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GLYPHOSINE

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Classification   |    Detailed evidence-based information

Substances Included Synonyms

Therapeutic Toxic Class

    A) Glyphosine is a plant growth regulator used to hasten ripening and increase the level of sucrose in sugar cane (Farm Chem, 1987).

Specific Substances

    1) N,N-bis(phosphonomethyl)glycine
    2) N-carboxymethyl-N,N-bis(methylene
    3) phosphonic acid)amine
    4) Polaris
    5) CP-41845
    6) CAS 2439-99-8

Available Forms Sources

    A) FORMS
    1) Polaris (55% glyphosine) was discontinued by Monsanto in 1984 (Farm Chem, 1987).

Overview

Life Support

    A) This overview assumes that basic life support measures have been instituted.

Clinical Effects

    0.2.1) SUMMARY OF EXPOSURE
    A) Glyphosine is corrosive when applied to rabbit eyes and is expected to be irritating to the gastrointestinal tract.
    0.2.4) HEENT
    A) CORROSIVE - May cause irreversible eye damage.
    0.2.6) RESPIRATORY
    A) Respiratory irritation may be noted.
    0.2.8) GASTROINTESTINAL
    A) Mucosal damage is probable.

Laboratory Monitoring

    A) Monitor for signs and symptoms of gastrointestinal irritation.

Treatment Overview

    0.4.2) ORAL/PARENTERAL EXPOSURE
    A) DILUTION: If no respiratory compromise is present, administer milk or water as soon as possible after ingestion. Dilution may only be helpful if performed in the first seconds to minutes after ingestion. The ideal amount is unknown; no more than 8 ounces (240 mL) in adults and 4 ounces (120 mL) in children is recommended to minimize the risk of vomiting.
    B) Observe patients with ingestion carefully for the possible development of esophageal or gastrointestinal tract irritation or burns. If signs or symptoms of esophageal irritation or burns are present, consider endoscopy to determine the extent of injury.
    0.4.3) INHALATION EXPOSURE
    A) INHALATION: Move patient to fresh air. Monitor for respiratory distress. If cough or difficulty breathing develops, evaluate for respiratory tract irritation, bronchitis, or pneumonitis. Administer oxygen and assist ventilation as required. Treat bronchospasm with an inhaled beta2-adrenergic agonist. Consider systemic corticosteroids in patients with significant bronchospasm.
    0.4.4) EYE EXPOSURE
    A) CAUSTIC EYE DECONTAMINATION: Immediately irrigate each affected eye with copious amounts of water or sterile 0.9% saline for about 30 minutes. Irrigating volumes up to 20 L or more have been used to neutralize the pH. After this initial period of irrigation, the corneal pH may be checked with litmus paper and a brief external eye exam performed. Continue direct copious irrigation with sterile 0.9% saline until the conjunctival fornices are free of particulate matter and returned to pH neutrality (pH 7.4). Once irrigation is complete, a full eye exam should be performed with careful attention to the possibility of perforation.
    B) EYE ASSESSMENT: The extent of eye injury (degree of corneal opacification and perilimbal whitening) may not be apparent for 48 to 72 hours after the burn.
    0.4.5) DERMAL EXPOSURE
    A) OVERVIEW
    1) DECONTAMINATION: Remove contaminated clothing and jewelry and irrigate exposed areas with copious amounts of water. A physician may need to examine the area if irritation or pain persists.

Range Of Toxicity

    A) At the time of this review, no data regarding minimum lethal dose or maximum tolerated exposure are available.

Clinical Effects

Summary Of Exposure

    A) Glyphosine is corrosive when applied to rabbit eyes and is expected to be irritating to the gastrointestinal tract.

Heent

    3.4.1) SUMMARY
    A) CORROSIVE - May cause irreversible eye damage.
    3.4.3) EYES
    A) CORROSIVE - May cause irreversible eye damage (Prod Info, 1983).

Respiratory

    3.6.1) SUMMARY
    A) Respiratory irritation may be noted.
    3.6.2) CLINICAL EFFECTS
    A) IRRITATION SYMPTOM
    1) Respiratory irritation may be noted (Prod Info, 1983).

Neurologic

    3.7.2) CLINICAL EFFECTS
    A) NEUROLOGICAL FINDING
    1) LACK OF EFFECT
    a) Tests indicated that glyphosine did not cause any neurotoxic effects (Prod Info, 1983).

Gastrointestinal

    3.8.1) SUMMARY
    A) Mucosal damage is probable.
    3.8.2) CLINICAL EFFECTS
    A) CHEMICAL BURN OF ORAL MUCOSA
    1) Mucosal damage is probable (Prod Info, 1983).
    3.8.3) ANIMAL EFFECTS
    A) ANIMAL STUDIES
    1) DIARRHEA
    a) Animals developed symptoms of reduced activity, weakness, diarrhea, and collapse ((Suppl 141)).

Dermatologic

    3.14.3) ANIMAL EFFECTS
    A) ANIMAL STUDIES
    1) IRRITATION
    a) Skin irritation may be noted, but was non-irritating to rabbit skin (Prod Info, 1983).

Immunologic

    3.19.3) ANIMAL EFFECTS
    A) ANIMAL STUDIES
    1) LEUKOPENIA
    a) MICE - Administration of a diet containing 1, 20, or 80 mg/kg of glyphosine to mice resulted in decreased white blood cell count. At the 80 mg/kg dose spleen plaque forming cell assay was reduced by 23%. The clinical significance of these effects on immune function is unknown (Olson & Hinsdill, 1984).

Carcinogenicity

    3.21.1) IARC CATEGORY
    A) IARC Carcinogenicity Ratings for CAS2439-99-8 (International Agency for Research on Cancer (IARC), 2016; International Agency for Research on Cancer, 2015; IARC Working Group on the Evaluation of Carcinogenic Risks to Humans, 2010; IARC Working Group on the Evaluation of Carcinogenic Risks to Humans, 2010a; IARC Working Group on the Evaluation of Carcinogenic Risks to Humans, 2008; IARC Working Group on the Evaluation of Carcinogenic Risks to Humans, 2007; IARC Working Group on the Evaluation of Carcinogenic Risks to Humans, 2006; IARC, 2004):
    1) Not Listed
    3.21.4) ANIMAL STUDIES
    A) LACK OF EFFECT
    1) Tests showed that glyphosine did not cause any carcinogenic effects (Prod Info, 1983).

Laboratory Monitoring

Monitoring Parameters Levels

    4.1.1) SUMMARY
    A) Monitor for signs and symptoms of gastrointestinal irritation.

Treatment

Life Support

    A) Support respiratory and cardiovascular function.

Monitoring

    A) Monitor for signs and symptoms of gastrointestinal irritation.

Oral Exposure

    6.5.1) PREVENTION OF ABSORPTION/PREHOSPITAL
    A) DILUTION -
    1) DILUTION: If no respiratory compromise is present, administer milk or water as soon as possible after ingestion. Dilution may only be helpful if performed in the first seconds to minutes after ingestion. The ideal amount is unknown; no more than 8 ounces (240 mL) in adults and 4 ounces (120 mL) in children is recommended to minimize the risk of vomiting.
    B) EMESIS/NOT RECOMMENDED -
    1) Emesis is NOT recommended due to the potential risk of developing esophageal or gastrointestinal tract irritation or burns.
    6.5.2) PREVENTION OF ABSORPTION
    A) DILUTION
    1) DILUTION: If no respiratory compromise is present, administer milk or water as soon as possible after ingestion. Dilution may only be helpful if performed in the first seconds to minutes after ingestion. The ideal amount is unknown; no more than 8 ounces (240 mL) in adults and 4 ounces (120 mL) in children is recommended to minimize the risk of vomiting (Caravati, 2004).
    6.5.3) TREATMENT
    A) IRRITATION SYMPTOM
    1) Observe patients with ingestion carefully for the possible development of esophageal or gastrointestinal tract irritation or burns. If signs or symptoms of esophageal irritation or burns are present, consider endoscopy to determine the extent of injury.
    B) ENDOSCOPIC PROCEDURE
    1) There is little information regarding the use of endoscopy, corticosteroids or surgery in the setting of concentrated glyphosine ingestion. The following information is derived from experience with other corrosives.
    2) SUMMARY: Obtain consultation concerning endoscopy as soon as possible, and perform endoscopy within the first 24 hours when indicated.
    3) INDICATIONS: Endoscopy should be performed in adults with a history of deliberate ingestion, adults with any signs or symptoms attributable to inadvertent ingestion, and in children with stridor, vomiting, or drooling after unintentional ingestion (Crain et al, 1984). Endoscopy should also be performed in children with dysphagia or refusal to swallow, significant oral burns, or abdominal pain after unintentional ingestion (Gaudreault et al, 1983; Nuutinen et al, 1994). Children and adults who are asymptomatic after accidental ingestion do not require endoscopy (Gupta et al, 2001; Lamireau et al, 2001; Gorman et al, 1992).
    4) RISKS: Numerous large case series attest to the relative safety and utility of early endoscopy in the management of caustic ingestion.
    a) REFERENCES: (Dogan et al, 2006; Symbas et al, 1983; Crain et al, 1984a; Gaudreault et al, 1983a; Schild, 1985; Moazam et al, 1987; Sugawa & Lucas, 1989; Previtera et al, 1990; Zargar et al, 1991; Vergauwen et al, 1991; Gorman et al, 1992)
    5) The risk of perforation during endoscopy is minimized by (Zargar et al, 1991):
    a) Advancing across the cricopharynx under direct vision
    b) Gently advancing with minimal air insufflation
    c) Never retroverting or retroflexing the endoscope
    d) Using a pediatric flexible endoscope
    e) Using extreme caution in advancing beyond burn lesion areas
    f) Most authors recommend endoscopy within the first 24 hours of injury, not advancing the endoscope beyond areas of severe esophageal burns, and avoiding endoscopy during the subacute phase of healing when tissue slough increases the risk of perforation (5 to 15 days after ingestion) (Zargar et al, 1991).
    6) GRADING
    a) Several scales for grading caustic injury exist. The likelihood of complications such as strictures, obstruction, bleeding, and perforation is related to the severity of the initial burn (Zargar et al, 1991):
    b) Grade 0 - Normal examination
    c) Grade 1 - Edema and hyperemia of the mucosa; strictures unlikely.
    d) Grade 2A - Friability, hemorrhages, erosions, blisters, whitish membranes, exudates and superficial ulcerations; strictures unlikely.
    e) Grade 2B - Grade 2A plus deep discreet or circumferential ulceration; strictures may develop.
    f) Grade 3A - Multiple ulcerations and small scattered areas of necrosis; strictures are common, complications such as perforation, fistula formation or gastrointestinal bleeding may occur.
    g) Grade 3B - Extensive necrosis through visceral wall; strictures are common, complications such as perforation, fistula formation, or gastrointestinal bleeding are more likely than with 3A.
    7) FOLLOW UP - If burns are found, follow 10 to 20 days later with barium swallow or esophagram.
    8) SCINTIGRAPHY - Scans utilizing radioisotope labelled sucralfate (technetium 99m) were performed in 22 patients with caustic ingestion and compared with endoscopy for the detection of esophageal burns. Two patients had minimal residual isotope activity on scanning but normal endoscopy and two patients had normal activity on scan but very mild erythema on endoscopy. Overall the radiolabeled sucralfate scan had a sensitivity of 100%, specificity of 81%, positive predictive value of 84% and negative predictive value of 100% for detecting clinically significant burns in this population (Millar et al, 2001). This may represent an alternative to endoscopy, particularly in young children, as no sedation is required for this procedure. Further study is required.
    9) MINIPROBE ULTRASONOGRAPHY - was performed in 11 patients with corrosive ingestion . Findings were categorized as grade 0 (distinct muscular layers without thickening, grade I (distinct muscular layers with thickening), grade II (obscured muscular layers with indistinct margins) and grade III (muscular layers that could not be differentiated). Findings were further categorized as to whether the worst appearing image involved part of the circumference (type a) or the whole circumference (type b). Strictures did not develop in patients with grade 0 (5 patients) or grade I (4 patients) lesions. Transient stricture formation developed in the only patient with grade IIa lesions, and stricture requiring repeated dilatation developed in the only patient with grade IIIb lesions (Kamijo et al, 2004).
    C) CORTICOSTEROID
    1) CORROSIVE INGESTION/SUMMARY: The use of corticosteroids for the treatment of caustic ingestion is controversial. Most animal studies have involved alkali-induced injury (Haller & Bachman, 1964; Saedi et al, 1973). Most human studies have been retrospective and generally involve more alkali than acid-induced injury and small numbers of patients with documented second or third degree mucosal injury.
    2) FIRST DEGREE BURNS: These burns generally heal well and rarely result in stricture formation (Zargar et al, 1989; Howell et al, 1992). Corticosteroids are generally not beneficial in these patients (Howell et al, 1992).
    3) SECOND DEGREE BURNS: Some authors recommend corticosteroid treatment to prevent stricture formation in patients with a second degree, deep-partial thickness burn (Howell et al, 1992). However, no well controlled human study has documented efficacy. Corticosteroids are generally not beneficial in patients with a second degree, superficial-partial thickness burn (Caravati, 2004; Howell et al, 1992).
    4) THIRD DEGREE BURNS: Some authors have recommended steroids in this group as well (Howell et al, 1992). A high percentage of patients with third degree burns go on to develop strictures with or without corticosteroid therapy and the risk of infection and perforation may be increased by corticosteroid use. Most authors feel that the risk outweighs any potential benefit and routine use is not recommended (Boukthir et al, 2004; Oakes et al, 1982; Pelclova & Navratil, 2005).
    5) CONTRAINDICATIONS: Include active gastrointestinal bleeding and evidence of gastric or esophageal perforation. Corticosteroids are thought to be ineffective if initiated more than 48 hours after a burn (Howell, 1987).
    6) DOSE: Administer daily oral doses of 0.1 milligram/kilogram of dexamethasone or 1 to 2 milligrams/kilogram of prednisone. Continue therapy for a total of 3 weeks and then taper (Haller et al, 1971; Marshall, 1979). An alternative regimen in children is intravenous prednisolone 2 milligrams/kilogram/day followed by 2.5 milligrams/kilogram/day of oral prednisone for a total of 3 weeks then tapered (Anderson et al, 1990).
    7) ANTIBIOTICS: Animal studies suggest that the addition of antibiotics can prevent the infectious complications associated with corticosteroid use in the setting of caustic burns. Antibiotics are recommended if corticosteroids are used or if perforation or infection is suspected. Agents that cover anaerobes and oral flora such as penicillin, ampicillin, or clindamycin are appropriate (Rosenberg et al, 1953).
    8) STUDIES
    a) ANIMAL
    1) Some animal studies have suggested that corticosteroid therapy may reduce the incidence of stricture formation after severe alkaline corrosive injury (Haller & Bachman, 1964; Saedi et al, 1973a).
    2) Animals treated with steroids and antibiotics appear to do better than animals treated with steroids alone (Haller & Bachman, 1964).
    3) Other studies have shown no evidence of reduced stricture formation in steroid treated animals (Reyes et al, 1974). An increased rate of esophageal perforation related to steroid treatment has been found in animal studies (Knox et al, 1967).
    b) HUMAN
    1) Most human studies have been retrospective and/or uncontrolled and generally involve small numbers of patients with documented second or third degree mucosal injury. No study has proven a reduced incidence of stricture formation from steroid use in human caustic ingestions (Haller et al, 1971; Hawkins et al, 1980; Yarington & Heatly, 1963; Adam & Brick, 1982).
    2) META ANALYSIS
    a) Howell et al (1992), analyzed reports concerning 361 patients with corrosive esophageal injury published in the English language literature since 1956 (10 retrospective and 3 prospective studies). No patients with first degree burns developed strictures. Of 228 patients with second or third degree burns treated with corticosteroids and antibiotics, 54 (24%) developed strictures. Of 25 patients with similar burn severity treated without steroids or antibiotics, 13 (52%) developed strictures (Howell et al, 1992).
    b) Another meta-analysis of 10 studies found that in patients with second degree esophageal burns from caustics, the overall rate of stricture formation was 14.8% in patients who received corticosteroids compared with 36% in patients who did not receive corticosteroids (LoVecchio et al, 1996).
    c) Another study combined results of 10 papers evaluating therapy for corrosive esophageal injury in humans published between January 1991 and June 2004. There were a total of 572 patients, all patients received corticosteroids in 6 studies, in 2 studies no patients received steroids, and in 2 studies, treatment with and without corticosteroids was compared. Of 109 patients with grade 2 esophageal burns who were treated with corticosteroids, 15 (13.8%) developed strictures, compared with 2 of 32 (6.3%) patients with second degree burns who did not receive steroids (Pelclova & Navratil, 2005).
    3) Smaller studies have questioned the value of steroids (Ferguson et al, 1989; Anderson et al, 1990), thus they should be used with caution.
    4) Ferguson et al (1989) retrospectively compared 10 patients who did not receive antibiotics or steroids with 31 patients who received both antibiotics and steroids in a study of caustic ingestion and found no difference in the incidence of esophageal stricture between the two groups (Ferguson et al, 1989).
    5) A randomized, controlled, prospective clinical trial involving 60 children with lye or acid induced esophageal injury did not find an effect of corticosteroids on the incidence of stricture formation (Anderson et al, 1990).
    a) These 60 children were among 131 patients who were managed and followed-up for ingestion of caustic material from 1971 through 1988; 88% of them were between 1 and 3 years old (Anderson et al, 1990).
    b) All patients underwent rigid esophagoscopy after being randomized to receive either no steroids or a course consisting initially of intravenous prednisolone (2 milligrams/kilogram per day) followed by 2.5 milligrams/kilogram/day of oral prednisone for a total of 3 weeks prior to tapering and discontinuation (Anderson et al, 1990).
    c) Six (19%), 15 (48%), and 10 (32%) of those in the treatment group had first, second and third degree esophageal burns, respectively. In contrast, 13 (45%), 5 (17%), and 11 (38%) of the control group had the same levels of injury (Anderson et al, 1990).
    d) Ten (32%) of those receiving steroids and 11 (38%) of the control group developed strictures. Four (13%) of those receiving steroids and 7 (24%) of the control group required esophageal replacement. All but 1 of the 21 children who developed strictures had severe circumferential burns on initial esophagoscopy (Anderson et al, 1990).
    e) Because of the small numbers of patients in this study, it lacked the power to reliably detect meaningful differences in outcome between the treatment groups (Anderson et al, 1990).
    6) ADVERSE EFFECTS
    a) The use of corticosteroids in the treatment of caustic ingestion in humans has been associated with gastric perforation (Cleveland et al, 1963) and fatal pulmonary embolism (Aceto et al, 1970).
    D) SURGICAL PROCEDURE
    1) SUMMARY: Initially if severe esophageal burns are found a string may be placed in the stomach to facilitate later dilation. Insertion of a specialized nasogastric tube after confirmation of a circumferential burn may prevent strictures. Dilation is indicated after 2 to 4 weeks if strictures are confirmed. If dilation is unsuccessful colonic intraposition or gastric tube placement may be needed. Early laparotomy should be considered in patients with evidence of severe esophageal or gastric burns on endoscopy.
    2) STRING - If a second degree or circumferential burn of the esophagus is found a string may be placed in the stomach to avoid false channel and to provide a guide for later dilation procedures (Gandhi et al, 1989).
    3) STENT - The insertion of a specialized nasogastric tube or stent immediately after endoscopically proven deep circumferential burns is preferred by some surgeons to prevent stricture formation (Mills et al, 1978; (Wijburg et al, 1985; Coln & Chang, 1986).
    a) STUDY - In a study of 11 children with deep circumferential esophageal burns after caustic ingestion, insertion of a silicone rubber nasogastric tube for 5 to 6 weeks without steroids or antibiotics was associated with stricture formation in only one case (Wijburg et al, 1989).
    4) DILATION - Dilation should be performed at 1 to 4 week intervals when stricture is present(Gundogdu et al, 1992). Repeated dilation may be required over many months to years in some patients. Successful dilation of gastric antral strictures has also been reported (Hogan & Polter, 1986; Treem et al, 1987).
    5) COLONIC REPLACEMENT - Intraposition of colon may be necessary if dilation fails to provide an adequate sized esophagus (Chiene et al, 1974; Little et al, 1988; Huy & Celerier, 1988).
    6) LAPAROTOMY/LAPAROSCOPY - Several authors advocate laparotomy or laparoscopy in patients with endoscopic evidence of severe esophageal or gastric burns to evaluate for the presence of transmural gastric or esophageal necrosis (Cattan et al, 2000; Estrera et al, 1986; Meredith et al, 1988; Wu & Lai, 1993).
    a) STUDY - In a retrospective study of patients with extensive transmural esophageal necrosis after caustic ingestion, all 4 patients treated in the conventional manner (esophagoscopy, steroids, antibiotics, and repeated evaluation for the occurrence of esophagogastric necrosis and perforation) died while all 3 patients treated with early laparotomy and immediate esophagogastric resection survived (Estrera et al, 1986).

Inhalation Exposure

    6.7.1) DECONTAMINATION
    A) Move patient from the toxic environment to fresh air. Monitor for respiratory distress. If cough or difficulty in breathing develops, evaluate for hypoxia, respiratory tract irritation, bronchitis, or pneumonitis.
    B) OBSERVATION: Carefully observe patients with inhalation exposure for the development of any systemic signs or symptoms and administer symptomatic treatment as necessary.
    C) INITIAL TREATMENT: Administer 100% humidified supplemental oxygen, perform endotracheal intubation and provide assisted ventilation as required. Administer inhaled beta-2 adrenergic agonists, if bronchospasm develops. Consider systemic corticosteroids in patients with significant bronchospasm (National Heart,Lung,and Blood Institute, 2007). Exposed skin and eyes should be flushed with copious amounts of water.

Eye Exposure

    6.8.1) DECONTAMINATION
    A) IRRIGATION
    1) Begin irrigation immediately with copious amounts of water or sterile 0.9% saline, which ever is more rapidly available. Lactated Ringer's solution may also be effective. Once irrigation has begun, instill a drop of local anesthetic (eg, 0.5% proparacaine) for comfort; switching from water to slightly warmed sterile saline may also improve patient comfort (Singh et al, 2013; Spector & Fernandez, 2008; Ernst et al, 1998; Grant & Schuman, 1993). In one study, isotonic saline, lactated Ringer's solution, normal saline with bicarbonate, and balanced saline plus (BSS Plus) were compared and no difference in normalization of pH were found; however, BSS Plus was better tolerated and more comfortable (Fish & Davidson, 2010).
    a) Continue irrigation for at least an hour or until the superior and inferior cul-de-sacs have returned to neutrality (check pH every 30 minutes), pH of 7.0 to 8.0, and remain so for 30 minutes after irrigation is discontinued (Spector & Fernandez, 2008; Brodovsky et al, 2000). After severe alkaline burns, the pH of the conjunctival sac may only return to a pH of 8 or 8.5 even after extensive irrigation (Grant & Schuman, 1993). Irrigating volumes up to 20 L or more have been used to neutralize the pH (Singh et al, 2013; Fish & Davidson, 2010). Immediate and prolonged irrigation is associated with improved visual acuity, shorter hospital stay and fewer surgical interventions (Kuckelkorn et al, 1995; Saari et al, 1984).
    b) Search the conjunctival sac for solid particles and remove them while continuing irrigation (Grant & Schuman, 1993).
    c) For significant alkaline or concentrated acid burns with evidence of eye injury irrigation should be continued for at least 2 to 3 hours, potentially as long as 24 to 48 hours if pH not normalized, in an attempt to normalize the pH of the anterior chamber (Smilkstein & Fraunfelder, 2002). Emergent ophthalmologic consultation is needed in these cases (Spector & Fernandez, 2008).
    6.8.2) TREATMENT
    A) INJURY OF GLOBE OF EYE
    1) EVALUATION
    a) ASSESSMENT CAUSTIC EYE BURNS: It may take 48 to 72 hours after the burn to assess correctly the degree of ocular damage (Brodovsky et al, 2000a).
    b) The 1965 Roper-Hall classification uses the size of the corneal epithelial defect, the degree of corneal opacification and extent of limbal ischemia to evaluate the extent of the chemical ocular injury (Brodovsky et al, 2000a; Singh et al, 2013):
    1) GRADE 1 (prognosis good): Corneal epithelial damage; no limbal ischemia.
    2) GRADE 2 (prognosis good): Cornea hazy; iris details visible, ischemia less than one-third of limbus.
    3) GRADE 3 (prognosis guarded): Total loss of corneal epithelium; stromal haze obscures iris details; ischemia of one-third to one-half of limbus.
    4) GRADE 4 (prognosis poor): Cornea opaque; iris and pupil obscured, ischemia affects more than one-half of limbus.
    c) A newer classification (Dua) is based on clock hour limbal involvement as well as a percentage of bulbar conjunctival involvement (Singh et al, 2013):
    1) GRADE 1 (prognosis very good): 0 clock hour of limbal involvement and 0% conjunctival involvement.
    2) GRADE 2 (prognosis good): Less than 3 clock hour of limbal involvement and less than 30% conjunctival involvement.
    3) GRADE 3 (prognosis good): Greater than 3 and up to 6 clock hour of limbal involvement and greater than 30% to 50% conjunctival involvement.
    4) GRADE 4 (prognosis good to guarded): Greater than 6 and up to 9 clock hour of limbal involvement and greater than 50% to 75% conjunctival involvement.
    5) GRADE 5 (prognosis guarded to poor): Greater than 9 and less than 12 clock hour of limbal involvement and greater than 75% and less than 100% conjunctival involvement.
    6) GRADE 6 (very poor): Total limbus (12 clock hour) involved and 100% conjunctival involvement.
    2) MINOR INJURY
    a) SUMMARY
    1) If ocular damage is minor, artificial tears/lubricants, topical cycloplegics, and antibiotics may be all that are needed.
    b) ARTIFICIAL TEARS
    1) To promote re-epithelization, preservative-free artificial tears/lubricants (eg, hyaluronic acid hourly) may be used (Fish & Davidson, 2010; Tuft & Shortt, 2009).
    c) TOPICAL CYCLOPLEGIC
    1) Use to guard against development of posterior synechiae and ciliary spasm (Brodovsky et al, 2000b; Grant & Schuman, 1993). Cyclopentolate 0.5% or 1% eye drops may be administered 4 times daily to control pain (Tuft & Shortt, 2009; Spector & Fernandez, 2008).
    d) TOPICAL ANTIBIOTICS
    1) An antibiotic ophthalmic ointment or drops should be used for as long as epithelial defects persist (Brodovsky et al, 2000b; Grant & Schuman, 1993). Topical erythromycin or tetracycline ointment may be used (Spector & Fernandez, 2008).
    e) PAIN CONTROL
    1) If pain control is required, oral or parenteral NSAIDs or narcotics are preferred to topical ocular anesthetics, which may cause local corneal epithelial damage if used repeatedly (Spector & Fernandez, 2008; Grant & Schuman, 1993). However, topical 0.5% proparacaine has been recommended (Spector & Fernandez, 2008).
    3) SEVERE INJURY
    a) SUMMARY
    1) If the damage is minor, the above may be all that is needed. For grade 3 or 4 injuries, one or more of the following may be used, only with ophthalmologic consultation: acetazolamide, topical timolol, topical steroids, citrate, ascorbate, EDTA, cysteine, NAC, penicillamine, tetracycline, or soft contact lenses.
    b) ARTIFICIAL TEARS
    1) To promote re-epithelization, preservative-free artificial tears/lubricants (eg, hyaluronic acid hourly) may be used (Fish & Davidson, 2010; Tuft & Shortt, 2009).
    c) PAIN CONTROL
    1) If pain control is required, oral or parenteral NSAIDs or narcotics are preferred to topical ocular anesthetics, which may cause local corneal epithelial damage if used repeatedly (Spector & Fernandez, 2008; Grant & Schuman, 1993). However, topical 0.5% proparacaine has been recommended (Spector & Fernandez, 2008).
    d) CARBONIC ANHYDRASE INHIBITOR
    1) Acetazolamide (250 mg orally 4 times daily) may be given to control increased intraocular pressure (Singh et al, 2013; Tuft & Shortt, 2009; Spector & Fernandez, 2008).
    e) TOPICAL STEROIDS
    1) DOSE: Dexamethasone 0.1% ointment 4 times daily to reduce inflammation. If persistent epithelial defect is present, discontinue dexamethasone by day 14 to reduce the risk of stromal melt (Tuft & Shortt, 2009). Other sources suggest that corticosteroids should be stopped if the epithelium has not covered surface defects by 5 to 7 days (Grant & Schuman, 1993a).
    2) Topical prednisolone 0.5% has also been used. A further increase in corneoscleral melt may occur if topical steroids are used alone. In one study, topical prednisolone 0.5% was used in combination with topical ascorbate 10%; no increase in corneoscleral melt was observed when topical steroids were used until re-epithelization (Singh et al, 2013; Fish & Davidson, 2010).
    3) In one retrospective study, fluorometholone 1% drops were administered every 2 hours initially, then decreased to four times daily when there was evidence of progressive corneal reepithelialization and lessened inflammation, and discontinued when corneal reepithelialization was complete (Brodovsky et al, 2000).
    a) STUDY: The combination of intensive topical corticosteroids, topical citrate and ascorbate, and oral citrate and ascorbate was associated with improved best corrected visual acuity and a trend towards more rapid corneal reepithelialization in Grade 3 alkali burns in one retrospective study (Brodovsky et al, 2000).
    f) ASCORBATE
    1) Oral or topical ascorbate may be used to promote epithelial healing and reduce the risk of stromal necrosis (Fish & Davidson, 2010).
    2) DOSE: Ascorbate 10% 4 times daily topically or 1 g orally (2 g/day) (Singh et al, 2013; Tuft & Shortt, 2009).
    3) Ascorbate is needed for the formation of collagen and the concentration of ascorbate in the anterior chamber is decreased when the ciliary body is damaged by alkali burns (Tuft & Shortt, 2009; Grant & Schuman, 1993a). In one retrospective study, ascorbate drops (10%) were administered every 2 hours, then decreased to 4 times a day when there was evidence of progressive corneal reepithelialization and lessened inflammation, and discontinued when corneal reepithelialization was complete. These patients also received 500 mg of oral ascorbate 4 times daily, until discharge from the hospital (Brodovsky et al, 2000).
    a) STUDY: The combination of intensive topical corticosteroids, topical citrate and ascorbate, and oral citrate and ascorbate was associated with improved best corrected visual acuity and a trend towards more rapid corneal reepithelialization in Grade 3 alkali burns in one retrospective study (Brodovsky et al, 2000).
    g) CITRATE
    1) Topical citrate may be used to promote epithelial healing and reduce the risk of stromal necrosis (Fish & Davidson, 2010).
    2) DOSE: Potassium citrate 10% 4 times daily topically (Tuft & Shortt, 2009).
    3) Citrate chelates calcium, and thereby interferes with the harmful effects of neutrophil accumulation, such as release of proteolytic enzymes and superoxide free radicals, phagocytosis and ulceration (Grant & Schuman, 1993a). In one retrospective study, 10% citrate drops were administered every 2 hours, then decreased to 4 times a day when there was evidence of progressive corneal reepithelialization and lessened inflammation, and discontinued when corneal reepithelialization was complete. These patients also received a urinary alkalinizer containing 720 mg of citric acid anhydrous and 630 mg of sodium citrate anhydrous 3 times daily, until discharge from the hospital (Brodovsky et al, 2000).
    a) STUDY: The combination of intensive topical corticosteroids, topical citrate and ascorbate, and oral citrate and ascorbate was associated with improved best corrected visual acuity and a trend towards more rapid corneal reepithelialization in Grade 3 alkali burns in one retrospective study (Brodovsky et al, 2000).
    h) COLLAGENASE INHIBITORS
    1) Inhibitors of collagenase can inhibit collagenolytic activity, prevent stromal ulceration, and promote wound healing. Several effective agents, such as cysteine, n-acetylcysteine, sodium ethylenediamine tetra acetic acid (EDTA), calcium EDTA, penicillamine, and citrate, have been recommended (Singh et al, 2013; Tuft & Shortt, 2009; Perry et al, 1993; Seedor et al, 1987).
    2) TETRACYCLINE: Has been found to have an anticollagenolytic effect. Systemic tetracycline 50 mg/kg/day reduced the incidence of alkali-induced corneal ulcerations in rabbits (Seedor et al, 1987).
    3) DOXYCYCLINE: Decreased epithelial defects and collagenase activity in a rabbit model of alkali burns to the eye (Perry et al, 1993). DOSE: 100 mg twice daily (Tuft & Shortt, 2009).
    i) ANTIBIOTICS
    1) An antibiotic ophthalmic ointment or drops should be used for as long as epithelial defects persist (Brodovsky et al, 2000b; Grant & Schuman, 1993). Topical erythromycin or tetracycline ointment may be used (Spector & Fernandez, 2008). In patients with severe burns, a topical fluoroquinolone antibiotic drop 4 times daily may also be used (Tuft & Shortt, 2009). A topical fourth generation fluoroquinolone has been recommended as an antimicrobial prophylaxis in patients with large epithelial defect (Fish & Davidson, 2010).
    j) TOPICAL CYCLOPLEGIC
    1) Cyclopentolate 0.5% or 1% eye drops may be administered 4 times daily to control pain (Tuft & Shortt, 2009; Spector & Fernandez, 2008).
    k) SOFT CONTACT LENSES
    1) A bandage contact lens (eg, silicone hydrogel) may make the patient more comfortable and protect the surface (Fish & Davidson, 2010; Tuft & Shortt, 2009). Hydrophilic high oxygen permeability lenses are preferred (Singh et al, 2013). Soft lenses with intermediate water content and inherent rigidity may facilitate reepithelialization. The use of 0.5 normal sodium chloride drops hourly and artificial tears or lubricant eyedrops instilled 4 times a day may help maintain adequate hydration and lens mobility.
    4) SURGICAL THERAPY
    a) SURGICAL THERAPY CAUSTIC EYE INJURY
    1) Early insertion of methylmethacrylate ring or suturing saran wrap over palpebral and cul-de-sac conjunctiva may prevent fibrinosis adhesions and reduce fibrotic contracture of conjunctiva, but the advantage of such treatments is not clear.
    2) Limbal stem cell transplantation has been used successfully in both the acute stage of injury and the chronically scarred healing phase in patients with persistent epithelial defects after chemical burns (Azuara-Blanco et al, 1999; Morgan & Murray, 1996; Ronk et al, 1994).
    3) In some patients, amniotic membrane transplantation (AMT) has been successful in improving corneal healing and visual acuity in patients with persistent epithelial defects after chemical burns. It can restore the conjunctival surface and decrease limbal stromal inflammation (Fish & Davidson, 2010; Sridhar et al, 2000; Su & Lin, 2000; Meller et al, 2000; Azuara-Blanco et al, 1999).
    4) Control glaucoma. Remove any cataracts formed (Fish & Davidson, 2010; Tuft & Shortt, 2009).
    5) In patients with severe injury, tenonplasty can be performed to promote epithelialization and prevent melting (Tuft & Shortt, 2009).
    6) A keratoprosthesis placement has also been indicated in severe cases (Fish & Davidson, 2010). Penetrating keratoplasty is usually delayed as long as possible as results appear to be better with a greater lag time between injury and keratoplasty (Grant & Schuman, 1993).
    B) Treatment should include recommendations listed in the ORAL EXPOSURE section when appropriate.

Dermal Exposure

    6.9.1) DECONTAMINATION
    A) DERMAL DECONTAMINATION
    1) DECONTAMINATION: Remove contaminated clothing and wash exposed area thoroughly with soap and water for 10 to 15 minutes. A physician may need to examine the area if irritation or pain persists (Burgess et al, 1999).

Range Of Toxicity

Summary

    A) At the time of this review, no data regarding minimum lethal dose or maximum tolerated exposure are available.

Maximum Tolerated Exposure

    A) GENERAL/SUMMARY
    1) Minimum lethal human exposure is unknown.

Workplace Standards

    A) ACGIH TLV Values for CAS2439-99-8 (American Conference of Governmental Industrial Hygienists, 2010):
    1) Not Listed

    B) NIOSH REL and IDLH Values for CAS2439-99-8 (National Institute for Occupational Safety and Health, 2007):
    1) Not Listed

    C) Carcinogenicity Ratings for CAS2439-99-8 :
    1) ACGIH (American Conference of Governmental Industrial Hygienists, 2010): Not Listed
    2) EPA (U.S. Environmental Protection Agency, 2011): Not Listed
    3) IARC (International Agency for Research on Cancer (IARC), 2016; International Agency for Research on Cancer, 2015; IARC Working Group on the Evaluation of Carcinogenic Risks to Humans, 2010; IARC Working Group on the Evaluation of Carcinogenic Risks to Humans, 2010a; IARC Working Group on the Evaluation of Carcinogenic Risks to Humans, 2008; IARC Working Group on the Evaluation of Carcinogenic Risks to Humans, 2007; IARC Working Group on the Evaluation of Carcinogenic Risks to Humans, 2006; IARC, 2004): Not Listed
    4) NIOSH (National Institute for Occupational Safety and Health, 2007): Not Listed
    5) MAK (DFG, 2002): Not Listed
    6) NTP (U.S. Department of Health and Human Services, Public Health Service, National Toxicology Project ): Not Listed

    D) OSHA PEL Values for CAS2439-99-8 (U.S. Occupational Safety, and Health Administration (OSHA), 2010):
    1) Not Listed

Toxicity Information

    7.7.1) TOXICITY VALUES
    A) ANIMAL DATA
    1) LD50- (ORAL)RAT:
    a) 3925 mg/kg (RTECS, 2001)

Physicochemical

Physical Characteristics

    A) White solid with negligible volatility (Farm Chem, 1987)

Molecular Weight

    A) 263.08

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