin/mineral (single, multi-mineral, multi-vitamin/mineral)

This page is a scaffolded entry for HMTc Taxonomy v2.0 Category 16 (Dietary Supplements (Human)), Row 14: Ingredient class — vitamin/mineral (single, multi-mineral, multi-vitamin/mineral). Evidence ingest into this row is in progress; this page is the routing destination for source-page declarations of products: [supplements-vitamin-mineral]. Sections below are populated by the routing layer (CLAUDE.md Part 5b) as sources land. Where a section is empty, the row has not yet accumulated contributing sources of the required kind.

Literature scope

The Heavy Metal Index source corpus is currently focused on food and food-contact materials. This page documents an HMTc Taxonomy v2.0 row in the category Dietary Supplements (Human) for which no peer-reviewed primary or government sources have yet been ingested. The page exists as the routing destination for future ingest. Until sources land, the literature-evidence sections below are deliberately empty rather than guessed; HMTc certification thresholds for products in this row continue to be developed under the certification program at heavymetaltested.com, not on this public page.

Who this page is for

Brand legal teams
What the peer-reviewed and regulatory literature reports for heavy-metal occurrence in Ingredient class — vitamin/mineral (single, multi-mineral, multi-vitamin/mineral), with applicable regulatory caps and source-traceable findings. Use this page to evaluate certification or class-action exposure on a literature-anchored basis.
Brand regulatory affairs / QA
The current evidence base for Ingredient class — vitamin/mineral (single, multi-mineral, multi-vitamin/mineral), the levers most-effective at reducing heavy-metal load, and the applicable regulatory limits with jurisdiction and basis.
Retailers and category buyers
The row-level assortment risk profile and where the literature distinguishes higher-risk from lower-risk product configurations within this row.
HMT&C staff (internal)
HMT&C certification thresholds for products in this row are developed under the certification program at heavymetaltested.com, not on this public page. The Index and HMT&C operate on the same evidence base but apply different publication rules; see the methodology for the separation.

Methodology

This page reports what the cited sources say about heavy-metal concentrations in ingredient class — vitamin/mineral (single, multi-mineral, multi-vitamin/mineral). Speciation is non-substitutable per CLAUDE.md Part 14 (iAs vs tAs, MeHg vs tHg, Cr-VI vs total Cr). Basis is preserved (finished-product as sold unless the source specifies otherwise; see each row for the basis label). Non-detect handling follows each source’s reporting convention. Pooling is 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.

The applicable regulatory jurisdictions for this row are: FDA (DSHEA), USP, California Prop 65.

Literature Evidence Summary

Pending ingest. The routing layer will surface direct-row-fit sources here as they are added to the corpus with products: [supplements-vitamin-mineral] in source-page frontmatter.

Source Evidence Inventory

Pending ingest. The routing layer populates this section from the source-page set declaring products: [supplements-vitamin-mineral].

Broad Product Context: Author-Scope Index

Pending ingest. The routing layer surfaces sources whose author-stated scope is broader than this row (route_kind: broad_product_context) as they are added.

Federal/Regulatory Limits vs Field Findings

Pending ingest. The applicable regulatory jurisdictions for this row are recorded in the page frontmatter; the crosswalk table is generated by tools/apply-product-crosswalk-sections.mjs once regulation pages and field-evidence sources are routed to this row with structured limit values.

Levers to reduce contamination

Practical interventions to reduce heavy-metal load in this row, ordered by impact magnitude. Each lever names the magnitude of the effect with a cited source; cross-links to dedicated Mitigation pages where they exist.

How standards math uses this page

HMT&C certification thresholds for this row are developed under the certification program at heavymetaltested.com, not on this page. The row-standard for this row is an aggregate computed from the contributing source pool in the row’s native finished-product basis; it is not a per-source decoration of any single value cited on this page. This public page reports literature evidence only.

Historical recalls and enforcement

Pending ingest. Regulatory events (recalls, enforcement actions, import alerts) relevant to this row will be added as agency records are ingested into the corpus.

Sources

Pending ingest. The Source Legend below is auto-generated by tools/evidence/build-source-legend.mjs once source pages declaring products: [supplements-vitamin-mineral] are added.

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
1Porwollik et al. 2026. The quality and safety of Rhodiola rosea supplements on the U.S. market: An analysis of biomarkers, heavy metals, and pesticide residues, PLoS One2026Peer-reviewedUS Pb, Cd, tAs, tHg occurrence in Ten commercially available Rhodiola rosea supplement products (7 capsular, 3 tinctures) purchased on the U.S. market in 2024 (n=10)
2Barber et al. 2025. Toxic elements in baby and young children’s foods in the US and correlation to ingredients, Food Additives & Contaminants: Part B2025Peer-reviewedUS tAs, iAs, Cd, tHg, MeHg, Pb, Tl occurrence in Non-targeted 2023 FDA convenience survey of 566 foods intended for babies, young children, pregnant women, and nursing mothers:… (n=566)
3Gao et al. 2025. Wild Cordyceps sinensis exhibits far lower arsenic accumulation and hepatorenal toxicity in mice compared to equivalent dose of inorganic arsenic, Frontiers in Pharmacology2025Peer-reviewedCN tAs, iAs occurrence in Eighteen CD-1 mice assigned to control, wild Cordyceps sinensis, and inorganic arsenic groups. (n=18)
4Sochacka et al. 2025. Spirulina and Chlorella Dietary Supplements—Are They a Source Solely of Valuable Nutrients?, International Journal of Molecular Sciences2025Peer-reviewedPL/EU Al, Ba, Cd, Co, Cr, Cs, Cu, Ga, Mn, Mo, Ni, Pb, Rb, Sr, Tl, V, Zn occurrence in 52 commercially available microalgae-based dietary supplements sold on the Polish market: 29 Spirulina (Spirulina platensis) products and 23… (n=52)
5Brodziak-Dopierała et al. 2024. Mercury Levels in Selected Medicines and Dietary Supplements in Poland, Biological Trace Element Research2024Peer-reviewedPL tHg occurrence in 139 pharmaceutical preparations (75 prescription and OTC drugs, 64 dietary supplements) purchased from pharmacies, drugstores, hypermarkets, and online… (n=139)
6Thomas et al. 2024. Case of lead poisoning secondary to intake of herbal medicine for diabetes mellitus in a tertiary care hospital in Kerala, Endocrinology, Diabetes & Metabolism Case Reports2024Peer-reviewedIN Pb occurrence in Single clinical case: 58-year-old female with lead poisoning from Ayurvedic herbal diabetes capsules, Jubilee Mission Medical College, Kerala,… (n=1)
7Torović et al. 2024. Mercury Content in Fish Oil Food Supplements and Associated Health Risk, Proceedings 2023, 91, 364 (MDPI Proceedings — 14th European Nutrition Conference FENS 2023)2024Conference proceedingsRS/BA tHg occurrence in 42 fish oil food supplements available on the markets of the Republic of Serbia and the Republic of… (n=42)
8Abuawad et al. 2023. The Folic Acid and Creatine Trial: Treatment Effects of Supplementation on Arsenic Methylation Indices and Metabolite Concentrations in Blood in a Bangladeshi Population, Environmental Health Perspectives2023Peer-reviewedBD iAs, tAs occurrence in Bangladeshi adults aged 20-65 years with household well-water arsenic concentrations above 50 ug/L for at least one year (n=622)
9Fuckar et al. 2023. Coffee Silver Skin-Health Safety, Nutritional Value, and Microwave Extraction of Proteins, Foods2023Peer-reviewedHR Ni, Pb, tAs, Cd, Cr, Cu, Zn, Mn, Fe occurrence in One homogenized coffee-silverskin by-product sample from Croatian coffee roasting, analyzed in six parallel probes for reported heavy-metal concentrations. (n=1)
10Brodziak-Dopierała et al. 2023. Mercury Exposure from the Consumption of Dietary Supplements Containing Vegetable, Cod Liver, and Shark Liver Oils, International Journal of Environmental Research and Public Health2023Peer-reviewedPL/EU tHg occurrence in 36 dietary supplement preparations purchased in Poland (pharmacies, drugstores, herbal shops): 18 vegetable oils (cold-pressed and unrefined), 12… (n=36)
11Brzezinska-Rojek et al. 2023. Evaluation of the Safety and Potential Benefits of Beetroot-Based Dietary Supplements According to Their Elemental Composition, Biological Trace Element Research (published online 7 October 2023)2023Peer-reviewedPL Cd, Pb, Al occurrence in 37 beetroot-based dietary supplements (10 tablets, 14 capsules, 13 powders) from Polish market (online and in-person shops); products… (n=37)
12Nelson et al. 2022. Determination of Heavy Metals in a Variety of Cannabis and Cannabis-Derived Products, First Action 2021.03, Journal of AOAC INTERNATIONAL2022Peer-reviewedUS/CA tAs, Cd, tHg, Pb occurrence in Four cannabis/cannabis-derived validation matrices with native As, Cd, Hg, and Pb values in Table 5: flower (inhaled), hemp… (n=4)
13Cheyns et al. 2021. Intake of food supplements based on algae or cyanobacteria may pose a health risk due to elevated concentrations of arsenic species, Food Additives & Contaminants: Part A2021Peer-reviewedBE tAs, iAs occurrence in Thirty-three food supplements containing algae and/or cyanobacteria purchased from local stores and online stores in Belgium during 2013-2016;… (n=33)
14Ciocan et al. 2021. Lead poisoning from Ayurvedic treatment: a further case, La Medicina del Lavoro2021Peer-reviewedIT/IN Pb, tHg, tAs occurrence in Single case: 30-year-old Indian sailor treated in Italy; ICP-MS analysis of 4 Ayurvedic drug product samples (products 1,…
15Liu et al. 2021. Discovery and Identification of Arsenolipids Using a Precursor-Finder Strategy and Data-Independent Mass Spectrometry, Environmental Science and Technology2021Peer-reviewedCA tAs occurrence in Krill oil capsules, tuna fillets, hairtail fish heads, and kelp purchased from retail markets in Edmonton (Canada) and… (n=4)
16Viviers et al. 2021. An assessment of heavy metal contaminants related to cannabis-based products in the South African market, Forensic Science International: Reports2021Peer-reviewedZA Cd, Pb, tAs, tHg, Co, V, Ni, Tl, Au, Pd, Ir, Os, Rh, Ru, Se, Ag, Pt occurrence in Three hundred ten cannabis-based products submitted to a South African contract laboratory, grouped as edible, extract, infusion, liquid,… (n=310)
17Wang et al. 2021. AGNH Protects Against Cinnabar and Realgar-Induced Hepatorenal Toxicity in Mice via Attenuation of Oxidative Stress, Inflammation, and Apoptosis, Frontiers in Pharmacology2021Peer-reviewedCN tHg, tAs, iAs occurrence in Mice (ICR strain) administered cinnabar (HgS) and realgar (As4S4) orally as part of traditional Chinese medicine formulation safety…
18Falandysz et al. 2020. Mercury in traditionally foraged species of fungi (macromycetes) from the karst area across Yunnan province in China, Applied Microbiology and Biotechnology2020Peer-reviewedCN tHg occurrence in Composite samples from 42 traditionally foraged or medicinal fungal species collected at 23 sites across Yunnan province, China,…
19Jairoun et al. 2020. Heavy Metal contamination of Dietary Supplements products available in the UAE markets and the associated risk, Scientific Reports2020Peer-reviewedAE Cd, Pb, tAs occurrence in 277 dietary supplement products collected by random selection from the UAE market (pharmacies, para-pharmacies, nutrition shops). Categories: 43.7%… (n=277)
20Liu et al. 2018. Speciation and bioaccessibility of arsenic in traditional Chinese medicines and assessment of its potential health risk, Science of the Total Environment2018Peer-reviewedCN tAs, iAs occurrence in Twenty-four Chinese patent medicines and sixty Chinese herbal medicines purchased from a Beijing drugstore. The patent medicines included… (n=84)
21Bolan et al. 2017. Comparative analysis of speciation and bioaccessibility of arsenic in rice grains and complementary medicines, Chemosphere2017Peer-reviewedAU/BD/IN tAs, iAs occurrence in Six rice-grain samples from research grain collections in Bangladesh, India, and Korea, grown under greenhouse or field conditions… (n=22)
22Li et al. 2017. Determination of different arsenic species in food-grade spirulina powder by ion chromatography combined with inductively coupled plasma mass spectrometry, Journal of Separation Science2017Peer-reviewedCN tAs, iAs occurrence in Food-grade spirulina powder samples purchased at production sites in seven Chinese provinces: Yunnan, Hainan, Guangxi, Fujian, Inner Mongolia,… (n=7)
23Sattler et al. 2016. Essential minerals and inorganic contaminants (barium, cadmium, lithium, lead and vanadium) in dried bee pollen produced in Rio Grande do Sul State, Brazil, Food Science and Technology2016Peer-reviewedBR Ba, Cd, Pb, V, Cr, Cu, Fe, Mn, Mo, Zn occurrence in Five unprocessed bee-pollen samples from Rio Grande do Sul State, Brazil, collected in August-October 2011 and analyzed as… (n=5)
24Coghlan et al. 2015. Combined DNA, toxicological and heavy metal analyses provides an auditing toolkit to improve pharmacovigilance of traditional Chinese medicine (TCM), Scientific Reports 5:174752015Peer-reviewedAU tAs, Pb, Cd occurrence in Twenty-six traditional Chinese medicine products audited in Australia; 25 screened for heavy metals by SF-ICP-MS because one aqueous… (n=26)
25Cao et al. 2014. Pharmacokinetic properties of arsenic species after oral administration of Sargassum pallidum extract in rats using an HPLC-HG-AFS method, Journal of Pharmaceutical and Biomedical Analysis2014Peer-reviewedCN tAs, iAs occurrence in One dried Sargassum pallidum material collected from Yantai City, Shandong Province, China, identified by the corresponding author, deposited… (n=1)
26Al-Dhabi 2013. Heavy metal analysis in commercial Spirulina products for human consumption, Saudi Journal of Biological Sciences2013Peer-reviewedAU/US/JP Ni, Zn, tHg, Pt, Mg, Mn occurrence in Twenty-five commercially available Spirulina dietary supplements in tablet (n = 16) and capsule (n = 9) forms, with… (n=25)
27EFSA 2012. Cadmium dietary exposure in the European population, EFSA Journal 2012;10(1):25512012Government reportEU Cd occurrence in Cadmium occurrence results in food submitted to EFSA from 22 EU Member States, 3 European Economic Area or… (n=178541)
28Uneyama et al. 2007. Arsenic in various foods: Cumulative data, Food Additives & Contaminants2007Peer-reviewedJP/US/GB tAs, iAs occurrence in Cumulative review of arsenic measurements in food from PubMed, Japanese local-authority research databases, and national food-safety surveillance reports;…

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
ae6c1292026-07-01feat(auth): large login + role-based signup screens (design, burgundy)