v -
Jakse dnes mate? (... a proc?)
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M U N I   R E C E T O X
Úvod do problému chemického znečištění
Jakub Hofman
Seminář
7.10.2024
U IM I   R E C E T O X
člověk -> chemické latky chemické látky -> člověk
Je všechno kolem nás JEN chemie ?
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Všechno kolem nás je chemie... (?)
u
https://www.whatsinsidesciohnson.com/ us/en/evervthing-is-chemistrv-posters
IV*^      Rte AOO
o
en      eu e
U Iv"*
-V
.JO"
IPolyphcnoIs I »Typcs of cpnípounds
ElcnxTii.il compomion
Chemické látky
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Kolik (řádově) chemických látek zná lidstvo?
deset tisíc	
sto tisíc	
milion	
deset milionů	
... o sto milionu	
ani jedna odpověďnení správně	
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UNI RECETOX
Chemické látky
50,000,000 40,000,000 30,000,000 20,000,000 10,000,000
svět kolem nás = chemie (známe > 100 mil. chemických látek)
www.cas.org       i JÉŽIffU^
UNI RECETOX
CAS DATA
The largest human-curated collection of scientific data in the world, the CAS Content Collection, underpins all of our solutions and relevant data that can be licensed for machine learning and in-house workflow integration.
contact us
CAS REGISTRY®
The authoritative source for tchemical substance data
CAXREGISTRY is the standard sou rebelled upon by scientists, manufacturers, regulators, and data scientists 1'Vldwide for accurate and completeVfomnation on chemical substarVes and sequences. Contairmig chemical names, structures, CA\Reqistry
ri a™
Mother data for morethan*279 jnillion registered substances, CAS^ INI 'inn ii ilh Iniliiiriliii Content Collection.
CAS Refe
Insights frc of publishc literature
The CAS refe aggregates ai knowledge t< journals and (
published glc languages da '830;
Chemické látky
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Kolik chemických látek (řádově) vyrábíme a používáme?
sto	
tisíc	
deset tisíc	
sto tisíc	
milion	
ani jedna odpověďnení správně	
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UNI RECETOX
8
Chemické látky
lidstvo v rámci svých aktivit vyrábí a používá > 100 000 látek
ECHA > Information on Chemicals > EC Inventory
rxECHA
HUROPHAN C H E M I CA L 5 AGENCY
EC Inventory
The EC inventory published below is a copy as received from the JRC in 2003 on the founding of ECHA. It is comprised of the following lists:
■ einecs (European INventory of Existing Commercial chemical Substances) as published in O.J, C 146A, IS.6.1990. EINECS is an inventory of substances that were deemed to be on the European Community market between 1 January 1971 and IS September 1931. EINECS was drawn up by the European Commission in the application of Article 13 of Directive 67/54S/EEC, as amended by Directive 79/S31/EEC, and in accordance with the detailed provisions of Commission Decision 31/437/EEC. Substances listed in EINECS are considered phase-in substances under the REACH Regulation.
■ elincs (European List of Notified Chemical Substances) in support of Directive 92/32/EEC, the 7th amendment to Directive 67/543/EEC. ELINCS lists those substances which were notified under Directive 67/548/EEC, the Dangerous Substances Directive Notification of New Substances (NONS) that became commercially available after 13 September 1981.
■ nlp (No-Longer Polymers). The definition of polymers was changed in April 1992 by Council Directive 92/32/EEC amending Directive 67/543/EEC, with the result that substances previously considered to be polymers were no longer excluded from regulation. Thus the No-longer Polymers (NLP) list was drawn up, consisting of such substances that were commercially available between 13 September 1981 and 31 October 1993.
Last updated 11 August 2017. Database contains 106211 unique substances/entries.
>   Filter the list
Page L of 2rL25   t        50 Items per Page   t      Shovjing 1 - 50 #F 10&F21 1 resultJ
— First Previous Ne>ct Last—*
Name A	EC no.	CAS no.	Molecular Formula	Description
"mercurous oxide"	239-934-0	15829-53-5	Hg20	
((2-ethyl-l-oxohexyl)oxy)-( 1-phenyl -1,3-decanedionyl)dioctyl stannane RHODORSIL ACCELERATEUR 2025	422-920-5			RHODORSIL ACCELERATEUR 2025
((4-phenylbutyl)hydroKyphosphoryl)a<=etic 412-170-7 acid
SQ_ 26999
Člověk vždy používal ChL, produkoval odpad a čelil následkům
skládky odpadu známé již ze starověku olověná potrubí v římském impériu
průmyslová revoluce - drastický nárůst produkce ChL a produkce odpadu
polovina 18. století-znečištění ovzduší, londýnský smog, nemoci
začátek 19. století - zpracování nafty, produkce organických chemikálií, umělá hnojiva, olovo do benzínu, kovy v elektronice
polovina 19. století - boom pesticidů - green revolution é^JJIM^Íj
od 60. let - zlepšení nakládání s odpady, legislativa
od 70. a 80. let environmentálni legislativa, regulace ChL
produkce ChL a odpadu stále roste s růstem populace a GDP
£ECha ř efsa
I RECETOX
EUROPEAN CHEMICALS AGENCY
European Food Safety Authority
Produkce chemických látek roste
Figure 6.13. Projected chemicals production by region (in sales):
Baseline, 2010-2050
současnost
2010
Billions oF 2007 USD
World
0ECD
2030
BRIICS
■ 2050
World chemicals sales (€3,534 billion)
1			
1			
1	■ 1	.1	
Rest of Europe
O
Japan A.     south Korea
O
Latin America
Rest of theworld
Source: CEFIC ChemData International 2016-
OECD (2012)
MUNI RECETOX
11
Bhopal
https://www.csfd.cz/film/2533 47-bhopal-modlitba-za-dest
továrna společnosti Union Carbide, výroba pesticidů pro Indii
2-3.12.1984 havárie zásobníku methylisokyanátu^
mrak vysoce toxického plynu těžšího než vzduch - MIC, CO, NOx, HCN, MMA, C02, COCI2 ... (~ 42 tun)
> 8000 úmrtí během týdne f0S9en
100-200 tisíc osob s trvalými zdravotními následky
~- íľtWtRMiBHlN
N
O
UNI RECET
aiHTioNBňW6r«rjr//^
(2005)
12
Seveso
RIP
x 106
10.7.1976 únik chemikálií z továjTTyja-výro&ú pesticidu cca 6 tun chemikálií s cca 1 kg 2,3,7,8-TCDD (LD50 0,6 u.g/kg !!) zamoření oblasti cca 18 km2
37.000 lidí s následky otravy Ck ^ XL ^ .Cl
D/WFT0 Dl ACCESSD
ňllt PfflSBNf NON MBMIAU
[ TUASGRESSOFI unono d«f»rrc ■UAutnnu auditu™ <i mm dtil Art SM C J"
UNI RECETOX
V. Yushchenko 2024
Eskenazi et al. (2018)
Další chemické katastrofy
Minamata 1950's Love Canal 1950's Agent Orange 1961-71 Chernobyl 1986 Exxon Valdez 1989 Gulf war 1991 Deepwater Horizon 2010 Fukushima 2011
■ desítky dalších ...
https://en.wikipedia.org/wiki/List of industrial disasters
UNI RECETOX
CHERNOBYL
14
nejen katastrofy ... kontaminovaná místa
■ v EU až 3,5 mil kontaminovaných míst, 0,5 mil vážně
■ v ČR kolem 10 tisíc kontaminovaných míst http://www.sekm.cz/
■ USA - superfund sites
nejen katastrofy ... kontaminovaná místa
Blacksmith Institute (2006)
MUNI RECETOX
httDs://www.thouahtco.com/worst-Dolluted-Dlaces-on-earth-1204101 https://www.livescience.com/30353-most-polluted-Dlaces-earth.html https://www.scientificamerican.com/slideshow/10-most-Dolluted-places-in-the-world/
... žel management při chemických katastrofách někdy připomíná tuto parodii...
17
nejen katastrofy...
Tributylcín
■ biocid, široké využití, ná
■ uvolnění do mořských e
■ bioakumulace, metaboli
■ vliv na hormonální syste
UNI REC
EE
Early 1970s	Rapid increase in the use of TBT antifouling paints on vessels of all sizes and first reports of imposex in marine snails (Blaber, 1970; Smith, 1971)
1976-81	Repeated failure of larval settlement leads to near collapse of oyster fishery, Arcachon Bay, France
1982	France introduces legislation prohibiting the use of TBT paints on small vessels
1985	First controls introduced in United Kingdom limiting concentrations of TBT in paints
1986	Bryan eta/. (1986) report widespread imposex in dogwhelkson southern coast of United Kingdom, linked to TBT
January 1987	United Kingdom announces further restrictions on TBT content of applied antifouling paint
May 1987	United Kingdom introduces ban on retail sale of TBT paint for use on vessels < 25 m and on fish cages
June 1987	PARCOM Recommendation 87/1 calls for similar ban over entire convention area (Northeast Atlantic)
1988	United States introduces restrictions. Waldock et a/. (1988) highlight significance of inputs from shipyards
1989	Restrictions introduced in Canada, Australia and New Zealand
1991	Harmonised ban on retail sale of TBT paint introduced at European Union level
1994	Early reports of imposex in whelks from offshore areas of North Sea linked to shipping activity
1995	Ministerial declaration of fourth North Sea conference (Esbjerg) commits to working for global phase-out of TBT paint within IMO
1997	Concept of global phase out of organotin containing paints agreed at MEPC's 40th session
1998	Draft mandatory regulations aimed at such a phase-out adopted. OSPAR (Convention for the Protection of the Marine Environment of the Northeast Atlantic) prioritises organotins for action to cease all releases. Cessation of all releases of organotins to marine environment, under OSPAR's hazardous substances strategy in 2020
November 1999	Deadlines for phase-out adopted under IMO Assembly Resolution A.895(21)
2001	Text of International Convention on the Control of Harmful Anti-fouling Systems to be finalised. In 2003 worldwide prohibition on new application of organotin antifoulants to all vessels and in 2008 the existing organotin antifouling coatings will be replaced on all vessels worldwide
nejen katastrofy...
DDT
1874
Cl-
Cl
XI
Cl
Cl
1939
Paul Hermann Muller 1900
ýskyt malári
Příběhy - "Late Lessons from Early Warnings"
olovo v benzínu, MTBE v benzínu
rtuť a minamata
azbest ve stavebnictví
tributylcín
PCBs v průmyslu
freony a ozonová vrstva
antibiotika a mikrobiálni resistence
hormony a „jako"-hormony (BPA)
kauza dietylstilbestrol
kouření a rakovina
pesticidy (DDT, neonikotinoidy,)
2002
MU N I   R E C E T 0 X
https://www.eea.europa.eu/publications/late-lessons-2
https://www.eea.europa.eu/publications/environmental issue report 2001 22 20
Zpoždění legislativy za problémy ŽP
I Discovery of problem
uctlon Ongoing use      Ongoing presence
I use In some countries   In the environment
PFAS
2001 Giesy & Kannan
2009 PFOS in Stockholm Convention
2017 PFOA in
Stockholm Convention * PFAS restriction in EU
Plastics
1972
Carpenter and Smith
■
19B8 MARPOL
International Convention for
the Prevention of Pollution from Ships
UN is considering global action
CFCs
1974
Molina & Rowland
01987
Montreal Protocol
2010
End of use in developing countries
Scheringer et al. (2022): Stories of Global Chemical Pollution: Will We Ever Understand Environmental Persistence? Environmental Science & Technology 56, 17498-17501.
PCBs
DDT
1950
1969 Jensen et al
f
1362 Silent Spring
1
1960
1970
National bans
National bans
1960
1990
End of production
J.
2004
Stockholm Convention
2004
Stockholm Convention
2000
2010
2020
I 2029
Environmentally sound management under Stockholm Convention
2030
Figure  1. Time lines  of selected  global chemical pollution cases. Abbreviations:  PFAS, per-  and polyfluoroalkyl substances; CFCs, chlorofluorocarbons; PCBs, polychlorinated biphenyls. In some cases, the production and use started at lower levels before 1950, but production 11II        l\l D  t  I and use of all substances increased strongly from 1950 on. All chemicals remain in the environment for long periods of time after national or
international bans. References not cited in the text: Carson, R. Silent Spring; 1962. Carpenter, E. J.; Smith, K. L. Science 1972, 175, 1240—1241,
Ne všechny příběhy končí špatně ...
-i—> o
>
CD
LJ o
u !-
fO o
Í3 -!=
C S(L> CD
u to
o <u co
1930
Q Q
«-
o
in OJ
ť
£
o.
ro ■o
u
1940
EEA (2013)
production and release
damage in natural environment
I cause of damage emerges
Figure 6.5 DDT Levels in humans, 1960-2008
Nanograms per gram ot lipid weight (note logarithmic scale] 1000 000
100 000
10 000
1000
100 • Northern highly exposed population • Tropical highly exposed population T Tropical general population -« Northern general population 101-1-1-1-
1960
1970
1980
1990
2000
2010
UNEP (2012)
MUNI RECETOX
22
i když ... 2., 3.... dějství
OJ Ö
cd 3_
3 -+
<5 2
"O
c
cti
(55
1955
HSRs
1979 Years
[1995 1985 1992
Roberts (1997)
UNI RECETOX
Figure 6.14. Potential population at risk from malaria: Baseline, 2010-2050
H 2010 I 2030 H 2050
Sill ions of people 1
OECD (2012)
climate change
malaria
w
DDT (?)
Ne všechny příběhy končí špatně, i když ...
... setrvačnost, dohra...
1907	Laboratory experiments by Weigert on the decomposition of ozone photosensitised by chlorine
1934	Ditto by Norrish and Neville
1973	Global survey of CFCs by Lovelock etal. showing their distribution in the atmosphere worldwide
1974	Molina and Rowland publish their theoretical arguments that CFCs would be destroying the ozone layer
1977	United States bans CFCs in aerosols based on 'reasonable expectation' of damage, followed by Canada, Norway and Sweden.
1977	Research-oriented 'world plan of action on the ozone layer' agreed, overseen by UNEP
1980	European decision restricting use of CFCs in aerosols, but rising use in refrigerators, etc. marginalises this restriction
1985	UNEP Vienna Convention for the protection of the ozone layer agrees research, monitoring, information exchange and restrictions if and when justified
1985	Farman, Gardiner and Shanklin publish results showing hole in ozone layer over Antartica
1987	Montreal Protocol on protection of the ozone layer is signed, with phasing out of ozone depleting substances for both developed and developing countries within different timescales
1990s	Increasing finance to developing countries to help them reduce their dependence on ozone depleting substances
1997	Amendments to the Montreal Protocol in order to restore levels of chlorine by 2050-60
1999	Beijing Declaration calling for efforts to stop illegal trade in ozone depleting substances
EEA (2001)
Cl F
[ I CI—C—Cl Cl—C—Cl
I I
F F
Average latent period for skin cancer is 30-40 years
■-Vrt-
1975
2000
2025
2050
207 f>
2100
I   I CFC's production & consumption
I Ozone depleting substances in stratosphere
|  | Increased UV-radiatmn
st the earth's surface | Background skin cancer rate
| Estimated additional skin cancer from ozone layer depletion
This graph illustrates the approximate time lags between CFC production, the resulting depletion of the stratospheric ozone layer and subsequent extra penetration of Uv radiation and the impact this will eventually have on increasing the background rate of skin cancer, given the 30-40year average latent period for such cancers. Reality is far more complex than this schematic illustration. For example, there are other ozone-depleting chemicals (HCFCs, HFCs and methyl bromide); the ozone hole varies with latitude, time of the year and meteorological conditions; the increased UV radiation varies between different wavelengths and with latitude and cloud cover; and the skin cancer excess comes on top of a rising background rate of skin cancer, with differential effects on the different types of skin cancer, such as malignant melanoma and non-malignant skin cancers. Human behaviour is also a determining effect in skin cancer Health effects also include cataracts and immune response suppression. However, the figure illustrates the main relationships and time lags between CFC production and skin cancer, and the 'success' in stopping CFC production and averting much more skin cancer from ozone depletion than what is now expected. {Slaper, et aJ„ 1996).
QOQQ
Zákaz problematické chemikálie, hura ...
... anebo ? ... (strategie chemického průmyslu)
■ náhrady problematických chemikálií
Br Br
PBDEs: included in the Stockholm Convention
in 2009 now: many other BFRs
Br Br
I RECETOX
Martin Scheringer lecture at RECETOX seminar 19/9/2023
Zákaz problematické chemikálie, hura ...
... anebo ? ... (strategie chemického průmyslu)
náhrady problematických chemikálií
Fluoropolymer manufacture
CFo   CFp   CF2 CFp 3°     CF2  CF2  CF2  CH2 CH2OH
F3C
CF2   CF2   CF2 COOH
/ \ / \/ \2/
CF2   CF2 CF2
C8 PFAS: phase-out ongoing
ADONA (CAS No. 958445-44-8)
2 r2
GanX (CAS No. 62037-80-3)
coo
Asahi's product (CAS No. 908020-52-0)
_ COO"
'2 r2
Solvay's product (CAS No. 329238-24-6)
CF3 CF3
coo
Metal plating
N(Et)4-PFBS (CAS No. 25628-08-4)
F2
F3C-
C Fa
,CjHa
CSH6
6:2 FTSA (CAS No. 27619-97-2)
Fí Fs F, Hi
/•C\ /C\ /C\
F3C        ^      >T       c >(Wí
H.
F-53 (CAS No. 754925-54-7)
Fj
F^C
F-53B (CAS No. 73606-19-6)
F,
Fí
F ?
-C-
C
now: many other PFASs
F;
,so3-
c
U r JI   R E C E T 0 X
Martin Scheringer lecture at RECETOX seminar 19/9/2023
26
Zákaz problematické chemikálie, hura ...
... anebo ? ... (strategie chemického průmyslu)
■ náhrady problematických chemikálií
stabilizátory plastů
tBu
H —N         WO °    \ N_H
y-(CH,)S-^ W
TINUVIN 770
Mol. wt. 481
Tetrakis[methylene(3,5-di-tert-butyl-4-hydroxy-hydrocinnamate)] methane
IRGANOX 1010
N —ŕ— N
_/yj       v a ^
V_/     s N      N N
U —J—N
UNI   R E C E T 0 X
i II
'-fll N-(CHj);—N-
Tris(2,4-di-tert-butylphenyl) phosphite
IRGAFOS 168
TINUVIN NOR 356
Mol.wt. 1700
CHIMASSORB 944
Mol. wt. > 2500
H,C
HO.
.CH 3
Cl
>-o
CH,
^CH3
N /M
CH,
CHIMASSORB 119
Mol. wt. 2286
OH
TINUVIN 327
Mol.wt. 358 Abs. Max. 310, 351 nm
OC„H,
CYASORB UV1164
Mol.wt. 509 Abs. Max 290, 342 nm 27
Životní cyklus výrobku
Pomalé uvolňování chemikálií do ŽP
estradiol
Jfi ftaláty
UNI RECETOX
paraben
triclosan
ibuprofen
glyfosát
o		0
II	H	II
		^F?'"i.í-\i_i
HO -	/ \	
		OH
F   F F
N N H H
novaluron
29
Směsi - koktejly polutantů
Výsledky průzkumu půd 2015
81% půd s alespoň jedním pesticidem nad 0.01 mg/kg 36% půd s > 3 pesticidy nad 0.01 mg/kg
https://www.stream.cz/adost /10028599-zamorena-puda-alarmujici-vysledkv-testu-pudv-v-cesku
30
Směsi - koktejly polutantů
Výsledky monitoringu vod ČR 2014-2016
■ 43% objektů nad limit 0.1 |jg/L pro jednotlivý pesticid
■ 31% objektů nad limit
pro sumu pesticidů UNII RECETOX
| desetyldesisopropylatrazin i DEDiA ^ 2,ťj-<JichlGí&enzannid f 2.6-ctivhlotQbenzamide ^ atrazin 2-hydrDsy /atrazine ] desetylatrazin/DEd I atrazin / aträzine
Pesticidy: 41% objektů nad limit Žádné citlivé oblasti, zranitelné oblasti ani opatření!
překročena referenční hodnota i^ Ihreshoíd VBÍue excj
Koncentrace nad mezi stanovíteInosli f concentfation above iimit ofquentification
koncentrace pod mezľ stanovltelnosti i concenttatiQr} beiow flmft of quantiftcation
|| promelryn í prometryn
^\ atetoclilorOA/acetoerifarOA
acQtochlor ESA / aceíochtor ESA
| alachlor OA/ slathicr OA
_J alac-ilír ESA'1 alachíorESA
I metolachlorOA/m&tofachfcrOA
I me to la ch Iq r ES A /    tofachíor ESA
| rne taza c Mor O A f metaza ctfnr OA ^ me taza c Not ESA' m&lazacftfor ESA I     I mcpp/mcpp
| hexazinoi / hexňzinůne
] chloridazon J ctihridazoti
□chloridaz&r* desphenyiv cblorktúzon desphsnyf
□chloridazon methyl despheryl V err/orTďazon metfry/ děSf/hé/ffi
chlortolnron / cfiforoto/uron
| isopr-oturon ŕ isoproturon
^ klopyratid / cíop-jra^tf
nittribuzin desamino diketo/
I bentazon ŕ1 bentezcne
31
Proč asi uhynula tato ryba?
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56
Proč uhynula tato ryba?
M-P-K
Excess use of Chemical Fertilisers leads to run of and ground water contamination
T ft
The inorganic salts dissolved ground water eventually enter lakes, ponds and rivers
Fish begin to die as oxygen levels fall
Increased growth of algae shading out other plants
Increased nutrients
absorbed by al gae Inreased decomposition of
dead aJgae uses up Farab
UNI RECETOX
oxygen in the water
I      H     I      H n7
Vsí
C02H
eutrofizace saprobita
toxiny
MUNI RECETOX
Globální chemické znečištění
34
www.R3llEv.com/lindan443
Jaké skupiny látek znečištujících ŽP vás napadají?
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Globální chemické znečištění
Produkty denní spotřeby
MUNI|RECETOX
Skupiny znečišťujících látek
■ anorganické plyny ■
■ kovy
■ průmyslové kyseliny
■
■ radionuklidy
nutrienty (živiny, anorganická hnojiva) B
organické (degradabilní, komunální, fekální) znečištění
■
komunální chemie - PCPs, detergenty, mýdla, změkčovadla ...
nehalogenovaná rozpouštědla (alkoholy, étery, BTEX ...)
halogenované alifatické uhlovodíky (freony ...)
látky průmyslu gumy a plastů (ftaláty, polybromované difenylethery, PFAS ...)
persistentní organické látky (POPs), halogenované [produkty průmyslu (PCBs, PBBs) a vedlejší produkty (PCDD/Fs, PBDD/Fs)]
pesticidy [insekticidy - nehalogenované vs. halogenované (patří mezi POPs), herbicidy]
farmaka, léčiva
produkty denní spotřeby (PCPs)
PAHs - polycyklické aromatické uhlovodíky
NI|RECETOX
Globální chemické znečištění
■ zejména perzistentní chemikálie
Htgíi latitudes
F. Wania, D. Mackay, Environ. Sci. Technol. 30 (1996), 390A-396A
Globální chemické znečištění - dopady
UNI RECETOX
Rockstróm et al. (2009)
Richardson etai, Sci. Adv. 9, eadh2458 (2023)
39
Globální chemické znečištění - dopady
MUNI
40
Které SDG souvisí s chemickým znečištěním PŘÍMO
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Které SDG souvisí s chemickým znečištěním NEPŘÍMO
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Expozom
Dopady chemického znečištění na člověka
Table 1: Some major health impacts associated with environmental exposures to Resniratorvdiseases chemicals and other environmental stressors. Source: Adapted from EEA (2005)
Health impact	Associations with some
	environmental exposures
Infectious diseases
Water, air and food contamination Climate change-related changes in the lifecycle of pathogens
Cancer
Air pollution
Some pesticides Asbestos
Natural toxins Caflatoxins)
Polycyclic aromatic hydrocarbons
Some metals, e.g. arsenic, cadmium,
chromium
Benzene
Dioxins
Cardiovascular diseases
Air pollution Carbon monoxide Lead
UNEP(2013)
Respiratory diseases,	Sulphur dioxide Nitrogen dioxide Inhalable particles Ground-level ozone Fungal spores Dust mites Pollen
Skin diseases	UV radiation Some metals, e.g. nickel Pentachlorophenol Dioxins
Reproductive	Polychlorinated biphenyls (PCBs) DDT Cadmium Phthalates and other endocrine disrupters Pharmaceuticals
Developmental (foeta and childhood) disorders	Lead Mercury Cadmium Some pesticides Endocrine disruptors
Nervous system disorders	Lead PCBs Methylmercury Manganese Some solvents Organophosphates
Immune response	Some pesticides
	
MUNI RECETOX
https://www.fao.org/3/cb4894en/o nline/src/htm l/ch apter-04-3.html
Lead, manganese, mercury, tin, PBDEs, PAHs.PCBs Neurodevelopmental impairment, reduction of intelligence quotient, behavioural disorder, Parkinson-type syndrome, headache
BTEX, lead, PFAS, PCBs
Altered immune response, reduced response to vaccines in children Cadmium. PCBs, PDBEs
Altered metabolism and reproductive hormone levels Reduced thyroid hormones, altered growth
Benzene, lead, mercury, organochlorine
Pesticides, PAHs, PFAS, PCBs, microplastics hypertension,
endothelial dysfunction, vascular inflammation, oxidative stress,
atherosclerosis
Arsenic, asbestos, cadmium, chromium, copper, mercury, radon Pulmonary emphysema, asthma, chemical pneumonia, lung cancer, mesothelioma
Nitrogen and ionizing radiation Stomach cancer
Phthalates, PCBs
Altered insulin metabolism and adipogenesis, diabetes
DDT, chromium, copper, PAHs, PCBs, PFAS, phthalates Increased cholesterol levels, liver cancer, elevated hepatic enzyme levels, necrosis
Cadmium, lead, mercury, PAHs, PFA3
Renal tubular dysfunction, kidney weight changes,
progressive nephropathy, chronic inflammation, kidney cancer
Arsenic, copper, lead, mercury, tin, microplastics, POPs Nausea, vomiting, diarrhea, cancer ot gastrointestinal system, abdominal pain and cramping
Arsenic, lead
Cancer of urinary bladder, urinary changes
Antimony, asbestos, lead, manganese, phthalates, PBDEs, PCBs, PFAS Testicular atrophy, early menopause, reduced testosterone, reproductive alterations, decreased libido, impotence, sexual dysfunction, endometriosis, hormonal cancers (breast, prostate, testes), infertility, ovary cancer
Cadmium, lead, PCBs, radium and its decay products impaired bones development, slow growth, changes in metabolism of calcium and bone formation, osteomalasia, bone cancer
Arsenic, chromium, PAHs, PCBs
Hyperkeratosis, hyperpigmentation, iiypopigmentation, skin irritation and inflammation, chloracne, hirsutism, skin, tooth, and nail abnormalities
Dopady chemického znečištění na člověka
■ malárie + AIDS + tuberkulóza 3,4 mi
■ 8-9 mil lidí ročně zemře na následky znečistení
o znečištěné venkovní ovzduší 3,7 mil
o znečištěné vnitřní ovzduší (pece, kamna) 4,2 mil
o znečištěná půda a voda 1 mil
https://ensia.com/voices/leadinq-cause-death-developinq-countries http://qahp.net/the-lancet-report-2/ Landrigan et al. (2018)
The economic cost of air pollution
The cost of air pollution to the world's most advanced
Choking to death
Deaths attributable to the Joint effects of household and ambient air pollution in 20' 2, by region ['000)
America ^ 95
America LrVil 131
Europe HI 295
Europe LMI 287
Key:
LMI = lew- and middeircom HI = high-income
Western Pacific HI 61
Deaths attributable in 2012, bydisease Acute lower respiratory disease Lung cancer
Chronic obstructive pulmonary disease
Ischaemic heast disease Source: WHO 2012
Eastern Mediterranean LMI
— •
Eastern 14 Mediterranean HI
UNEP(2
Global premature deaths from selected environmental risks: Baseline,
2010 to 2050
2mo
2 J?C
economies plus India and China is estimated to be
trillion per year in lives lost and [II health. In OECD
US$3.5
]
countries the mo n eta ry i mpsct of death a nd l\Fness due to outdoor air pollution in 2010 is estfmated to have been [US51.7 trillion^
IUI U II 1   1   l\ L U
Particulate matter
Ground-level ozone
Unsafe water supply and sanitation
Indoorü pollution
M :la"
3.0 3.5 4.0,
Deaths (millions of people)
ISIEP (2014)
Chemicals/ Groups of chemicals	Disease outcomes considered (population attributable fraction of DALYs)	Deaths	DALYs	Method
Chemicals in acute poisonings				
Chemicals involved in unintentional acute poisonings (methanol diethylene glycol, kerosene, pesticides etc.)	Unintentional poisonings (73%)	61,523	3,489,814	Expert survey/ qualitative evidence synthesis
Chemicals involved in unintentional occupational poisonings (already included in the above poisonings)	Unintentional poisonings (occupational) (9.8%)	8,608	470,082	CRA
Pesticides involved in self-inflicted injuries	Self-inflicted injuries (20%)	137,631	6,245,500	Limited epidemiological data
Chemicals involved in congenital anomalies	Congenital anomalies (5,0%)	26,643	2,589,832	Expert survey/ qualitative evidence synthesis
Single chemicals with mostly longer term effects				
Lead	Cardiovascular diseases (CVD) (4.6%); chronic kidney diseases (CKD) (3.0%); idiopathic intellectual disability (1 ID) (30%) 3	901,716 (CVD: 848,778, CKD: 52,938) P	21,676,385 (CVD: 17 734.898. CKD: 1,225.202. IID: 2,716,285)	CRA
Chemicals in occupational exposures (longer term effects)				
Occupational carcinogens (arsenic, asbestos, benzene, beryllium, cadmium, chromium, diesel engine exhaust, formaldehyde, nickel, silica, sulphuric acid, trichloroethylene)b	Cancers (2.9%); pneumoconiosis (79%) ^	350,325 ■ (cancers: /\      333.S3': pneumoconiosis: 16,458)	7,691,763 [cancers: 6964,775, pneumoconiosis: 726,988)	CRA
Occupational particulates (dusts, fumes, gas)	COPD (16%); pneumoconiosis (21%)	524,290 A 517.734. pneumoconiosis: 5,556)	11,788,178 (COPD: 11,596,089, pneumoconiosis: 192,089)	CRA
Total	Considered diseases: poisonings, self-inflicted injuries, congenital anomalies, cardiovascular diseases, chronic kidney diseases, idiopathic intellectual disability, cancers, pneumoconiosis, COPD	/ 2,002,328 I (3.6% of total deaths)	V f53,481,472 11(2.1% of total 11 DALYs)	
Data sources: CRA: IHME (2021), disease statistics: WHO (2021a and 2021b): 'expertsurvey' and 'limited epidemiological data": Prüss-Ustün et al. (2016), a without counting the effect of chemicals in general ambient air pollution, 'excludes second-hand tobacco smoke.
Notes: DALYs: disability-adjusted life years. CRA: comparative risk assessment, COPD: chronic obstructive pulmonary disease, CVD: cardiovascular diseases, CKD: chronic kidney diseases, IID: idiopathic intellectual disability.
Dopady chemického znečištění na člověka
WHO (2021): The public health impact of chemicals: knowns and unknowns - 2021 data addendum.
https://www.who.int/publications/i/item/ WHO-HEP-ECH-EHD-21.01
Dopady chemického znečištění na člověka
Mil l\l figure 8: Number of deaths per 100 000 people that are attributable to all forms of pollution, 2015 U ll GBD Study, 2016.^
Landrigan et al. (2018)
47
Dopady chemického znečištění na člověka
■
Speda/ issue; Perspectives on tfie tecfjnosphere
3#
THE
ANTHROPOCENE REVIEW
Toxic chemicals as enablers and poisoners of the technosphere
The Anihropocene Review 2017. Vol. 4(2) 72-80 ©The Auihor(s) 2017 Reprints and permissions: sagepub to. u k/journalsPermi£i;ions.nav DOt: 10.1177/2051019b1772&30Ů ouľna[s.sagepub.com/home/anľ
Miriam L Diamond
„Neurobehavioural effects caused by toxic chemical exposure have profound implications for society and its ability to self-perpetuate. Not only does society have to shoulder associated health and management costs, but a five point decrease in IQ related to neurotoxicant exposure could also decrease the number'' gifted individuals needed to solve complex problems in the technosphere."
Neurobehavioral Deficits, Diseases, and Associated Costs of Exposure to Endocrine-Disrupting Chemicals in the European Union
Martine Bellanger, Barbara Demeneix, Philippe Grandjean, R. Thomas Zoeller, and Leonardo Trasande
Results: The panel identified a 70-100% probability that polybrominated diphenyl ether and organo-phosphate exposures contribute to IQ loss in the European population. Polybrominated diphenyl ether exposures were associated with 873 000 (sensitivity ana lysis, 148 000to2.02 million) lost IQ points and 3290 (sensitivity analysis, 3290 to 8080) cases of intellectual disability, at costs of €9.59 billion (sensitivity analysis, €1.58 billion to €22.4 billion). Organophosphate exposures were associated with 13.0 million (sensitivity analysis, 4.24 million to 17.1 million) lost IQ points and 59 300 (sensitivity analysis, 16 500 to 84 400) cases of intellectual disability, at costs of €146 billion (sensitivity analysis, €46.8 billion to €194 billion). Autism spectrum disorder causation by multiple EDCs was assigned a 20-39% probability, with 316 (sensitivity analysis, 126-631) attributable cases at a cost of €199 million (sensitivity analysis, €79.7 million to €399 million). Attention-deficit hyperactivity disorder causation by multiple EDCs was assigned a 20-69% probability, with 19 300 to 31 200 attributable cases at a cost of €1.21 billion to €2.86 billion.
jsions: EDC exposures in Europe contribute substantially to neurobehavioral detici disease, with a high probability of >€150 billion costs/year. These results emphasize the advances of controlling EDC exposure. (J Clin Endocrinol Metab 100: 1256-1266, 2015)
Diamond et al. (2017)
UNI RECETOX
Beilanger et al. (2015)
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Co ve mně vyvolávají zprávy/data o špatném stavu ŽP a jaký k tomu zaujímám postoj?
Neovlivňují moji náladu a chci je znát
| 0%
Neovlivňují moji náladu, ale i tak si je nechci moc pouštět do hlavy
| 0%
Přináší mi smutek či špatnou náladu či depresi, ale i tak je chci znát
| 0%
Přináší mi smutek či špatnou náladu či depresi a proto si je nechci moc pouštět do hlavy
| 0%
Ani jedno z výše uvedeného na mě nesedí
| 0%
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Chemicals at UNEP
mm
environment
Chemicals at UNEP
Modern society is living in the most chemical-intensive era in human history, the pace of production of new chemicals largely surpasses the capacity to fully assess their potential adverse impacts on human health and ecosystems (...) and now chemical pollution is considered a global threat, (p. 76 and 88)
https://www.unep.org/resources/ qlobal-environment-outlook-6
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Globální chemické znečištění - dopady
přelomová studie z roku 1972
modely dynamiky naší přítomnosti na planetě
pokračování modelu růstu "business as usual" (BAU) pravděpodobně povede ke kolapsu ZP a ekonomiky během jednoho století, protože čerpání zdrojů a produkce odpadu a znečištění překročí únosnou kapacitu planety
exponenciální růst v uzavřeném systému nemůže donekonečna růst
kontroverze mezi vědci, odborníky i širokou veřejností, ale v následujících desetiletích byly tyto objevy podpořeny modely růstu, stavu ŽP a využívání zdrojů
i dnes, 50 let po svém vydání, zůstává kniha důležitým zdrojem informací pro každého, kdo doufá, že lépe porozumí složitému systému, kterým je naše planeta
UNII RECETOX
li
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Donella H. Meadows Dennis L. Meadows J0rqen Panders William W. Behrens III
A Report for THE CLUB OF ROME'S Project on tne Predicament ot Mankind
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The "standard" world modal run assumes no major change in the physical, economic, or social relationships that have historically governed the development of the world system. All variables plotted here follow historical values from 1900 to 1970. Food, industrial output, and population grow exponentially until the rapidly diminishing resource base forces a slowdown in industrial growth. Because of natural delays in the system, both population and pollution continue to increase for some time after the peak ot industrialization. Population growth is finally halted by a rise in the gr^tft
(dostupne Zde)        rate due to decreased food and medical services.
Globální chemické znečištění - dopady
Turner, G. (2014): Is Global Collapse Imminent? MSSI Research Paper No. 4, Melbourne Sustainable Society Institute,The University of Melbourne. ISBN: 978 0 7340 4940 7
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Figure I. LTG BAU (Standard Run) scenario (dotted lines) compared with historical data from 1970 to 2010 (solid lines)—for demographic variables: population, crude birth rate, crude death rate; for economic output variables: industrial output per capita, food per capita, services per capita (upper curve: electricity p.c; lower curves: literacy rates for adults, and youths [lowest data curve]); for environmental variables: global persistent pollution, fraction of non-renewable resources remaining (upper curve uses an upper limit of 150,000 EJ for ultimate energy resources; lower curve uses a lower limit of 60,000 EJ [Turner 2008]).
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53
Na závěr
myšlenky prof Scheringera z přednášky na RECETOX semináři 19/9/2023:
Společnost je v chemickém přebytku: Příliš mnoho různých látek v příliš mnoha různých aplikacích
■ Chemické výrobky jsou potřebné, ale společnost musí být mnohem více „chemicky efektivní"
■ Je také nutná podstatná změna
Chemical Simplification
týkající se chemických látek
Problémem není jen uhlíková stopa chemický průmyslu, ale i jeho „toxická stopa"
fpOHL
Lbciencesiecnnology
pubs.ac5.org/eit
Viewpoint
The Need for Chemical Simplification As a Logical Consequence of Ever-Increasing Chemical Pollution
Kathrin Fermer* and Martin Scheringer*
Fenner, K., Scheringer, M., 2021. The Need for Chemical Smplification As a Logical Consequence of Ever-Increasing Chemical Pollution. Environmental Sciences Technology 55, 14470-14472.. ht t ps: / / doi. org/10.1021 / acs. est. 1C04903
UNI RECETOX
Devising chemically less intense, but functional materials and products requires intense development efforts and new design principles. Importantfy, this also offers promising market opportunities because materials and products that are chemically simpler and, thereby, easier to recycle and inherently safe are in high demand by many large brands of consumer products and by the consumers themselves.
Literatura
OECD (2012): OECD Environmental Outlook to 2050, OECD Publishing. http://dx.doi.Org/10.1787/9789264122246-en
Eckerman I. (2005): The Bhopal Saga: Causes and Consequences of the World's Largest Industrial Disaster. Universities Press, https://eckerman.nu/the-bhopal-saqa
Eskenazi B. et al. (2018): The Seveso accident: A look at 40 years of health research and beyond. Environment International 121,71 -84.
Schoyen M. et al. (2019): Levels and trends of tributyltin (TBT) and imposex in dogwhelk (Nucella lapillus) along the Norwegian coastline from 1991 to 2017. Marine Environmental Research 144, 1-8.
Scheringer, M., Johansson, J.H., Salter, M.E., Sha, B., Cousins, IT., 2022. Stories of Global Chemical Pollution: Will We Ever Understand Environmental Persistence?. Environmental Science & Technology 56, 17498-17501.. https://doi.org/10.1021/acs.est.2c06611
EEA (2001): Late lessons from early warnings: the precautionary principle 1896-2000. Luxembourg. 210 pp. ISBN 92-9167-323-4.
EEA (2013): Late lessons from early warnings: science, precaution, innovation. 760 pp. ISBN 978-92-9213-356-6
UNEP (2012): Global Environmental Outlook 5: Environment for the Future We Want.
Roberts, D.R., Laughlin, L.L., Hsheih, P., Legters, L.J., 1997. DDT, global strategies, and a malaria control crisis in South America. Emerging infectious diseases 3, 295-302
Blacksmith Institute (2006): The world's worst polluted places. The Top Ten. The Blacksmith Institute.
UNEP (2013): UNEP Year Book 2013: Emerging issues in our global environment. ISBN: 978-92-807-3284-9.
UNEP (2014): UNEP Year Book 2014: Emerging issues in our global environment. ISBN: 978-92-807-3284-9.
UNEP (2013): GCO Global Chemicals Outlook: Towards Sound Management of Chemicals. Ed. United Nations Environment
UNEP (2019): Global Chemicals Outlook II. From Legacies to Innovative Solutions: Implementing the 2030 Agenda for Sustainable Development.
MUNI | RECETOX
Literatura
Rockstróm et al. (2009): A safe operating space for humanity. Nature 461, 472.
Turner, G. (2014) 'Is Global Collapse Imminent?', MSSI Research Paper No. 4, Melbourne Sustainable Society Institute, The University of Melbourne. ISBN: 978 0 7340 4940 7
Bellanger, M., et al., 2015. Neurobehavioral deficits, diseases, and associated costs of exposure to endocrine-disrupting chemicals in the European Union. J Clin Endocrinol Metab. 100, 1256-66
Landrigan et al. 2018. The Lancet Commission on pollution and health. The Lancet 391, 462-512.. doi:10.1016/s0140-6736(17)32345-0
WHO (2021): The public health impact of chemicals: knowns and unknowns - 2021 data addendum. https://www.who.int/publications/i/item/WHO-HEP-ECH-EHD-21.01
Holoubek I. (2018): Chemie životního prostředí I - IV. Přednášky pro MU.
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