Cybersecurity and privacy risk assessment of point-of-care systems in healthcare: A use case approach

Picric acid
Names
Preferred IUPAC name
2,4,6-Trinitrophenol[1]
Systematic IUPAC name
2,4,6-Trinitrobenzenol
Other names
Picric acid[1]
Carbazotic acid
Phenol trinitrate
Picronitric acid
Trinitrophenol
2,4,6-Trinitro-1-phenol
2-Hydroxy-1,3,5-trinitrobenzene
TNP
Melinite
Lyddite
Identifiers
3D model (JSmol)
ChEBI
ChEMBL
ChemSpider
DrugBank
ECHA InfoCard 100.001.696 Edit this at Wikidata
RTECS number
  • TJ7875000
UNII
UN number UN1344
  • InChI=1S/C6H3N3O7/c10-6-4(8(13)14)1-3(7(11)12)2-5(6)9(15)16/h1-2,10H checkY
    Key: OXNIZHLAWKMVMX-UHFFFAOYSA-N checkY
  • InChI=1/C6H3N3O7/c10-6-4(8(13)14)1-3(7(11)12)2-5(6)9(15)16/h1-2,10H
    Key: OXNIZHLAWKMVMX-UHFFFAOYAM
  • O=[N+]([O-])c1cc(cc([N+]([O-])=O)c1O)[N+]([O-])=O
Properties
C6H3N3O7
Molar mass 229.10 g·mol−1
Appearance Colorless to yellow solid
Density 1.763 g·cm−3, solid
Melting point 122.5 °C (252.5 °F; 395.6 K)
Boiling point > 300 °C (572 °F; 573 K) Detonates
12.7 g·L−1
Vapor pressure 1 mmHg (195 °C)[2]
Acidity (pKa) 0.38
-84.34·10−6 cm3/mol
Hazards
Occupational safety and health (OHS/OSH):
Main hazards
explosive
GHS labelling:
GHS01: ExplosiveGHS02: FlammableGHS06: Toxic
H206, H302, H311, H331
P210, P212, P230, P233, P280, P370+P380+P375, P501
NFPA 704 (fire diamond)
NFPA 704 four-colored diamondHealth 3: Short exposure could cause serious temporary or residual injury. E.g. chlorine gasFlammability 4: Will rapidly or completely vaporize at normal atmospheric pressure and temperature, or is readily dispersed in air and will burn readily. Flash point below 23 °C (73 °F). E.g. propaneInstability 4: Readily capable of detonation or explosive decomposition at normal temperatures and pressures. E.g. nitroglycerinSpecial hazards (white): no code
3
4
4
Flash point 150 °C; 302 °F; 423 K[2]
Lethal dose or concentration (LD, LC):
100 mg/kg (guinea pig, oral)
250 mg/kg (cat, oral)
120 mg/kg (rabbit, oral)[3]
NIOSH (US health exposure limits):
PEL (Permissible)
TWA 0.1 mg/m3 [skin]
REL (Recommended)
TWA 0.1 mg/m3 ST 0.3 mg/m3 [skin][2]
IDLH (Immediate danger)
75 mg/m3[2]
Explosive data
Detonation velocity 7,350 m·s−1 at ρ 1.70
RE factor 1.20
Except where otherwise noted, data are given for materials in their standard state (at 25 °C [77 °F], 100 kPa).
checkY verify (what is checkY☒N ?)

Picric acid is an organic compound with the formula (O2N)3C6H2OH. Its IUPAC name is 2,4,6-trinitrophenol (TNP). The name "picric" comes from Greek: πικρός (pikros), meaning "bitter", due to its bitter taste. It is one of the most acidic phenols. Like other strongly nitrated organic compounds, picric acid is an explosive, which is its primary use. It has also been used as medicine (antiseptic, burn treatments) and as a dye.

History

Picric acid was probably first mentioned in the alchemical writings of Johann Rudolf Glauber. Initially, it was made by nitrating substances such as animal horn, silk, indigo, and natural resin, the synthesis from indigo first being performed by Peter Woulfe in 1771.[4] The German chemist Justus von Liebig had named picric acid Kohlenstickstoffsäure (rendered in French as acide carboazotique). Picric acid was given that name by the French chemist Jean-Baptiste Dumas in 1841.[5] Its synthesis from phenol, and the correct determination of its formula, were accomplished during 1841.[6] In 1799, French chemist Jean-Joseph Welter (1763–1852) produced picric acid by treating silk with nitric acid; he found that potassium picrate could explode.[7] Not until 1830 did chemists think to use picric acid as an explosive. Before then, chemists assumed that only the salts of picric acid were explosive, not the acid itself.[8] In 1871 Hermann Sprengel proved it could be detonated[9] and afterwards most military powers used picric acid as their main high explosive material. A full synthesis was later found by Leonid Valerieovich Kozakov.

Picric acid was the first strongly explosive nitrated organic compound widely considered suitable to withstand the shock of firing in conventional artillery. Nitroglycerine and nitrocellulose (guncotton) were available earlier, but shock sensitivity sometimes caused detonation in an artillery barrel at the time of firing. In 1885, based on research of Hermann Sprengel, French chemist Eugène Turpin patented the use of pressed and cast picric acid in blasting charges and artillery shells. In 1887 the French government adopted a mixture of picric acid and guncotton with the name Melinite. In 1888, Britain started manufacturing a very similar mixture in Lydd, Kent, with the name Lyddite. Japan followed with an alternative stabilization approach known as Shimose powder which, instead of attempting to stabilize the material itself, removed its contact with metal by coating the inside of the shells with layer(s) of resin and wax.[10] In 1889, a mixture of ammonium cresylate with trinitrocresol, or an ammonium salt of trinitrocresol, started to be manufactured with the name Ecrasite in Austria-Hungary. By 1894 Russia was manufacturing artillery shells filled with picric acid. Ammonium picrate (known as Dunnite or explosive D) was used by the United States beginning in 1906. However, shells filled with picric acid become unstable if the compound reacts with the metal shell or fuze casings to form metal picrates which are more sensitive than the parent phenol. The sensitivity of picric acid was demonstrated by the Halifax Explosion.

Workers filling shells with liquid melinite at a French munitions factory during WWI

Picric acid was used in the Battle of Omdurman,[11] the Second Boer War,[12] the Russo-Japanese War,[13] and World War I.[14] Germany began filling artillery shells with trinitrotoluene (TNT) in 1902. Toluene was less readily available than phenol, and TNT is less powerful than picric acid, but the improved safety of munitions manufacturing and storage caused the replacement of picric acid by TNT for most military purposes between the World Wars.[15]

Efforts to control the availability of phenol, the precursor to picric acid, emphasize its importance in World War I. Germans are reported to have bought US supplies of phenol and converted it to acetylsalicylic acid (aspirin) to keep it from the Allies. At the time, phenol was obtained from coal as a co-product of coke ovens and the manufacture of gas for gas lighting. Laclede Gas reports being asked to expand production of phenol (and toluene) to assist the war effort.[16] Both Monsanto[17] and Dow Chemical[18] began manufacturing synthetic phenol in 1915, with Dow being the main producer. Dow describes picric acid as "the main battlefield explosive used by the French. Large amounts [of phenol] also went to Japan, where it was made into picric acid sold to the Russians."[19]

Photograph showing the use of picric acid on a farm to remove stumps and rocks.

Thomas Edison needed phenol to manufacture phonograph records. He responded by undertaking production of phenol at his Silver Lake, New Jersey, facility using processes developed by his chemists.[20] He built two plants with a capacity of six tons of phenol per day. Production began the first week of September, one month after hostilities began in Europe. He built two plants to produce the raw material benzene at Johnstown, Pennsylvania, and Bessemer, Alabama, replacing supplies previously from Germany. Edison manufactured aniline dyes, which had previously been supplied by the German dye trust. Other wartime products included xylene, p-phenylenediamine, shellac, and pyrophyllite. Wartime shortages made these ventures profitable. In 1915, his production capacity was fully committed by midyear.[citation needed]

Synthesis

The aromatic ring of phenol is activated towards electrophilic substitution reactions, and attempted nitration of phenol, even with dilute nitric acid, results in the formation of high molecular weight tars. In order to minimize these side reactions, anhydrous phenol is sulfonated with fuming sulfuric acid, and the resulting sulfonic acid is then nitrated with concentrated nitric acid. During this reaction, nitro groups are introduced, and the sulfonic acid group is displaced. The reaction is highly exothermic, and careful temperature control is required. Synthesis routes that nitrate aspirin or salicylic acid can also be used to mitigate tar formation. Carbon dioxide is lost from the former via decarboxylation, while both acetic acid and carbon dioxide are lost from the latter.[21] Another method of picric acid synthesis is direct nitration of 2,4-dinitrophenol with nitric acid.[22][23] It crystallizes in the orthorhombic space group Pca21 with a = 9.13 Å, b = 18.69 Å, c = 9.79 Å and α = β = γ = 90°.[24]

Uses

By far the greatest use of picric acid has been in ammunitions and explosives. Explosive D, also known as Dunnite, is the ammonium salt of picric acid. Dunnite is more powerful but less stable than the more common explosive TNT (which is produced in a similar process to picric acid but with toluene as the feedstock). Picramide, formed by aminating picric acid (typically beginning with Dunnite), can be further aminated to produce the very stable explosive TATB.

It has found some use in organic chemistry for the preparation of crystalline salts of organic bases (picrates) for the purpose of identification and characterization.

Optical metallography

In metallurgy, a 4% picric acid in ethanol etch, termed "picral", has been commonly used in optical metallography to reveal prior austenite grain boundaries in ferritic steels. The hazards associated with picric acid have meant it has largely been replaced with other chemical etchants. However, it is still used to etch magnesium alloys, such as AZ31.

Histology

Bouin solution is a common picric-acid–containing fixative solution used for histology specimens.[25] It improves the staining of acid dyes, but it can also result in hydrolysis of any DNA in the sample.[26]

Picric acid is used in the preparation of Picrosirius red, a histological stain for collagen.[27][28]

Blood tests

Clinical chemistry laboratory testing utilizes picric acid for the Jaffe reaction to test for creatinine. It forms a colored complex that can be measured using spectroscopy.[29]

Picric acid forms red isopurpurate with hydrogen cyanide (HCN). By photometric measurement of the resulting dye, picric acid can be used to quantify hydrogen cyanide.[30]

During the early 20th century, picric acid was used to measure blood glucose levels. When glucose, picric acid and sodium carbonate are combined and heated, a characteristic red color forms. With a calibrating glucose solution, the red color can be used to measure the glucose levels added. This is known as the Lewis and Benedict method of measuring glucose.[31]

Skin dye

Much less commonly, wet picric acid has been used as a skin dye, or temporary branding agent.[citation needed] It reacts with proteins in the skin to give a dark brown color that may last as long as a month.[citation needed]

Antiseptic

During the early 20th century, picric acid was stocked in pharmacies as an antiseptic and as a treatment for burns, malaria, herpes, and smallpox. Picric-acid–soaked gauze was commonly stocked in first aid kits from that period as a burn treatment. It was notably used for the treatment of burns suffered by victims of the Hindenburg disaster in 1937. Picric acid was used as a treatment for trench foot suffered by soldiers stationed on the Western Front during World War I.[32]

Picric acid has been used for many years by fly tyers to dye mole skins and feathers a dark olive green for use as fishing lures. Its popularity has been tempered by its toxic nature.[citation needed]

Safety

Modern safety precautions recommend storing picric acid wet, to minimize the danger of explosion. Dry picric acid is relatively sensitive to shock and friction, so laboratories that use it store it in bottles under a layer of water, rendering it safe. Glass or plastic bottles are required, as picric acid can easily form metal picrate salts that are even more sensitive and hazardous than the acid itself. Industrially, picric acid is especially hazardous because it is volatile and slowly sublimes even at room temperature. Over time, the buildup of picrates on exposed metal surfaces can constitute an explosion hazard.[33]

Picric acid gauze, if found in antique first aid kits, presents a safety hazard because picric acid of that vintage (60–90 years old) will have become crystallized and unstable,[34] and may have formed metal picrates from long storage in a metal first aid case.

Bomb disposal units are often called to dispose of picric acid if it has dried out.[35][36] In the United States there was an effort to remove dried picric acid containers from high school laboratories during the 1980s[citation needed].

Munitions containing picric acid may be found in sunken warships. The buildup of metal picrates over time renders them shock-sensitive and extremely hazardous. It is recommended that shipwrecks that contain such munitions not be disturbed in any way.[37] The hazard may subside when the shells become corroded enough to admit seawater as these materials are water-soluble.[37] Currently there are various fluorescent probes to sense and detect picric acid in very minute quantity.[38]

See also

References

  1. ^ a b Nomenclature of Organic Chemistry: IUPAC Recommendations and Preferred Names 2013 (Blue Book). Cambridge: Royal Society of Chemistry. 2014. p. 691. doi:10.1039/9781849733069-FP001. ISBN 978-0-85404-182-4.
  2. ^ a b c d NIOSH Pocket Guide to Chemical Hazards. "#0515". National Institute for Occupational Safety and Health (NIOSH).
  3. ^ "Picric acid". Immediately Dangerous to Life or Health Concentrations (IDLH). National Institute for Occupational Safety and Health (NIOSH).
  4. ^ Peter Woulfe (1771) "Experiments to shew the nature of aurum mosaicum," Philosophical Transactions of the Royal Society of London, 61: 114–130. See pages 127–130: "A method of dying wool and silk, of a yellow colour, with indigo; and also with several other blue and red colouring substances." and "Receipt for making the yellow dye." — where Woulfe treats indigo with nitric acid ("acid of nitre").
  5. ^ Dumas, J. (1841). "Quatrième mémoire sur les types chimiques" [Fourth memoir on chemical types]. Annales de Chimie et de Physique. 3rd series (in French). 2: 204–232. From p. 228: "C'est sous ce nom que j'ai désigné l'acide carboazotique, ..." (It is by this name [i.e., picric acid] that I designated carboazotic acid, ... )
  6. ^ Auguste Laurent (1841) "Sur le phényle et ses dérivés" (On phenol and its derivatives), Annales de Chimie et de Physique, series 3, 3: 195–228; see especially pages 221–228.
  7. ^ Welter, Jean-Joseph (1799). "Sur quelques matières particulières, trouvées dans les substances animals, traitées par l'acide nitrique" [On some particular materials, found in animal substances, treated with nitric acid]. Annales de Chimie et de Physique. 1st series (in French). 29: 301–305. From p. 303: "Le lendemain je trouvai la capsule tapisée de cristaux dorés qui avoient la finesse de la soie, qui détonoient comme la poudre à canon, et qui, à mon avis, en auroient produit l'effet dans une arme à feu." (The next day, I found the crucible covered with golden crystals which had the fineness of silk, which detonated like gun powder, and which, in my opinion, would produce the same effect in a firearm.) Welter named picric acid amer (bitter): from p. 304: " ... je nommerai amer." ( ... I will name it "bitter".)
  8. ^ A theory to explain why picrate salts detonated whereas picric acid itself didn't, was proposed by the French chemists Antoine Fourcroy and Louis Vauquelin in 1806 and reiterated by the French chemist Michel Chevreul in 1809. Picric acid evidently contained enough oxygen within itself — i.e. it was "super-oxygenated" (suroxigéné) (Fourcroy and Vauquelin, 1806), p. 543; (Chevreul, 1809), p. 129) — to combust completely even in the absence of air (because even in the absence of air, heat could transform it completely into gases, leaving no carbon). ((Fourcroy and Vauquelin, 1806), pp. 542–543); (Chevreul, 1809), pp. 127–128) However, when picric acid was burned, the heat that was generated caused some of the acid to evaporate, dissipating so much heat that only burning, not detonation, occurred. In contrast, picrate salts were solids that did not sublimate, and thus did not dissipate heat; hence, they did detonate.((Fourcroy and Vauquelin, 1806), p. 542); (Chevreul, 1809), pp. 129–130) See:
  9. ^ Note:
    • In March 1871, Sprengel detonated picric acid at the gunpowder works of John Hall & Sons in Faversham in Kent, England.
    • Sprengel filed patents in Britain for "safety explosives" (i.e., stable explosives) on April 6, 1871 (no. 921), and on October 5, 1871 (no. 2642); in the latter patent, Sprengel proposed using picric acid dissolved in nitric acid as an explosive.
    • Hermann Sprengel (1873) "On a new class of explosives which are non-explosive during their manufacture, storage, and transport", Journal of the Chemical Society, 26 : 796–808 doi:10.1039/js8732600796.
    • Hermann Sprengel, The Discovery of Picric Acid (Melinite, Lyddite) "As a Powerful Explosive" ..., 2nd ed. (London: Eyre & Spottiswoode, 1903). This pamphlet is a collection of (splenetic) letters in which Sprengel defends his priority in the use of picric acid as a high explosive.
  10. ^ Koike, Shigeki (2006). "The Russo-Japanese War and the system of SHIMOSE gunpowder" (PDF). Bulletin of Papers (in Japanese). Takasaki City University of Economics. 1 (49).
  11. ^ Brown, G.I. (1998). The big bang: a history of explosives. Stroud, UK: Sutton Pub. pp. 151–163. ISBN 0-7509-1878-0. OCLC 40348081.
  12. ^ Wisser, John Philip (1901). The second Boer War, 1899–1900. Hudson-Kimberly. p. 243. Retrieved 2009-07-22.
  13. ^ Dunnite Smashes Strongest Armor, The New York Times, August 18, 1907
  14. ^ Marc Ferro. The Great War. London and New York: Routeladge Classics, p. 98.
  15. ^ Brown, G.I. (1998), The Big Bang: a History of Explosives, Sutton Publishing ISBN 0-7509-1878-0 pp.151–163
  16. ^ Beck, Bill (2007) Laclede Gas and St. Louis: 150 Years Working Together, 1857–2007, Laclede Gas Company, ISBN 978-0-9710910-1-6 p. 64
  17. ^ Forrestal, Dan J. (1977), Faith, Hope & $5000: The Story of Monsanto, Simon & Schuster, ISBN 0-671-22784-X[2] p. 24
  18. ^ Brandt, E.N. (1997), Growth Company: Dow Chemical's First Century, Michigan State University, ISBN 0-87013-426-4 p. 77, 97 and 244
  19. ^ Brandt, E.N. (1997), Growth Company: Dow Chemical's First Century, Michigan State University, ISBN 0-87013-426-4 p. 97
  20. ^ Conot, Robert (1979), A Streak of Luck: The Life & Legend of Thomas Alva Edison, Seaview Books, NY, p 413-4
  21. ^ "λ » LambdaSyn – Synthese von Pikrinsäure". www.lambdasyn.org. Retrieved 2024-08-01.
  22. ^ Agrawal, Jai Prakash; Hodgson, Robert (2007-01-11). Organic Chemistry of Explosives. John Wiley & Sons. ISBN 9780470059357.
  23. ^ Green, Arthur George (1919-04-01). "Manufacture of picric acid. US Patent US1299171A". patents.google.com. Retrieved 2018-08-26.
  24. ^ V. Bertolasi, P. Gilli, G. Gilli: Hydrogen Bonding and Electron Donor-Acceptor (EDA) Interactions Controlling the Crystal Packing of Picric Acid and Its Adducts with Nitrogen Bases. Their Rationalization in Terms of the pKa Equalization and Electron-Pair Saturation Concepts. In: Cryst. Growth Des. 2011, 11, 2724–2735, doi:10.1021/cg101007a.
  25. ^ Carson, Freida L.; Hladik, Christa (2009). Histotechnology: A Self-Instructional Text (3 ed.). Hong Kong: American Society for Clinical Pathology Press. p. 19. ISBN 978-0-89189-581-7.
  26. ^ Llewellyn, Brian D (February 2009). "Picric Acid". StainsFile. Archived from the original on 31 May 2015. Retrieved 28 September 2012.
  27. ^ Lattouf R, Younes R, Lutomski D, Naaman N, Goudeau G, Senni K, Changotade S (2014). "Picrosirius Red Staining: A Useful Tool to Appraise Collagen Networks in Normal and Pathological Tissues". Journal of Histochemistry & Cytochemistry. 62 (10): 751–758. doi:10.1369/0022155414545787. PMID 25023614.
  28. ^ Junqueira LC, Bignolas G, Brentani RR (1979). "Picrosirius staining plus polarization microscopy, a specific method for collagen detection in tissue sections". The Histochemical Journal. 11 (4): 447–455. doi:10.1007/BF01002772. PMID 91593.
  29. ^ "Creatinine Direct Procedure, on CimaScientific". Archived from the original on 2020-08-06. Retrieved 2011-03-26.
  30. ^ Quantification of total cyanide content in stone fruit kernels. Archived 2019-04-30 at the Wayback Machine pdf, Pg.33
  31. ^ 2"Measuring blood glucose levels in the 1920s". Tacomed.com. Archived from the original on 16 December 2018. Retrieved 13 June 2017.
  32. ^ (1922) [1] History of the Great War - Surgery of the War, Vol. 1, Pg. 175.
  33. ^ "Picric Acid, Wet". hazard.com. 21 April 1998. Retrieved 13 April 2021.
  34. ^ Harding, Evan; Searle, Jamie (7 July 2021). "Potentially explosive substance was in Catlins museum for decades". Stuff. Retrieved 20 July 2021.
  35. ^ "Bomb squad called to Dublin lab". irishtimes.com. Irish Times. 1 October 2010. Archived from the original on 22 October 2012. Retrieved 22 July 2011.
  36. ^ "Unstable chemicals made safe by army". rte.ie. RTÉ News. 3 November 2010. Retrieved 22 July 2011.
  37. ^ a b Albright, p.78
  38. ^ Arunkumar, Chellaiah; Sujatha, Subramaniam (26 Oct 2015). "Protonation and axial ligation intervened fluorescence turn-off sensing of picric acid in freebase and tin(iv) porphyrins". RSC Advances. 5 (113): 93243. Bibcode:2015RSCAd...593243S. doi:10.1039/C5RA18310C.

Further reading

  • Albright, Richard (2011). Cleanup of Chemical and Explosive Munitions: Location, Identification and Environmental Remediation. William Andrew.
  • Brown, David K.; McCallum, Iain (2001). "Ammunition Explosions in World War I". Warship International. XXXVIII (1). International Naval Research Organization: 58–69. ISSN 0043-0374.
  • Cooper, Paul W., Explosives Engineering, New York: Wiley-VCH, 1996. ISBN 0-471-18636-8
  • CDC - NIOSH Pocket Guide to Chemical Hazards