Acridine SDS

Acute toxicity - Category 4, Oral

H302 Harmful if swallowed

P264 Wash ... thoroughly after handling.

P270 Do not eat, drink or smoke when using this product.

P301+P317 IF SWALLOWED: Get medical help.

P330 Rinse mouth.

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P501 Dispose of contents/container to an appropriate treatment and disposal facility in accordance with applicable laws and regulations, and product characteristics at time of disposal.

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Move the victim into fresh air. If breathing is difficult, give oxygen. If not breathing, give artificial respiration and consult a doctor immediately. Do not use mouth to mouth resuscitation if the victim ingested or inhaled the chemical.

Take off contaminated clothing immediately. Wash off with soap and plenty of water. Consult a doctor.

Rinse with pure water for at least 15 minutes. Consult a doctor.

Rinse mouth with water. Do not induce vomiting. Never give anything by mouth to an unconscious person. Call a doctor or Poison Control Center immediately.

Inhalation irritates respiratory system and causes sneezing, crying, and vomiting. Contact with liquid irritates eyes, skin, and mucous membranes. At high temperature and during sun exposure, damage to the cornea, skin, and mucous membranes may occur following the liberation of acridine vapor. (USCG, 1999)

3. 3= moderately toxic: probable oral lethal dose (human) 0.5-5 g/kg, between 1 oz & 1 pint (or 1 lb) for 70 kg person (150 lb).

Acridine was rapidily accum from water by fathead minnows. equil concn within 24 hr @ concn factor ((acridine)fish,wet wt/(acridine)water) of 125 +/- 10. depuration was rapid. net elimination rate was 0.23/hr (acridine)fish @ equilibrium.

If material on fire or involved in fire: Use water in flooding quantities as fog. Use "alcohol" foam, dry chemical or carbon dioxide. Cool all affected containers with flooding quantities of water. Apply water from as far a distance as possible. Keep run-off water out of sewers and water sources.

Special Hazards of Combustion Products: Toxic oxides of nitrogen may form in fire. Behavior in Fire: Sublimes before melting (USCG, 1999)

Wear self-contained breathing apparatus for firefighting if necessary.

Avoid dust formation. Avoid breathing mist, gas or vapours.Avoid contacting with skin and eye. Use personal protective equipment.Wear chemical impermeable gloves. Ensure adequate ventilation.Remove all sources of ignition. Evacuate personnel to safe areas.Keep people away from and upwind of spill/leak.

Prevent further spillage or leakage if it is safe to do so. Do not let the chemical enter drains. Discharge into the environment must be avoided.

Collect and arrange disposal. Keep the chemical in suitable and closed containers for disposal. Remove all sources of ignition. Use spark-proof tools and explosion-proof equipment. Adhered or collected material should be promptly disposed of, in accordance with appropriate laws and regulations.

Handling in a well ventilated place. Wear suitable protective clothing. Avoid contact with skin and eyes. Avoid formation of dust and aerosols. Use non-sparking tools. Prevent fire caused by electrostatic discharge steam.

Materials which are toxic as stored or which can decompose into toxic components...should be stored in a cool, well ventilated place, out of the direct rays of the sun, away from areas of high fire hazard, and should be periodically inspected. incompatible materials should be isolated...

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Ensure adequate ventilation. Handle in accordance with good industrial hygiene and safety practice. Set up emergency exits and the risk-elimination area.

Wear tightly fitting safety goggles with side-shields conforming to EN 166(EU) or NIOSH (US).

Wear fire/flame resistant and impervious clothing. Handle with gloves. Gloves must be inspected prior to use. Wash and dry hands. The selected protective gloves have to satisfy the specifications of EU Directive 89/686/EEC and the standard EN 374 derived from it.

If the exposure limits are exceeded, irritation or other symptoms are experienced, use a full-face respirator.

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Slightly soluble in hot water.

Volatile with steam

ACRIDINE neutralizes acids in exothermic reactions to form salts plus water. May be incompatible with isocyanates, halogenated organics, peroxides, phenols (acidic), epoxides, anhydrides, and acid halides. Flammable gaseous hydrogen may be generated in combination with strong reducing agents, such as hydrides. Burns to give toxic oxides of nitrogen.

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STABILITY: This chemical undergoes photo-oxidation after irradiation in indoor sunlight or by fluorescent light in organic solvents. Solutions of this chemical in benzene oxidize under the influence of light and air. Solutions of this chemical in water, DMSO, 95% ethanol or acetone should be stable for 24 hours under normal lab conditions.REACTIVITY: This chemical is incompatible with strong oxidizers. It readily undergoes nitration and halogenation. Ozone, chromic acid and chlorinating agents oxidize this compound. This chemical may react with organic and inorganic oxidants including various electrophiles, peroxides, nitrogen oxides and sulfur oxides. Hydrogenation occurs with platinum oxide. (NTP, 1992)

When heated to decomposition, acridine emits toxic fumes.

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EPA-B2, IARC-1, NIOSH-Ca, NTP-R, TLV-A2

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The biodegradation of acridine at concentrations from 0.1 to 20 mg/l was measured in river die-away tests using Green River water; over 11 days this compound was not significantly biodegraded at any measured concentration(1). Acridine at 500 mg/kg soil was measurably present for 83 days in chernozem soil samples at a temperature of 19 deg C(2). A half-life of 3 days in soil was reported for acridine when present at a concentration of 5 mg/kg(3). Acridine, initially present in a groundwater sample at 22.5 ug/ml, was inoculated with creosote-contaminated surface soil; 19, 37, 91.5, 91, and 91% of this compound was biodegraded following 1, 3, 5, 8, and 14 days incubation(4). The sterile control was not degraded over 14 days(4). During solid-phase bioremediation of creosote/PCP contaminated surface soils, unamended soils, containing acridine initially at 46.8 mg/landfarming chamber (3 kg) biodegraded this compound by 83% over 12 weeks(5). In similar experiments using surficial soil, 32% biodegradation was reported over 12 weeks with an initial acridine concentration of 14569.7 mg/landfarming chamber (3 kg)(5). The presence of 9-acridinone in groundwater samples possibly indicates that this compound may be the final product of the biodegradation of acridine in contaminated aquifers(6).

In a static bioconcentration test, a BCF value of 1300 was measured in the guppy, Poecilia reticulata(1). Rate constants for uptake and depuration were 40.8 and 0.031/hour, respectively(1). An equilibrium BCF of 30 was measured for acridine in Daphnia pulex; rate constants for uptake and depuration were 109.6 and 0.47/hour, respectively(2). A BCF value of 126 was measured in fathead minnows(3). Fathead minnows, exposed to 100 ug/L acridine in a flow-through spring water system, rapidly accumulated acridine directly from the water with concentrations of about 12 ug/g wet attained in the fish after 24 hours giving a BCF of 125(4). Further exposure did not result in higher levels of acridine in these fish(4). Rate constants for uptake and depuration were 14 and 0.112/hour, respectively(4). Uncontaminated water rapidly contained measurable concentrations of acridine once minnows containing this compound were added to the water; this suggests that acridine can be eliminated without metabolic alteration as well as through metabolic degradation(4). Minnows exposed to acridine-contaminated sediment and a low level of dissolved acridine did not accumulate much acridine from the sediment(4). According to a classification scheme(5), these BCF values suggest that bioconcentration in aquatic organisms is low to very high depending on the aquatic organism studied(SRC); however, this compound appears to be readily depurated in several organisms. Mussels, Elliptio complanata, did not accumulate detectable concentrations of acridine following three weeks exposure to contaminated sediments in the St. Mary's River in 1985 (detection limit= 1 ug/kg wet weight)(6).

Fourteen soil and sediment samples, collected from the Ohio, Missouri, Mississippi, and Illinois rivers and their watersheds had a wide range in pH (4.54-8.34), total clay (6.8 to 69.1%), organic carbon (0.11 to 2.38%), and expanding clay (2.0 to 60.0%). Koc values for acridine added to these soils/sediments ranged from 5500 to 30,909 with an average value of 12,910(1). According to a recommended classification scheme(2), these measured Koc values suggest that acridine will be immobile in soil(SRC). Adsorption of acridine to silica was measured in a continuous-flow column. The extent of adsorption was greater when the solution pH was below the pKa of acridine(pKa= 5.68(3)) than when it was above(4). Therefore, mobility should be greater in a sand soil when the pH is above the pKa of acridine and adsorption is greatest when the solution pH equals acridine's pKa(4). Sorption of acridine to two low organic carbon subsurface materials with similar properties but different equilibrium pH values when saturated with water was measured(5). Higher sorption was reported for the Loring subsoil (0.24% organic carbon, pH 4.85) than the Anvil Points subsoil (0.58% organic carbon, pH 8.15), consistent with compound ionization and preferential retention of the organic cation over the neutral compound(5).

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The material can be disposed of by removal to a licensed chemical destruction plant or by controlled incineration with flue gas scrubbing. Do not contaminate water, foodstuffs, feed or seed by storage or disposal. Do not discharge to sewer systems.

Containers can be triply rinsed (or equivalent) and offered for recycling or reconditioning. Alternatively, the packaging can be punctured to make it unusable for other purposes and then be disposed of in a sanitary landfill. Controlled incineration with flue gas scrubbing is possible for combustible packaging materials.

ADR/RID: UN2713 (For reference only, please check.)

IMDG: UN2713 (For reference only, please check.)

IATA: UN2713 (For reference only, please check.)

ADR/RID: ACRIDINE (For reference only, please check.)

IMDG: ACRIDINE (For reference only, please check.)

IATA: ACRIDINE (For reference only, please check.)

ADR/RID: 6.1 (For reference only, please check.)

IMDG: 6.1 (For reference only, please check.)

IATA: 6.1 (For reference only, please check.)

ADR/RID: III (For reference only, please check.)

IMDG: III (For reference only, please check.)

IATA: III (For reference only, please check.)

ADR/RID: No

IMDG: No

IATA: No

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