Toxic Metals in a Green Transition: Global Health Risks, Sources, and Policy Responses—Insights from the Munich Toxic Metals Symposium 2025

Stephan Bose-O'Reilly; Stefan Rakete; Philip J. Landrigan; Johanna Elbel; Monica Nordberg; Gunnar Nordberg; Karin Broberg; Dewi Yunia Fitriani; Jenna Forsyth; Joanna Gaitens; Jinky Leilanie Lu; Dennis Nowak; Ernesto Sanchez-Triana; Sophie Turner; John Yabe; Melissa McDiarmid; Florencia Harari

doi:10.5334/aogh.5214

Toxic Metals in a Green Transition: Global Health Risks, Sources, and Policy Responses—Insights from the Munich Toxic Metals Symposium 2025

Volume 92 (2026): Issue 1

By: Stephan Bose-O'Reilly, Stefan Rakete, Philip J. Landrigan, Johanna Elbel, Monica Nordberg, Gunnar Nordberg, Karin Broberg, Dewi Yunia Fitriani, Jenna Forsyth, Joanna Gaitens, Jinky Leilanie Lu, Dennis Nowak, Ernesto Sanchez-Triana, Sophie Turner, John Yabe, Melissa McDiarmid and Florencia Harari

Open Access

|Apr 2026

Figures & Tables

Table 1

Summary of key toxic metals, main sources, and primary health effects.

METAL	MAIN SOURCES	PRIMARY HEALTH EFFECTS
Lead (Pb)	Recycling of used lead‑acid batteries, legacy mining, contaminated soil and paint, small aircraft fuel, commodity products	Cardiovascular mortality, Neurodevelopmental impairment, kidney disease
Mercury (Hg)	Artisanal and small‑scale gold mining (ASGM), fish consumption, industrial emissions, coal burning	Cognitive deficits, kidney toxicity, cardiovascular disease, neurological symptoms
Arsenic (As)	Drinking water, mining and smelting, e‑waste	Cancers of the skin, bladder and lung, skin lesions other than skin cancer, spontaneous abortion, stillbirth, infant mortality, congenital heart disease, respiratory disease, chronic kidney disease, neurodevelopmental effects, ischemic heart disease and carotid artery atherosclerosis
Cadmium (Cd)	Mining, battery recycling, fertilizers	Kidney dysfunction, osteoporosis, cancer, cardiovascular disease
Uranium (U)	Mining, processing, military	Kidney dysfunction, cancer
Chromium (Cr)	E‑waste, tanning, metal plating	Neurodevelopmental issues, stomach cancer
Nickel (Ni)	Battery recycling, mining, refining	Dermatitis, occupational asthma, cancer
Cobalt (Co)	Battery recycling, mining, refining	Dermatitis, occupational asthma, cancer
Lithium (Li)	Battery recycling, mining, refining	Irritation of airways and skin, reproductive effects

Sources: References [49, 51–54].

Table 2

Roadmap for mitigating toxic metal hazards.

LEVEL	KEY ACTIONS	STAKEHOLDERS
Foundational Prevention	Systematically monitor exposures and health outcomes; apply the precautionary principle; strengthen surveillance in high‑risk sectors	National governments, work environment, public health and environment agencies, research institutions, industry
Sustainable Production and Regulation	Protect workers by promoting cleaner mining, smelting, and recycling technologies; harmonizing health‑based standards; formalizing informal workers; strengthening enforcement	Governments, industry, labor organizations, NGOs
Equitable Community Protection	Protect communities by expanding community engagement; ensuring social protection for vulnerable groups; investing in surveillance technologies and early‑warning systems	Local authorities, community groups, Indigenous organizations
Long‑term Governance and Global Cooperation	Adopt due‑diligence laws; integrate toxic‑metal monitoring into climate finance; establish reference guidelines; pursue multilateral agreements	International bodies, regional blocs, national governments

ADME	(Absorption, distribution, metabolism, and excretion)
As	Arsenic
ASGM	Artisanal and small‑scale gold mining
ASM	Artisanal and small‑scale mining
ASQ‑3	Ages and stages questionnaire
BLL	Blood lead level
Cd	Cadmium
CDC	Centers for Disease Control and Prevention
Co	Cobalt
Cr VI	Hexavalent chromium
Cr	Chromium
CR	Corporate responsibility
CSDDD	Corporate Sustainability Due Diligence Directive
CVD	Cardiovascular disease
DBS	Dried blood spot
EHIA	Environmental and health impact assessment
EV	Electric vehicle
Ge	Germanium
GGT	Gamma‑glutamyl transferase
Hb	Hemoglobin
Hg	Mercury
HIC	High‑income country
IIEF	International Index of Erectile Function
In	Indium
IQ	Intelligence quotient
LDH	Lactate dehydrogenase
Li	Lithium
LiB	Lithium‑ion battery
LMIC	Low‑ and middle‑income country
NGO	Non‑governmental organization
Ni	Nickel
Pb	Lead
PPE	Personal protective equipment
qDBS	Quantitative dried blood spot
REE	Rare earth elements
SDG	Sustainable development goal
U	Uranium
ULAB	Used lead‑acid battery
UN	United Nations
VAMS	Volumetric absorptive microsampling
WHO	World Health Organization
XRF	X‑ray fluorescence
mg/kg	Milligram per kilogram
µg/L	Microgram per liter
µg/dL	Microgram per deciliter
µg/g	creatinine microgram per gram creatinine
µL	Microliter
mmol/L	Millimole per liter
ng/dL	Nanogram per deciliter

Articles in this issue

DOI: https://doi.org/10.5334/aogh.5214 | Journal eISSN: 2214-9996

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Language: English

Submitted on: Feb 10, 2026

Accepted on: Mar 10, 2026

Published on: Apr 7, 2026

Published by: Ubiquity Press

In partnership with: Paradigm Publishing Services

Publication frequency: 1 issue per year

Keywords:

green transition,

critical raw materials,

lithium,

cobalt,

nickel,

lead,

mercury,

uranium,

health,

policy interventions,

occupational & environmental safety

© 2026 Stephan Bose-O'Reilly, Stefan Rakete, Philip J. Landrigan, Johanna Elbel, Monica Nordberg, Gunnar Nordberg, Karin Broberg, Dewi Yunia Fitriani, Jenna Forsyth, Joanna Gaitens, Jinky Leilanie Lu, Dennis Nowak, Ernesto Sanchez-Triana, Sophie Turner, John Yabe, Melissa McDiarmid, Florencia Harari, published by Ubiquity Press
This work is licensed under the Creative Commons Attribution 4.0 License.

Volume 92 (2026): Issue 1