2. Toxicity of solvents suicide attempt
directly toxicity
3. Toxicokinetic Absorption:
concentration, time, dose, lipophilicity, blood flow
Distribution:
the more lipophilic solvents the more toxicity
Metabolism:
Metabolic inactivation (detoxification) Ex. toluene
Metabolic activation (bioactivation) Ex. benzene
Elimination:
liver, renal, respiratory
4. ????????????????? Solvents
ethanol
methanol
isopropranol
(isopropyl alcohol)
formaldehyde
acetadehyde
Gases
carbonmonoxide (CO)
cyanide
5. Commercial beer
wine
liquors
colognes
perfumes
after-shaves
mouthwashes
pharmaceutical preparations Ex elixir
6. Mechanism of toxicity Central nervous system depression
principal effect of acute ethanol intoxication
Hypoglycemia
impaired gluconeogenesis particularly in children and poorly nourished person
trauma
exposure induced hypothermia
7. pure ethanol 0.7 g/kg = 100 mg/dl (Blood alcohol concentration)
level of 100 mg/dl is enough to inhibit gluconeogenesis and hypoglycemia
>300 mg/dl coma
500-600 mg/dl coma (chronic alcoholism)
9. Toxicokinetic Absorption
rapidly absorption especially in duodenum
saturated lipid inhibit ethanol absorption
5% by inhalation and skin
10. Distribution:
Vd =0.7 L/kg
rapidly distribution
ratio of distribution of alveolar and blood: 1:2100
Toxicokinetic
11. ethanol
12. Blood concentration < Km
first order kinetic
Blood concentration > Km
zero order kinetic
Km =8-14 mg/dl
13. Clinical presentation Acute intoxication
mild to moderate intoxication
euphoria, mild incoordination, ataxia, nystagmus, impaired judgement and reflex
deep intoxication
coma, respiratory depression, pulmonary aspiration, decrease blood pressure and pulse rate
hypoglycemia/ hypoinsulinemia
14. Chronic intoxication Gastrointestinal bleeding (GASTRITIS)
Pancreatitis
hepatitis
cirrhosis
hepatic encephalopathy
hypokalemia/hypophosphatemia/hypomanesemia
thiamine deficiency
alcoholic ketoacidosis
Decreased resistance to infection
15. Alcoholic ketoacidosis (AKA) Chronic alcohol intake, Alcoholism
Nausea, vomiting, hematemesis, abdominal pain
Complex interaction of EtOH metabolism, decreased caloric intake, volume depletion
Lack or oral intake & Volume depletion
Decreased glucose decreased insulin
Increased NADH/ NAD
inh. Gluconeogenesis decrease glucose
Decreased insulin Increased lipolysis
Increased NADH/ NAD ratio favor production of Beta-hydroxybutyrate (ketone)
Ketone clearance is impaired by volume depletion
Tx IV glucose, hydration
16. Other toxicity Alcohol withdrawal
tremulousness, anxiety, overactivity of sympathetic nervous system
17. Enhancing toxicity Disulfiram
CNS depressant drugs
18. Diagnosis History of ingestion
the characteristic of smell of fresh alcohol, aldehyde
others toxic symptoms
nystagmus, ataxia, alter mental status
Blood ethanol concentration
Calculating the osmolar gap
19. Osmolar gap Osmolar gap = Measured osmolality Calculated osmolality
Calculated osmolality
= 2[Na+] + [glucose]/ 18 + [BUN]/ 2.8
Normal calculated osmolality = 290 mOsm/ L
Increased osmolar gap may occur from low molecular wt. substance ethanol, other alcohol increased measured osmolality
20. TREATMENT Supportive measure.assist ventilation, prevent seizure
glucose to relief ketosis
benzodiazepine (diazepam 2-10 mg IV) to relief alcohol withdrawal
emesis/gastric lavage is not indicated unless ingestion has occurred within a few minute of presentation.
21. wood alcohol, Columbian spirit, colonial spirit
ingredient in many solvents
windshield-washing solution
duplication fluids
paints removers
an ethanol substitute by alcoholic methanol ??????????? wood alcohol, Columbian spirit, colonial spirit ????????????????????????????????????????????????????????????????? ?????????????????? methanol ????????????????????? methanol ???????????????????????? methanol ????????????? ???????????????????????????????????????????????????????????????? methanol ???????????????????? methanol ??????????????????????????????????????????? ??? methanol ???????????? ethanol ??????????? metabolites ????????? methanol ??? formic acid ?????????????????? metabolic acidosis, ????????????????? ???????????????????????? 6-30 ??????? methanol ??????????? wood alcohol, Columbian spirit, colonial spirit ????????????????????????????????????????????????????????????????? ?????????????????? methanol ????????????????????? methanol ???????????????????????? methanol ????????????? ???????????????????????????????????????????????????????????????? methanol ???????????????????? methanol ??????????????????????????????????????????? ??? methanol ???????????? ethanol ??????????? metabolites ????????? methanol ??? formic acid ?????????????????? metabolic acidosis, ????????????????? ???????????????????????? 6-30 ???????
22. Toxicokinetic Readily absorbed
Quickly distributed to the water (Vd =0.6 L/kg)
Not bound to plasma protein
metabolized slowly by alcohol dehydrogenase Via Zero-order kinetic but slowly than ethanol
Excreted unchanged by kidney and <10% by breath
23. The accumulation of formic acid is responsible for the presence of metabolic acidosis. Formic acid also inhibits cellular respiration leading to lactic acidosis. The ocular injury caused by methanol may be due to retinal injury, which results from intra-retinal metabolism of methanol and the accumulation of formic acid. Alternatively, it may be caused be the inhibition of normal metabolism in optic nerve calls (Jacobsen 1997).The accumulation of formic acid is responsible for the presence of metabolic acidosis. Formic acid also inhibits cellular respiration leading to lactic acidosis. The ocular injury caused by methanol may be due to retinal injury, which results from intra-retinal metabolism of methanol and the accumulation of formic acid. Alternatively, it may be caused be the inhibition of normal metabolism in optic nerve calls (Jacobsen 1997).
25. Mechanism of toxicity Toxicity is form metabolic products, formaldehyde and formic acid.
Lactic acid and formic acid cause systemic acidosis.
Formate cause blindness.
Increase anion gap. Like ethylene glycol, methanol is relatively non-toxic; however, it is metabolized to highly toxic compounds that are responsible for the acidosis and blindness characteristic of methanol poisoning.
As in ethylene glycol poisonings, the initial step in the metabolism of methanol involves the enzyme alcohol dehydrogenase (ADH) (see Figure 2). First, methanol is slowly oxidized by ADH to yield formaldehyde. Next,formaldehyde is oxidized by formaldehyde dehydrogenase to yield formic acid (or formate, depending on the pH). This oxidation occurs rapidly so that little formaldehyde accumulates in the serum. FInally, formic acid is metabolized to carbon dioxide and water, which are excreted by the kidneys and lungs.�Like ethylene glycol, methanol is relatively non-toxic; however, it is metabolized to highly toxic compounds that are responsible for the acidosis and blindness characteristic of methanol poisoning.
As in ethylene glycol poisonings, the initial step in the metabolism of methanol involves the enzyme alcohol dehydrogenase (ADH) (see Figure 2). First, methanol is slowly oxidized by ADH to yield formaldehyde. Next,formaldehyde is oxidized by formaldehyde dehydrogenase to yield formic acid (or formate, depending on the pH). This oxidation occurs rapidly so that little formaldehyde accumulates in the serum. FInally, formic acid is metabolized to carbon dioxide and water, which are excreted by the kidneys and lungs.
26. Anion gap = [Na+] [Cl-] [HCO3-]
Normal = 8 12 meq/ L
Anion gap acidosis usually occur from accumulation of lactic acid or other unmeasured acid anion, such as formic acid
27. 20-150 g
minimun toxic dose = 100 mg/kg
ACGIH recommended workplace exposure limit TLV-TWA) concentrated inhalation is 200 ppm as 8 h. time-weighted average
Exposure to 6,000 ppm is considered to dangerous to life.
28. Clinical presentation In the first few hour
inebriation and gastritis
increase osmolar gap After latent periods
up to 30 h
metabolic acidosis
visual disturbance
Like standing in the snow field
blindness
seizure
coma and death Initial symptoms of methanol poisoning may appear as soon as 12 hours post-ingestion, but usually develop 24 hours after ingestion. These may resemble ethanol intoxication and consist of drowsiness, confusion, and ataxia, as well as weakness, headache, nausea, vomiting, and abdominal pain. Collectively, these symptoms may mimic an alcohol hangover and are due to mild intoxication, caused by methanol itself.
As methanol metabolism proceeds, a severe anion gap metabolic acidosis will develop. Severe metabolic acidosis in conjunction with visual effects are the hallmark of methanol poisoning. Patients usually describe blurred or misty vision, double vision, or changes in color perception. There my be constricted visual field and, occasionally, total loss of vision. Characteristic visual dysfunctions include pupillary dilation and loss of pupillary reflex (Burkhart 1990; Suit 1990).
Further signs and symptoms may be shallow respiration, cyanosis, tachypnea, coma, seizures, electrolyte disturbances, and various hemodynamic changes including profound hypotension and cardiac arrest. There may be mild to profound loss of memory, confusion, and agitation, which may progress to stupor and coma as the severity of the acidosis increases (Suit 1990). In severe cases, death is possible. Surviving patients can be left with permanent blindness or with other neurological deficits (Jacobsen 1997).Initial symptoms of methanol poisoning may appear as soon as 12 hours post-ingestion, but usually develop 24 hours after ingestion. These may resemble ethanol intoxication and consist of drowsiness, confusion, and ataxia, as well as weakness, headache, nausea, vomiting, and abdominal pain. Collectively, these symptoms may mimic an alcohol hangover and are due to mild intoxication, caused by methanol itself.
As methanol metabolism proceeds, a severe anion gap metabolic acidosis will develop. Severe metabolic acidosis in conjunction with visual effects are the hallmark of methanol poisoning. Patients usually describe blurred or misty vision, double vision, or changes in color perception. There my be constricted visual field and, occasionally, total loss of vision. Characteristic visual dysfunctions include pupillary dilation and loss of pupillary reflex (Burkhart 1990; Suit 1990).
Further signs and symptoms may be shallow respiration, cyanosis, tachypnea, coma, seizures, electrolyte disturbances, and various hemodynamic changes including profound hypotension and cardiac arrest. There may be mild to profound loss of memory, confusion, and agitation, which may progress to stupor and coma as the severity of the acidosis increases (Suit 1990). In severe cases, death is possible. Surviving patients can be left with permanent blindness or with other neurological deficits (Jacobsen 1997).
29. Diagnostic Calculation of osmolar and anion gap can be used to estimate the methanol level and predict the severity of ingestion
specific level
>20 mg/dl Toxic
>40 mg/dl Severe toxic
After latent period dose not detect methanol because has been metabolized to formate. Anion gap = [Na+] [Cl-] [HCO3-]
??????? = 8- 12 meq/L
????????? anion gap acidosis ???????????????????? lactic acid ?????????????? acid anion ??????????????????????? ???? formic acid ??????????????? methanol poisoningAnion gap = [Na+] [Cl-] [HCO3-]
??????? = 8- 12 meq/L
????????? anion gap acidosis ???????????????????? lactic acid ?????????????? acid anion ??????????????????????? ???? formic acid ??????????????? methanol poisoning
30. Emergency and supportive measurement
open airway
treatment coma and seizure
treat metabolic acidosis by NaHCO3 IV
Specific antidote
fomepizole or ethanol
saturated alcohol dehydrogenase enzyme
Not available measurement methanol serum level
ethanol is less expensive.
Folic acid 50 mg IV q 4 h
increase conversion of formate to CO2+H2O
????????
1. Emergency and supportive measure
-?????????????? methanol ????????????????? ?????????????????? methanol ????????????????????????????????????????????????????????? ??????????????????????????????????????? ???????????????????????? acidosis ????????????????? methanol ??? metabolites ???????????????
-????????????????????????????????
-????????? metabolic acidosis ?????? sodium bicarbonate ????????????????????????
Specific drugs and antidotes
-ethanol: ?????????????????????????????????????????????????????????????? alcohol dehydrogenase ?????????????????????? methanol toxic metabolites ??? methanol ???????? loading dose ???? 0.6-0.8 g/kg ?????? maintenance dose ???? 125-130 mg/kg/h ?????????????????? ethanol ??????????? 100 mg/dl ?????????????? methanol ??? metabolized ????? ?????????????????? ethanol ???????????????? osmolar gap ??????? 5 mOsm/L ??????????? methanol ?????????????? 20 mg/dl
-folic acid, leucovorin calcium (folate analogue) ?????????????????????????????????? formate ???? CO2 ??? H2O ????????????? 50 mg ??? 4 ???????
-?? fomepizole ??????????????????????????? alcohol dehydrogenase enzyme ??????? methanol metaboiltes ?????????????????????????? methanol *?????????????? fomepizole ????????????????????????????????????????? ethanol ?????????????????*
Introduction�Fomepizole, commonly referred to a 4-methylpyrazole or 4-MP, is a relatively recent addition to the therapeutic regimens for ethylene glycol and methanol poisonings. Fomepizole, as either the sulfate or hydrochloride salt, has been available in France since 1981 through a centralized compounding pharmacy servicing French hospitals. Until about 1990, fomepizole was used there investigationally to treat ethylene glycol poisonings. Since 1990, fomepizole has been accepted as the standard of care in France for the treatment of ethylene glycol poisonings.
In 1997, Antizol (fomepizole) Injection was approved by the FDA as an antidote for ethylene glycol (antifreeze) poisoning, or for use in suspected ethylene glycol ingestion. In 2000, Antizol was approved by the FDA for an additional indication as an antidote for methanol poisoning, or for use in suspected methanol ingestion. In 2000, Antizol was approved by Health Canada as an antidote for ethylene glycol poisoning, followed by approval in 2001 as an antidote for methanol poisoning.
Chemistry�Antizol is the free base form of fomepizole, which has a molecular formula of C4H6N2 and a molecular weight of 82.1 grams/mole. Antizol is a clear, colorless to yellow liquid at room temperature, but may solidify below 25 C (77 F). Solidification does not affect the efficacy, safety, or stability of Antizol [Antizol (fomepizole) Injection package insert]. Its chemical structure is shown in Figure 3.
Figure 3. Chemical Structure of Antizol
Mechanism of Action�Antizol is a competitive inhibitor of alcohol dehydrogenase, the enzyme that catalyzes the oxidation of ethanol to acetaldehyde. Alcohol dehydrogenase also catalyzes the initial steps in the metabolism of ethylene glycol and methanol to their toxic metabolites.
Absorption, Bioavailability and Distribution�Intended for administration by the intravenous route, Antizol is immediately and completely bioavailable. Antizol rapidly distributes to total body water. The volume of distribution is between 0.6 L/kg and 1.02 L/kg [Antizol (fomepizole) Injection package insert].
Metabolism and Excretion�In healthy volunteers, only 1-3.5% of an administered dose of Antizol (7-20 mg/kg oral and IV) was excreted unchanged in the urine, indicating that metabolism is the major route of elimination (Jacobsen 1990). In humans, the primary metabolite of Antizol is 4-carboxypyrazole (4-CP), which is excreted in the urine.
Other minor metabolites of fomepizole observed in the urine are 4-hydroxymethylpyrazole and the N-glucuronide conjugates of 4-carboxypyrazole and 4-hydroxymethylpyrazole. These metabolites are either inactive or are so weakly active �(4-hydroxymethylpyrazole) that they do not contribute significantly to the inhibition of alcohol dehydrogenase (Weintraub 1988).
The elimination of Antizol is enhanced after several doses have been administered at 12-hour intervals, suggesting that it induces its own metabolism. Following auto-induction, a first order kinetic model more closely describes the elimination of Antizol. The metabolism of Antizol to 4-CP occurs after an initial cytochrome P-450-mediated hydroxylation followed by further oxidation. As antizol is a potent inducer of cytochrome P-450-mediated drug elimination in animal studies, the auto-induction of Antizol elimination in humans over 36-48 hours may also involve the induction of cytochrome P-450 (Jacobsen 1990).
The elimination of Antizol follows zero order, saturable Michaelis-Menten kinetics after acute doses and a first order kinetic model after induction of metabolism following chronic doses. Values for plasma half-life vary with dose and were therefore not calculated in early study reports.????????
1. Emergency and supportive measure
-?????????????? methanol ????????????????? ?????????????????? methanol ????????????????????????????????????????????????????????? ??????????????????????????????????????? ???????????????????????? acidosis ????????????????? methanol ??? metabolites ???????????????
-????????????????????????????????
-????????? metabolic acidosis ?????? sodium bicarbonate ????????????????????????
Specific drugs and antidotes
-ethanol: ?????????????????????????????????????????????????????????????? alcohol dehydrogenase ?????????????????????? methanol toxic metabolites ??? methanol ???????? loading dose ???? 0.6-0.8 g/kg ?????? maintenance dose ???? 125-130 mg/kg/h ?????????????????? ethanol ??????????? 100 mg/dl ?????????????? methanol ??? metabolized ????? ?????????????????? ethanol ???????????????? osmolar gap ??????? 5 mOsm/L ??????????? methanol ?????????????? 20 mg/dl
-folic acid, leucovorin calcium (folate analogue) ?????????????????????????????????? formate ???? CO2 ??? H2O ????????????? 50 mg ??? 4 ???????
-?? fomepizole ??????????????????????????? alcohol dehydrogenase enzyme ??????? methanol metaboiltes ?????????????????????????? methanol *?????????????? fomepizole ????????????????????????????????????????? ethanol ?????????????????*
IntroductionFomepizole, commonly referred to a 4-methylpyrazole or 4-MP, is a relatively recent addition to the therapeutic regimens for ethylene glycol and methanol poisonings. Fomepizole, as either the sulfate or hydrochloride salt, has been available in France since 1981 through a centralized compounding pharmacy servicing French hospitals. Until about 1990, fomepizole was used there investigationally to treat ethylene glycol poisonings. Since 1990, fomepizole has been accepted as the standard of care in France for the treatment of ethylene glycol poisonings.
In 1997, Antizol (fomepizole) Injection was approved by the FDA as an antidote for ethylene glycol (antifreeze) poisoning, or for use in suspected ethylene glycol ingestion. In 2000, Antizol was approved by the FDA for an additional indication as an antidote for methanol poisoning, or for use in suspected methanol ingestion. In 2000, Antizol was approved by Health Canada as an antidote for ethylene glycol poisoning, followed by approval in 2001 as an antidote for methanol poisoning.
ChemistryAntizol is the free base form of fomepizole, which has a molecular formula of C4H6N2 and a molecular weight of 82.1 grams/mole. Antizol is a clear, colorless to yellow liquid at room temperature, but may solidify below 25 C (77 F). Solidification does not affect the efficacy, safety, or stability of Antizol [Antizol (fomepizole) Injection package insert]. Its chemical structure is shown in Figure 3.
Figure 3. Chemical Structure of Antizol
Mechanism of ActionAntizol is a competitive inhibitor of alcohol dehydrogenase, the enzyme that catalyzes the oxidation of ethanol to acetaldehyde. Alcohol dehydrogenase also catalyzes the initial steps in the metabolism of ethylene glycol and methanol to their toxic metabolites.
Absorption, Bioavailability and DistributionIntended for administration by the intravenous route, Antizol is immediately and completely bioavailable. Antizol rapidly distributes to total body water. The volume of distribution is between 0.6 L/kg and 1.02 L/kg [Antizol (fomepizole) Injection package insert].
Metabolism and ExcretionIn healthy volunteers, only 1-3.5% of an administered dose of Antizol (7-20 mg/kg oral and IV) was excreted unchanged in the urine, indicating that metabolism is the major route of elimination (Jacobsen 1990). In humans, the primary metabolite of Antizol is 4-carboxypyrazole (4-CP), which is excreted in the urine.
Other minor metabolites of fomepizole observed in the urine are 4-hydroxymethylpyrazole and the N-glucuronide conjugates of 4-carboxypyrazole and 4-hydroxymethylpyrazole. These metabolites are either inactive or are so weakly active (4-hydroxymethylpyrazole) that they do not contribute significantly to the inhibition of alcohol dehydrogenase (Weintraub 1988).
The elimination of Antizol is enhanced after several doses have been administered at 12-hour intervals, suggesting that it induces its own metabolism. Following auto-induction, a first order kinetic model more closely describes the elimination of Antizol. The metabolism of Antizol to 4-CP occurs after an initial cytochrome P-450-mediated hydroxylation followed by further oxidation. As antizol is a potent inducer of cytochrome P-450-mediated drug elimination in animal studies, the auto-induction of Antizol elimination in humans over 36-48 hours may also involve the induction of cytochrome P-450 (Jacobsen 1990).
The elimination of Antizol follows zero order, saturable Michaelis-Menten kinetics after acute doses and a first order kinetic model after induction of metabolism following chronic doses. Values for plasma half-life vary with dose and were therefore not calculated in early study reports.
31. Treatment (cont.) Do not induce vomiting
Hemodialysis rapidly remove both methanol and formate
Osmolar gap>10 mOsm/L and serum methanol concentration>40 mg/dl should elimination by dialysis and continued until methanol concentration is less than 20 mg/dl.
32. 3. Isopropanol ???? isopropyl alcohol Used as solvents
antiseptic
disinfectant
often ingested by alcoholic a the cheap substitute for liquor
Blue dye Blue heaven Isopropyl alcohol ???????????????????????? ????????????????????????? ??????????????????????????????? 70% (Antiseptic and disinfectant) ??????????????????????????????????? ethanol ?????????????? isopropyl alcohol ??? methanol ??? isopropyl alcohol ???????????????? toxic organic acid metabolite ????????? ??????????????????????????????????????????????????????????????????? (Vd=0.6 L/kg) ??? metabolized ???????????? alcohol dehydrogenase enzyme ??????? acetoneIsopropyl alcohol ???????????????????????? ????????????????????????? ??????????????????????????????? 70% (Antiseptic and disinfectant) ??????????????????????????????????? ethanol ?????????????? isopropyl alcohol ??? methanol ??? isopropyl alcohol ???????????????? toxic organic acid metabolite ????????? ??????????????????????????????????????????????????????????????????? (Vd=0.6 L/kg) ??? metabolized ???????????? alcohol dehydrogenase enzyme ??????? acetone
33. Isopropyl alcohol is not metabolized to highly toxic organic acid and not produce anion gap acidosis.
34. Mechanism of toxicity Potent CNS depressant of CNS especially with acetone
Coma and respiratory depression
Very large dose cause hypotension and myocardial depression
Irritate gastrointestinal tract and cause gastritis -???????????????????? ??????????????????????????????????????????????????????????? ???????????????????? coma ??? ?????????? ?????????????????????????? isopropanol ????????????? acetone ??????????????????????????????????????????????????? ????????????????????????????????? isopropanol ??????? ethanol ?????? 2-3 ????
-????????????????????????????? hypotension ????????????????? isopropyl alcohol ????????? vasodilation ??? myocardial depression
-??????????????????????????????????????????????????????????????-???????????????????? ??????????????????????????????????????????????????????????? ???????????????????? coma ??? ?????????? ?????????????????????????? isopropanol ????????????? acetone ??????????????????????????????????????????????????? ????????????????????????????????? isopropanol ??????? ethanol ?????? 2-3 ????
-????????????????????????????? hypotension ????????????????? isopropyl alcohol ????????? vasodilation ??? myocardial depression
-??????????????????????????????????????????????????????????????
35. Toxic dose Ingestion
>0.5-1 mg/kg
> 240 ml fetal dose
Inhalation
40-200 ppm
ACGIH TLV-TWA 400 ppm
2,000 ppm immediately dangerous
36. Clinical presentation Similar to clinical presentation of ethanol toxicity
slurred speech, ataxia, stupor, coma, hypotenion, respiratory depression
GI: abdominal pain and gastritis
CNS: CNS depressant from acetone (metabolite)
37. Diagnostic Smell of isopropanol or acetone
after 1-3 h of ingestion present ketonuria and ketonemia
serum isopropanol level > 150 mg/dl ..coma
???????????? isopropanol ??????????????????????????????????????????? 15-30 ???? ???????????????????????????????? 30-60 ????????????????????????????? ????????????????????????????????????????????? ethanol ???? slurred speech, ataxia, stupor ????????????????????????????????? ??????????????? ?????????? ????????? metabolic acidosis ????????????????? ethanol ???????? osmolar gap ???????????????? ?????????????????????????????????????????????????? acetone (????????????????????????????????????????????? methanol ??? ethylene glycol ???????????????????????????? isopropanol ??????????????????????????????????????????? 15-30 ???? ???????????????????????????????? 30-60 ????????????????????????????? ????????????????????????????????????????????? ethanol ???? slurred speech, ataxia, stupor ????????????????????????????????? ??????????????? ?????????? ????????? metabolic acidosis ????????????????? ethanol ???????? osmolar gap ???????????????? ?????????????????????????????????????????????????? acetone (????????????????????????????????????????????? methanol ??? ethylene glycol ????????????????
38. Treatment Emergency and supportive measurement
No specific antidote
activated charcoal is not effective because isoprapanol is rapidly absorbed.
Dialysis is indicated when level are extremely high (>500 mg/dl) ?????
* ????????????????? ???????????? ????????????
* ????? specific antidote
* ????????? isoproppanol ?????????????????????????? activated charcoal ????????????? isopropanol ????????? 30 ??????????????????????????????????
* Decontamination ????????? isopropanol ????????????????????? ???????????????????????????????????????????????????? ?????? ????????????????????? ????????????????????????????? ???????????????????????????????????????????????? coma ??????????????????? ?????? hemodialysis ?????????????????????????????????????????????????????????? supportive care ???????????????????? isopropanol ?????? (>500-600 mg/ dl) ???????? hypotension ????????????? fluid ??? vasopressor?????
* ????????????????? ???????????? ????????????
* ????? specific antidote
* ????????? isoproppanol ?????????????????????????? activated charcoal ????????????? isopropanol ????????? 30 ??????????????????????????????????
* Decontamination ????????? isopropanol ????????????????????? ???????????????????????????????????????????????????? ?????? ????????????????????? ????????????????????????????? ???????????????????????????????????????????????? coma ??????????????????? ?????? hemodialysis ?????????????????????????????????????????????????????????? supportive care ???????????????????? isopropanol ?????? (>500-600 mg/ dl) ???????? hypotension ????????????? fluid ??? vasopressor
39. Ingredients of antifreeze
intentionally consumed as alcohol substitute by alcoholic
sweet taste ..be careful in children ?????????????????????????????????????????????????????????????? ???? antifreeze ????????????????????????????????????????????????? ethylene glycol ??????????????????????????????????? ???????? ???????? Glycol ?????????????????????????? ethylene glycol ???? diethylene glycol ??????????????????????????????? sulfanilamide elixir ??????????????????????? ??????? ?????????????????? ??????????? ???? liver necrosis, renal tubular degeneration ??????????? ?????????????????????????????????????????????????????????????????????????????????????? ????????????????????? ??????????????????? (Vd =0.8 L/kg) ????????? plasma protein ?????????????????? 17 ??????? ??? metabolized ??? alcohol dehydrogenase enzyme ??????? glycoaldehyde ??????? metabolized ?????????? glycolic, glyoxylic ??? oxalic acid?????????????????????????????????????????????????????????????? ???? antifreeze ????????????????????????????????????????????????? ethylene glycol ??????????????????????????????????? ???????? ???????? Glycol ?????????????????????????? ethylene glycol ???? diethylene glycol ??????????????????????????????? sulfanilamide elixir ??????????????????????? ??????? ?????????????????? ??????????? ???? liver necrosis, renal tubular degeneration ??????????? ?????????????????????????????????????????????????????????????????????????????????????? ????????????????????? ??????????????????? (Vd =0.8 L/kg) ????????? plasma protein ?????????????????? 17 ??????? ??? metabolized ??? alcohol dehydrogenase enzyme ??????? glycoaldehyde ??????? metabolized ?????????? glycolic, glyoxylic ??? oxalic acid
40. And where does this noxious liquid end up after all the cars and trucks seize their last journal bearings? Into the eco-system! It drips out of the radiators upon the fertile junkyard soil, slowly seeping into the streams and aquifers, leading to the rivers and oceans, killing off the plankton that feed the fishies, until finally, the entire food chain is destroyed!�And where does this noxious liquid end up after all the cars and trucks seize their last journal bearings? Into the eco-system! It drips out of the radiators upon the fertile junkyard soil, slowly seeping into the streams and aquifers, leading to the rivers and oceans, killing off the plankton that feed the fishies, until finally, the entire food chain is destroyed!
42. Mechanism of toxicity Metabolic acidosis
oxalate precipitate with calcium to form insoluble calcium oxalate crystal
Tissue injury from deposition of oxalate crystal and toxic effects of glycolic and glyoxylic acids
43. Toxic Metabolize Glycolic acid
severe high anion gap acidosis that develops
Oxalic acid
Precipitation of calcium oxalate crystals in the kidney causes renal failure
45. Toxic dose Lethal dose of 95% ethylene glycol is 1.5 ml/kg.
46. Clinical presentation Stage 1: Intoxication
Up to 12 hours post-ingestion
An ethanol-like intoxicated state (without an appropriate odour on the breath) progressing to CNS depression
A high anion gap metabolic acidosis develops
Nausea, vomiting, arrhythmias and tetany (due to hypocalcaemia) may occur
???????????????????????????? ethylene glycol ????????????? ethanol ??????????????????????????????????????? ??? ?????? ???????? ??????? ????????????????????????????????? ????????????????????????????????????????? ?????????????? calcium oxalate ???????????????????????????? ???????? anion gap ?????????????????? metabolic acidosis ???????????????????????????? ethylene glycol ????????????? ethanol ??????????????????????????????????????? ??? ?????? ???????? ??????? ????????????????????????????????? ????????????????????????????????????????? ?????????????? calcium oxalate ???????????????????????????? ???????? anion gap ?????????????????? metabolic acidosis
47. Stage 2: Cardiorespiratory Changes
From 12 to 24 hours post-ingestion.
Tachycardia, tachypnoea. Shock may occur in major ingestions
48. Stage 3: Renal Toxicity
At 24-72 hrs post-ingestion
Acute anuric renal failure may occur due to precipitation of calcium oxalate crystals in the renal tubules.
49. Diagnosis History of ingestion
oxalate crystal in urine
metabolic acidosis
serum level >50 mg/dl serious toxicity
50. Treatment Emergency and supportive measurement
maintain airway, treat hypocalcemia with IV Ca gluconate
specific antidote
fomepizole and ethanol to saturate the ADH enzyme
pridoxine, folate, thiamine
Hemodialysis when osmolar gap> 10 mOsm/L, with renal failure, serum level> 20-50 mg/dl.
-????????????????? ????????????
-????? fomepizole ???? ethanol ??????????????????????? alcohol dehydrogenase enzyme ????????????????? metabolism ??? ethylene glycol ?????????????????????????????????????? ethylene glycol ??????? 20 mg/dl
-????? pyridoxine, folate, thiamine ???????????????????????????? glyoxylic acid ????????????????????
-???????????? hemodialysis ?????????? ethylene glycol ???????????? metabolic acidosis
Ethanol: "Ethanol blocking" treatment is the traditional treatment but has the disadvantage of causing intoxication (CNS depression). It is also irritant and should be given via a central line.
Fomepizole: This is currently approved for this use in some countries (eg USA and Canada as 'Antizol'). Its advantages are effectiveness, ease of administration and absence of intoxication. Its use may obviate the need for haemodialysis in patients without visual impairment or severe acidosis.
-????????????????? ????????????
-????? fomepizole ???? ethanol ??????????????????????? alcohol dehydrogenase enzyme ????????????????? metabolism ??? ethylene glycol ?????????????????????????????????????? ethylene glycol ??????? 20 mg/dl
-????? pyridoxine, folate, thiamine ???????????????????????????? glyoxylic acid ????????????????????
-???????????? hemodialysis ?????????? ethylene glycol ???????????? metabolic acidosis
Ethanol: "Ethanol blocking" treatment is the traditional treatment but has the disadvantage of causing intoxication (CNS depression). It is also irritant and should be given via a central line.
Fomepizole: This is currently approved for this use in some countries (eg USA and Canada as 'Antizol'). Its advantages are effectiveness, ease of administration and absence of intoxication. Its use may obviate the need for haemodialysis in patients without visual impairment or severe acidosis.
51. Pungent odor gas
Commonly use for the production of urea foam insulation, cloth treated with formaldehyde-containing crease-resistant resin
formalin (formadehyde aqueous solution, 37%) is used as disinfectant and tissue fixative.
Formalin is usually stabilized with 6-15% methanol. ??????????? formaldehyde ?????????????????????? urea formaldehyde ???? insulator ??????????? formaldehyde ???????????? ???? formaldehyde ??????????????? ????????? ???????? ???????????????????????????????? formalin ??????????????? methanol 10-50% ??????????????????? polymerization ??????? formalin ??????????????????????????????????????????????????????????????? ???????????????????????? formaldehyde ?????????????????????? urea formaldehyde ???? insulator ??????????? formaldehyde ???????????? ???? formaldehyde ??????????????? ????????? ???????? ???????????????????????????????? formalin ??????????????? methanol 10-50% ??????????????????? polymerization ??????? formalin ??????????????????????????????????????????????????????????????? ?????????????
53. Mechanism of toxicity Precipitation of protein and cause coagulation necrosis of exposed tissue.
Irritate respiratory tract and spasm of larynx
metabolic acidosis from metabolites..formic acid
carcinogen ?????????????????????????????????????????????????? ???????? formaldehyde ??????????????????? ?????????????????????????????????????????????????????? ??????????????????????????????????????? ??????????????????? (carcinogen) ?????????? metabolite ??? formaldehyde ??? formic acid ???????????????????????????????? metabolic acidosis ???????????? ?????????????????????????????????????????????????? ???????? formaldehyde ??????????????????? ?????????????????????????????????????????????????????? ??????????????????????????????????????? ??????????????????? (carcinogen) ?????????? metabolite ??? formaldehyde ??? formic acid ???????????????????????????????? metabolic acidosis ????????????
54. Toxic dose Inhalation
ACGIH TLV-C is 0.3 ppm (0.37 mg/m3)
> 20 ppm immediately dangerous to life
ingestion
30 ml of 37% formaldehyde solution is reported to death in adult. formaldehyde gas: ???????????????????????????, ??, ???????????????, ??????
????????????: ????????????????????????????????????????????????formaldehyde gas: ???????????????????????????, ??, ???????????????, ??????
????????????: ????????????????????????????????????????????????
55. Clinical presentation Formaldehyde gas
irritate eyes, cough, wheezing, noncardiogenic pulmonary edema
ingestion
severe corrosive esophageal and gastritis injury
lethargy and coma
metabolic acidosis
56. Diagnosis Specific level
formate level
methanol and formate level for formalin solution contained methanol
Other:
Calculate osmolar gap ????????
* ????????????????????????? mucous membrane ??????????????????????????????????????
* ??????????? formate ??? methanol (????????????? formaldehyde) ????????????????????????????????????????????????
* ??? osmolar gap ??????????????????????????????? formic acid ??? methanol????????
* ????????????????????????? mucous membrane ??????????????????????????????????????
* ??????????? formate ??? methanol (????????????? formaldehyde) ????????????????????????????????????????????????
* ??? osmolar gap ??????????????????????????????? formic acid ??? methanol
57. Emergency and supportive measurement
maintain air way to treat bronchospasm
IV saline to replace fluid loss caused by gastroenteritis
NaHCO3 to treat metabolic acidosis
Antidotes
ethanol and folic acid to treat toxicity from formalin solution
folic acid to treat formate intoxication from formaldehyde ????????
*????????????????????????????? ???????????????? bronchospasm
*???????????????????????????????? ?????????????? formaldehyde ?????????????????????????
*?????? sodium bicarbonate ????????? metabolic acidosis
*?????????????? alkalinization ????????????????????????? formate
*?????????????? hemodialysis ??????????? formic acid ?????????????????????? metabolic acidosis ?????????????????? osmolar gap>10 mOsm/L????????
*????????????????????????????? ???????????????? bronchospasm
*???????????????????????????????? ?????????????? formaldehyde ?????????????????????????
*?????? sodium bicarbonate ????????? metabolic acidosis
*?????????????? alkalinization ????????????????????????? formate
*?????????????? hemodialysis ??????????? formic acid ?????????????????????? metabolic acidosis ?????????????????? osmolar gap>10 mOsm/L
58. Treatment (cont) Rescuers should wear self-contained breathing apparatus
remove the victim from exposure and give O2
Do not induce vomiting because of the risk of corrosive injury
hemodialysis when severe acidosis or osmolar gap > 10 mOsm/L
Alkalinization of the urine help promote excretion of formate
59. 6. Acetadehyde (acetic aldehyde) Colorless liquid, fruity odor and irritation
Corrosive
severe burns to eyes and skin
vapors strongly irritating to eyes and respiratory tract
fetal development in animals
carcinogen in test animals
ACGIH TLV 25 ppm
IDLH 2,000 ppm
60. Acetadehyde (cont.) Used with disulfiram cause acetadehyde syndrome
Clinical presentation:
flushing, throbbing headache, dypnea, anxiety, vertigo, vomiting, confusion, orthostatic hypotension
reaction may occur up to several days after the last dose of disulfiram ????????????????????? ???????????? ??????????????????????????????????????? ???????????????????????????? ??????? ???????????????? ????????? ?????????????????????????????? formaldehyde ?????????????????????????????????????????????????? ?????????????????????????????????????????????????
????????? acetadehyde ?????????????????????????????? ?? disulfuram ????????????????????????? ethanol ?????? ??????? disulfiram ????????????????? alcohol dehydrogenase enzyme ????????????? acetadehyde ??????????????????????????????????????????????? acetadehyde syndrome ????????????????????? ????????????? ???????? ??????? ????? ????? ???????????????? ??????????????????????????????????????????????????????????????????? ????????????????????? ???????????? ??????????????????????????????????????? ???????????????????????????? ??????? ???????????????? ????????? ?????????????????????????????? formaldehyde ?????????????????????????????????????????????????? ?????????????????????????????????????????????????
????????? acetadehyde ?????????????????????????????? ?? disulfuram ????????????????????????? ethanol ?????? ??????? disulfiram ????????????????? alcohol dehydrogenase enzyme ????????????? acetadehyde ??????????????????????????????????????????????? acetadehyde syndrome ????????????????????? ????????????? ???????? ??????? ????? ????? ???????????????? ???????????????????????????????????????????????????????????????????
61. Carbon monoxide
Cyanide
62. 1. Carbon monoxide (CO) Colorless, odorless, tasteless, nonirritating gas
"silent killer"
Produced by incomplete combustion of any carbon-containing material
Common source
Smoke inhalation in fire, automobile, exhaust fume, poorly ventilated charcoal, cigarette smoke
methylene chloride
Carbon monoxide can be a "silent killer" on many recreational powerboats. It is a colorless, odorless, tasteless deadly gas that is produced by gasoline engines and generators, cooking ranges, space heaters and water heaters. Cold or poorly tuned engines produce more carbon monoxide than warm, properly tuned engines. The gas enters your blood stream through the lungs and displaces the oxygen your body needs. Early symptoms of carbon monoxide poisoning include irritated eyes, headache, nausea, weakness and dizziness ???????????????????????????? ??????????????????????????? ???????????????????????????????????? ???????????? CO ?????????????????? ??????, ???????????, ??????????????????????????????????????????????, ?????????? ?????????????????? CO ??????? methylene chloride ????????????????????????? CO ???????? ?????????????????????????????????????, ??, ???????? ????????????????????????????? ???? methylene chloride ????????????????????????? CO
???????????????????????????????????????????????????????????????????????????????? ??????????????????????????? ?????????? ??????? ?????????????????????? ?????????????????????????????????? ?????????? ????????????????????????????????????????????????????????????? ???????????????????????????????????????????? Carbon monoxide can be a "silent killer" on many recreational powerboats. It is a colorless, odorless, tasteless deadly gas that is produced by gasoline engines and generators, cooking ranges, space heaters and water heaters. Cold or poorly tuned engines produce more carbon monoxide than warm, properly tuned engines. The gas enters your blood stream through the lungs and displaces the oxygen your body needs. Early symptoms of carbon monoxide poisoning include irritated eyes, headache, nausea, weakness and dizziness ???????????????????????????? ??????????????????????????? ???????????????????????????????????? ???????????? CO ?????????????????? ??????, ???????????, ??????????????????????????????????????????????, ?????????? ?????????????????? CO ??????? methylene chloride ????????????????????????? CO ???????? ?????????????????????????????????????, ??, ???????? ????????????????????????????? ???? methylene chloride ????????????????????????? CO
???????????????????????????????????????????????????????????????????????????????? ??????????????????????????? ?????????? ??????? ?????????????????????? ?????????????????????????????????? ?????????? ????????????????????????????????????????????????????????????? ????????????????????????????????????????????
64. Mechanism of toxicity Reversible bind to hemoglobin (COHb) with affinity 250 times of O2
Directly inhibit cytochrome oxidase .disrupt cell function
bind to myoglobin contribute to impaired myocardial contractility
Damage brain in animal model
systemic hypotension ??????????
????????????????? cellular hypoxia ??? ischemia ??? CO ????????????? cellular hypoxia ?????????????????? ??????
CO ?????? Hemoglobin (Hb) ????????????? Carboxyhemoglobin (COHb) ???? CO ?? affinity ??? Hb ??????? O2 ??? 250 ???? ??????????????????????? oxyhemoglobin ??? Hb ?????????????? O2 ?????????????????????????????? ??? CO ???????? oxyhemoglobin ????????????????? O2 ?????????????????
CO ????????????????????????????? cytochrome oxidase ???????? cellular function ?????????????????? myoglobin ????????? impaired myocardial contractility ????
????????????????????????????????????????????????? ???? ?????????????????????????????????????? CO ?????? ????????????????????????????????????????? ???????????????????? CO ??????????? ischemia ?????? ???????????? systemic hypotension??????????
????????????????? cellular hypoxia ??? ischemia ??? CO ????????????? cellular hypoxia ?????????????????? ??????
CO ?????? Hemoglobin (Hb) ????????????? Carboxyhemoglobin (COHb) ???? CO ?? affinity ??? Hb ??????? O2 ??? 250 ???? ??????????????????????? oxyhemoglobin ??? Hb ?????????????? O2 ?????????????????????????????? ??? CO ???????? oxyhemoglobin ????????????????? O2 ?????????????????
CO ????????????????????????????? cytochrome oxidase ???????? cellular function ?????????????????? myoglobin ????????? impaired myocardial contractility ????
????????????????????????????????????????????????? ???? ?????????????????????????????????????? CO ?????? ????????????????????????????????????????? ???????????????????? CO ??????????? ischemia ?????? ???????????? systemic hypotension
65. Toxic dose ACGIH TLV-TWA 25 ppm as 8 h time weights average
IDLH 1,200 ppm
several minutes of exposure to 1,000 ppm result in 50% saturation of COHb
>80% COHb cause rapidly death
66. Major toxicities are cellular hypoxia and ischemia
67. Toxicokinetic Elimination by breathing
T1/2= 4-5 h
%COHb = 6 L/min x %CO x min of exposure
68. Clinical presentation Predominately in organ with high O2 consumption. brain and heart
headache, dizziness, nausea, rash
Pts with CHD may experience angina or MI
Severe exposure cause impaired thinking, coma, convulsion, cardiac arrhythmia, hypotension, death
Exposure during pregnancy may result in fetal.
??????????? CO ?????????? %COHb ???????????????????????????????????????????? O2 ??????????????????? ?????????????????? COHb ???????? 10% ????????????????? ?????????????????????? COHb ??????? 30-50% ??????????????????????????? ??????????????????????????????????????????????????? (???????? 4)
?????????????? CO ??????????????????????????????? CO ????????????????????? ????????????? ????????????????????????? ????????????????????????????? CO ?????????????????????????? anemia, COPD ???? cardiovascular heart disease ??????????????????? CO ??????? ????????????????????? ?? ???????????????????????????????????????????????????????? ????????????????????????????????????????????? ???????????????????????????????? ??????????????????????????????????????????????????????????????????????????? CO ?????????? %COHb ???????????????????????????????????????????? O2 ??????????????????? ?????????????????? COHb ???????? 10% ????????????????? ?????????????????????? COHb ??????? 30-50% ??????????????????????????? ??????????????????????????????????????????????????? (???????? 4)
?????????????? CO ??????????????????????????????? CO ????????????????????? ????????????? ????????????????????????? ????????????????????????????? CO ?????????????????????????? anemia, COPD ???? cardiovascular heart disease ??????????????????? CO ??????? ????????????????????? ?? ???????????????????????????????????????????????????????? ????????????????????????????????????????????? ???????????????????????????????? ????????????????????????????????????????????????????????????????
69. Diagnosis History of exposure
No specific reliable clinical findings
Cherry red skin coloration or bright venous blood is highly suggestive but not frequently noted.
Specific carboxyhemoglobin concentration
70. Goal of Treatment CO toxicity Decrease cerebral and cardiac ischemia
increase dissociation of COHb
increase elimination rate of CO
71. Emergency and supportive treatment
Maintain airway
treat coma and seizure
Antidote: O2 in highest concentration (100%)
treat until the COHb level <5%
Hyperbaric O2 (2-3 ATM of pressure, T1/2 =20-30 min) use for patient's who do not response to O2 at the ATM
Be careful toxicity of large amount O2 ?????????????????????? ??????, ????????, ????????, ???????, ????????????????????????????????????????????????????, ??????, ????????????????, ???, ??????????????????,???????????????, ?????? ??????????????
??????????? CO ????????????? ?????????????????????????????????(bright cherry red) ?????????????????????? COHb ??????? 25% ???????????????????? ??? ?????
Decontamination ???????????????????????????????????????????????????????????????? ??????????????????????????????????????????????????????????????????
Emergency and supportive measure ??????????????????????????????? ?????????????????????????? ????????????? ECG ???????????????????????????????????????????? ?????????????????????????????? cyanide ???? irritated gas ?????????
Specific drugs and antidote
????????????????????? O2 ???????????????????????????????????????? (100%) ?????????? 100% O2 ???????? half-life ??? COHb ??? 6 ????????????????? 1 ??????? ?????? O2 ?????? COHb ???????????????? 5% ?????? O2 ???????????????????????????? COHb ????????????????????? CO ???
?????? Hyperbaric oxygen ????????? 100% O2 ????????????????? 2-3atm ??????????????????????? CO ??????????? ????????????????????????????????????????? ???? ????????????????? ******???????????????????????????????????????????????????????????????????????????????????????????????????????? tymphanic membrane rupture, damaged sinus******* ?????????????????????? ??????, ????????, ????????, ???????, ????????????????????????????????????????????????????, ??????, ????????????????, ???, ??????????????????,???????????????, ?????? ??????????????
??????????? CO ????????????? ?????????????????????????????????(bright cherry red) ?????????????????????? COHb ??????? 25% ???????????????????? ??? ?????
Decontamination ???????????????????????????????????????????????????????????????? ??????????????????????????????????????????????????????????????????
Emergency and supportive measure ??????????????????????????????? ?????????????????????????? ????????????? ECG ???????????????????????????????????????????? ?????????????????????????????? cyanide ???? irritated gas ?????????
Specific drugs and antidote
????????????????????? O2 ???????????????????????????????????????? (100%) ?????????? 100% O2 ???????? half-life ??? COHb ??? 6 ????????????????? 1 ??????? ?????? O2 ?????? COHb ???????????????? 5% ?????? O2 ???????????????????????????? COHb ????????????????????? CO ???
?????? Hyperbaric oxygen ????????? 100% O2 ????????????????? 2-3atm ??????????????????????? CO ??????????? ????????????????????????????????????????? ???? ????????????????? ******???????????????????????????????????????????????????????????????????????????????????????????????????????? tymphanic membrane rupture, damaged sinus*******
72. 2. Cyanide (hydrocyanic acid / prussic acid) Used as chemical synthesis, laboratory analysis, metal planting
Hydrogen cyanide (HCN)
Cyanide salt + acid
Plastic burn
Amagdalin (cyanogenic glycoside) seeds of apple, peach, plum, cherry, almond
Acrylnitrile, Propylnitrile
Nitroprusside ????????????????????? ???????????? ????????????????????????????????????????????????????????????????????? ??????????? cyanide ?????? ??? aliphatic nitriles ?????????????????????????, ??????????????? (direct vasodilator) ???? nitroprusside ???????????????????? metabolized ??? cyanide ????????????????????????????????????? amygdalin ???????? cyanogenic glycoside ??????????????????? ???, ????, ??????, ????????, ???????? ???????????? metabolized ????????? hydrogen cyanide (HCN) ???????????????????? cyanide ???????????????????????????????????? ???????????????????????????????????? ???????????? ????????????????????????????????????????????????????????????????????? ??????????? cyanide ?????? ??? aliphatic nitriles ?????????????????????????, ??????????????? (direct vasodilator) ???? nitroprusside ???????????????????? metabolized ??? cyanide ????????????????????????????????????? amygdalin ???????? cyanogenic glycoside ??????????????????? ???, ????, ??????, ????????, ???????? ???????????? metabolized ????????? hydrogen cyanide (HCN) ???????????????????? cyanide ???????????????????????????????????? ???????????????
73. Mixing acid+cyanide= HCN gas
combustion by product of burning plastic, wool
Has bitter almond smell
74. Mechanism of toxicity Bind to Fe2+
Bind to cellular cytochrome oxidase
CN- ???????? Fe2+ ????????? cellular hypoxia ????????? cytochrome oxidase ??????????????????????? electron ??? cytochrome ????? O2 ?? mitochrondia ???????????????????????? ATP ?????????????? O2 ???????????? ????????????????? metabolism ???? ????? pyruvate ????????????????? acetyl CoA ???????????? Krebs cycle ??????????????? lactate ????????? metabolic acidosis ?????????? cyanide ??????????????????????????????? O2 ???????????????????? O2 ?????? ??????????????????? CO ????????????????????? O2
?????????? cyanide ?????????? hydrocyanic acid ??????????????????????????????????? bitter almonds ???????? cyanide ???? LD50 ???? 2 mg/kg ????????? cyanide ???????? 50-75 mg ??????????? (syncope) ?????????????????????? 2-3 ???? ???? halogenate cyanide ?????????????????????????????????????????????????????? ???? pulmonary edema ????????????????? ???????CN- ???????? Fe2+ ????????? cellular hypoxia ????????? cytochrome oxidase ??????????????????????? electron ??? cytochrome ????? O2 ?? mitochrondia ???????????????????????? ATP ?????????????? O2 ???????????? ????????????????? metabolism ???? ????? pyruvate ????????????????? acetyl CoA ???????????? Krebs cycle ??????????????? lactate ????????? metabolic acidosis ?????????? cyanide ??????????????????????????????? O2 ???????????????????? O2 ?????? ??????????????????? CO ????????????????????? O2
?????????? cyanide ?????????? hydrocyanic acid ??????????????????????????????????? bitter almonds ???????? cyanide ???? LD50 ???? 2 mg/kg ????????? cyanide ???????? 50-75 mg ??????????? (syncope) ?????????????????????? 2-3 ???? ???? halogenate cyanide ?????????????????????????????????????????????????????? ???? pulmonary edema ????????????????? ???????
75. HCN: well absorbed across the skin
150-200 ppm can be fetal.
IDLH: 50 ppm
ACGIH TLV-C :4.7 ppm (5 mg/m3)
Ingestion
200 mg of Na/K salt
Rare toxicity in nitroprusside infusion or after ingestion amygdalin-containing seeds
Cyanide ???????????????????????????????????????????????? ????? hydrogen cyanide ?????????????????????????? ???????????? cyanide ?????????????????????????????????????????????????????????????????????? ????????? hydrogen cyanide gas (HCN) ???? 150-200 ppm ?????????????????????????????????????????????????? ???????????????????????????? 200 mg ?????????????????????????????????????? Cyanide ???????????????????????????????????????????????? ????? hydrogen cyanide ?????????????????????????? ???????????? cyanide ?????????????????????????????????????????????????????????????????????? ????????? hydrogen cyanide gas (HCN) ???? 150-200 ppm ?????????????????????????????????????????????????? ???????????????????????????? 200 mg ??????????????????????????????????????
76. Clinical presentation Headache, nausea, dypnea, confusion
heavy exposure exposure: syncope, seizure, coma, cardiovascular collapse
77. Diagnosis Lactic acidosis
the elevated of venous O2 saturation
bitter almond smell in some people (depend on genetic variable)
Specific cyanide level
>0.5-1mg/L consider to toxic
Cigarette smokers may have level>0.1mg/L
rapid nitroprusside infusion >1mg/L
78. Treatment Emergency and supportive measure
Specific drugs and antidote
1.cyanide antidote package
amyl and sodium nitrites
produce cyanide-scavenging methemoglobinemia
sodium thiosulfate
conversion cyanide to thiosulfate ????????????????????????? cyanide ??????????????? CN- ?????????????? ?????????????????????? O2 ??? antidote ??? CN- ????????? sulfur transferase enzyme ???? thiosulfate ????????? CN- ???????????? Fe3+ ????????????????????? thiocyanate ???????????????????????????????????? ????????
Sulfur transferase
�Cyanide + thiosulfate thiocyanate + sulfate
???????????????? Cyanide antidote kit ???????? Specific antidote ?????????????????????? cyanide ??????
Amyl nitrite ?????? crushable ampule
Sodium nitrite 3% ?????? injectable solution 300 mg IV
Sodium thiosulfate (25%) 12.5 g IV????????????????????????? cyanide ??????????????? CN- ?????????????? ?????????????????????? O2 ??? antidote ??? CN- ????????? sulfur transferase enzyme ???? thiosulfate ????????? CN- ???????????? Fe3+ ????????????????????? thiocyanate ???????????????????????????????????? ????????
Sulfur transferase
79. Treatment (cont.) 2.Hydroxocobalamin
investigate drug in USA
Decontamination
give O2
remove contaminate with water
activated charcoal
Hemodialysis /hemoperfusion are not indicated.
80. Thank you for your attention
