Response to a chemical incident or accident who is in charge? /

Briggs, Darryl J.

January 1900

Thesis (M.S. in Joint Campaign Planning and Strategy)--Joint Forces Staff College, Joint Advanced Warfighting School, 2007. / Title from title screen; viewed on July 9, 2007. "7 April 2007." Electronic version of original print document. Includes bibliographical references (p. 61-63).

Chemical warfare

Biological implications of chemical and radiological warfare

Williams, Dean Weeden

January 1963

Thesis (M.A.)--Boston University / This thesis is a major review of the acute biological effects of chemical and radiological weapons. These agents of modern warfare have a broader spectrum of biological effects than the weapons of past wars and also present more profound biological sequelae. In order to cope with the threat that these weapons pose, it is necessary to be familiar with the types of agents which might be used, the symptomatology, the modes of physiological effect, and the basic mechanisms of cellular action. The acute radiation syndrome is covered in detail along with hypotheses of the cellular action of ionizing radiation and a review of methods for protection against radiation [TRUNCATED]

Nuclear warfare

Chemical warfare

A chemical casualty model

Thornton, Paul D.

January 1990

Thesis (M.S. in Operations Research)--Naval Postgraduate School, September 1990. / Thesis Advisor(s): Johnson, Laura. Second Reader: Parry, Sam H. "September 1990." Description based on title screen as viewed on December 21, 2009. DTIC Identifier(s): Chemical Warfare Casualties, Chemical Warfare Agents, Mathematical Models. Author(s) subject terms: Chemical Casualties, Chemical Warfare, Regression, CHEMCAS. Includes bibliographical references (p. 36-37). Also available in print.

Mathematical models. Chemical warfare.

Can naval surface forces operate under chemical weapons conditions? /

Stebbins, Adriane A.

January 2002

Thesis (M.S.)--Naval Postgraduate School, 2002. / Thesis advisor(s): Peter R. Lavoy, Steven J. Iatrou. Includes bibliographical references (p. 55-57). Also available online.

Chemical warfare. Chemical weapons.

The mechanism of the sorption of gases by charcoal and other research in chemical warfare.

Arnell, J. C.

January 1942

No description available.

Gases -- Absorption and adsorption.

Chemical warfare.

An investigation into hydroxyl radical processes for the destruction of chemical warfare agents

Jeune, Gareth Huw

January 1997

No description available.

358.34

Enzyme-based detoxification of organophosphorus neurotoxic pesticides and chemical warfare agents

Kern, Rory James

15 May 2009

There are some 15,000 known organophosphorus chemicals. Some of these OP’s, including VX and paraoxon, demonstrate an acute neurotoxicity due to the inhibition of cholinergic enzymes. Organophosphorus chemical warfare agents and pesticide neurotoxins are subject to hydrolysis by OP degrading enzymes. To be useful as a bioremediation or anti-chemical warfare agent, the enzyme must be tailored for, and integrated into, a practical application platform. Several studies have established enzyme-based countermeasures, describing such diverse applications as decontaminating foams for surface remediation, encapsulating enzyme with liposome for in vivo therapy, enzyme attachments to surfaces for biosensors and development of a corn expression system for large-scale enzyme production. The goal of the research described here is to select, investigate and improve the operational potential of organophosphate-degrading enzymes including Organophosphorus Hydrolase (OPH, 3.1.8.1) and Organophosphorus Acid Anhydrolase (OPAA, 3.1.8.2). Using saturation kinetics, the catalytic efficiencies of these two major detoxification enzymes were characterized with substrates representing each class of OP neurotoxin, phosphotriester, phosphothioate and phosphofluoridate. OPH presents superior kinetic parameters with each OP class tested. Variants of OPH were created to increase the operational effectiveness of OP hydrolytic enzymes against phosphorothioates. An H254S/H257L mutation in the active site resulted in an improvement in the kinetics (kcat/KM) for the phosphorothioate, demeton-S. To screen potential vascular protection therapies, an in vitro protocol was developed to predict enzymatic effectiveness for protection of acetylcholinesterase from acute OP-inhibition. The protection abilities of the enzymes were directly related to their second order rate constants as inhibitory levels of OP are below the KM of the enzymes. Consideration of contaminant nature concentration and enzyme kinetic parameters, kcat and KM, is critical to understanding decontamination and effective use of enzyme technology. These technologies continue to develop and provide promising new decontamination tools for OP compounds.

Enzyme

Organophosphorus

Chemical Warfare Agents

Remediation

Treatment

Canada and chemical warfare 1939-1945

Paige, Christopher

09 March 2009

From 1939 to 1942 Canada, allied to the United Kingdom, prepared to defend itself against chemical attack by Nazi Germany. The Canadian preparations represented one of Canadas many contributions to the cause of the British Commonwealth, and may have been used as one method to counter British requests for additional ground troops. After the Japanese attack at Pearl Harbor, Canada became part of an alliance with the United States and the United Kingdom. Canadian chemical warfare preparations went from defensive to offensive following the attack on Pearl Harbor and the entry of the United States into the war. The chemical warfare preparations included preparation and testing of toxic gases and smokes, smoke screening and flame weapons.<p> One of the most important Canadian contributions to the alliance was the establishment of the Suffield Field Experimental Station in Alberta. This base was particularly useful in carrying out chemical weapon trials, during which approximately 2000 Canadian citizens and soldiers were exposed to toxic gases. At the beginning of the war chemical warfare volunteers were completely covered in protective clothing except for a patch to allow for controlled chemical burns. But by 1942 Suffield staff was given permission to rewrite the regulations for the trials, and volunteers often received significant chemical injuries, including to the eyes. It would appear that the full body of knowledge available to the wartime scientists, especially information relevant to the long-term health outcomes of exposure to vesicant agents, was not applied in the conduct of the human experimentation.

Canada

chemical warfare

mustard gas

Suffield

Electrochemical detection of chemical warfare agents

Khan, Mohammad Abdul Kader

22 May 2007

tert-butyl 1-methoxycarbonyl-1-ferrocenecarbamate, Boc-NH-Fc-COOMe, (1) was synthesized according to the literature procedure and modified to 1-amino-n′-ferrocenemethylcarboxylate, 1,n′-H2N-Fc-COOCH3 (2) by removing the Boc-group with TFA/Et3N mixture in dichloromethane. Compound 2 reacted with alkylating agents like MeI, EtI, EtSCH2CH2Cl (MA) and (CN)(EtO)2P(O) (NA) to form MeNH-Fc-COOMe (3), EtNH-Fc-COOMe (4), EtSCH2CH2NH-Fc-COOMe (5), (EtO)2P(O)NH-Fc-COOMe (6), respectively. Cyclic voltammetry (CV) of these compounds showed different half-wave potential characteristics compared to aminoferrocene and was dependent on the nature of the substituents, which was rationalized by molecular orbital calculations. Electron donating groups (Me, Et and 2-chloroethyl ethylsulfide, MA) shifted the half-wave potential towards the cathodic direction while electron withdrawing group like diethyl cyanophosphonate, NA, shifted it toward anodic direction. Anodic to cathodic peak separation were found to be within 62-88 mV indicating a quasi-reversible system. <p>Hydrolysis of compound 1 resulted in the formation of tert-butyl 1-methoxycarbonyl-1-ferrocenecarboxylic acid, Boc-NH-Fc-COOH, (11) which was coupled with cystamine using the EDC/HOBt protocol to synthesize the cystamine conjugate [BocHN-Fc-CO-CSA]2 (12). This molecule is equipped with an amino group that directly linked to the redox receptor. Compound 12 was fully characterized by spectroscopic methods and by single crystal x-ray diffraction. The cystamine conjugate 12 formed films on gold substrates, which upon deprotection of the amino group, reacted with chemical warfare agents (CWAs) mimics, such as EtSCH2CH2Cl (MA), a simulant for the sulfur mustard HD, and (CN)(EtO)2P(O) (NA), a simulant for the nerve agent Tabun. Their reaction with the surface-bound ferrocene derivative results in the formation of N-substituted products. <p>CV measurements showed anodic shifts of the Fc redox potentials by 50 (±5) mV after exposure to MA, and NA. Measurements by quartz crystal microbalance (QCM) showed an increase in mass upon exposure to MA and NA. Ellipsometry measured a film thickness increase from 6 (±1) Å for the deprotected film to 10 (±4) Å for the film modified with MA and to 7 (±2) Å for the film modified with NA. The surfaces were analyzed by x-ray photoelectron spectroscopy (XPS) and clearly showed the attachment of the cystamine conjugate on the surface and its reaction with CWAs mimics.

Chemical warfare agents

Electrochemical detection

Cyclic voltammetry

Electrochemical detection of chemical warfare agents

Khan, Mohammad Abdul Kader

22 May 2007

tert-butyl 1-methoxycarbonyl-1-ferrocenecarbamate, Boc-NH-Fc-COOMe, (1) was synthesized according to the literature procedure and modified to 1-amino-n′-ferrocenemethylcarboxylate, 1,n′-H2N-Fc-COOCH3 (2) by removing the Boc-group with TFA/Et3N mixture in dichloromethane. Compound 2 reacted with alkylating agents like MeI, EtI, EtSCH2CH2Cl (MA) and (CN)(EtO)2P(O) (NA) to form MeNH-Fc-COOMe (3), EtNH-Fc-COOMe (4), EtSCH2CH2NH-Fc-COOMe (5), (EtO)2P(O)NH-Fc-COOMe (6), respectively. Cyclic voltammetry (CV) of these compounds showed different half-wave potential characteristics compared to aminoferrocene and was dependent on the nature of the substituents, which was rationalized by molecular orbital calculations. Electron donating groups (Me, Et and 2-chloroethyl ethylsulfide, MA) shifted the half-wave potential towards the cathodic direction while electron withdrawing group like diethyl cyanophosphonate, NA, shifted it toward anodic direction. Anodic to cathodic peak separation were found to be within 62-88 mV indicating a quasi-reversible system. <p>Hydrolysis of compound 1 resulted in the formation of tert-butyl 1-methoxycarbonyl-1-ferrocenecarboxylic acid, Boc-NH-Fc-COOH, (11) which was coupled with cystamine using the EDC/HOBt protocol to synthesize the cystamine conjugate [BocHN-Fc-CO-CSA]2 (12). This molecule is equipped with an amino group that directly linked to the redox receptor. Compound 12 was fully characterized by spectroscopic methods and by single crystal x-ray diffraction. The cystamine conjugate 12 formed films on gold substrates, which upon deprotection of the amino group, reacted with chemical warfare agents (CWAs) mimics, such as EtSCH2CH2Cl (MA), a simulant for the sulfur mustard HD, and (CN)(EtO)2P(O) (NA), a simulant for the nerve agent Tabun. Their reaction with the surface-bound ferrocene derivative results in the formation of N-substituted products. <p>CV measurements showed anodic shifts of the Fc redox potentials by 50 (±5) mV after exposure to MA, and NA. Measurements by quartz crystal microbalance (QCM) showed an increase in mass upon exposure to MA and NA. Ellipsometry measured a film thickness increase from 6 (±1) Å for the deprotected film to 10 (±4) Å for the film modified with MA and to 7 (±2) Å for the film modified with NA. The surfaces were analyzed by x-ray photoelectron spectroscopy (XPS) and clearly showed the attachment of the cystamine conjugate on the surface and its reaction with CWAs mimics.

Chemical warfare agents

Electrochemical detection

Cyclic voltammetry