Effects of inhaled brevetoxins in allergic airways: toxin-allergen interactions and pharmacologic intervention.During a Florida red tide, brevetoxins produced by the dinoflagellate dinoflagellate Any of numerous one-celled, aquatic organisms that have two dissimilar flagella and characteristics of both plants (algae) and animals (protozoans). Most are microscopic and marine. Karenia brevis become aerosolized Adj. 1. aerosolized - in the form of ultramicroscopic solid or liquid particles dispersed or suspended in air or gas aerosolised gaseous - existing as or having characteristics of a gas; "steam is water is the gaseous state" and cause airway symptoms in humans, especially in those with pre-existing airway disease (e.g., asthma). To understand these toxin-induced airway effects, we used sheep with airway hypersensitivity hypersensitivity, heightened response in a body tissue to an antigen or foreign substance. The body normally responds to an antigen by producing specific antibodies against it. The antibodies impart immunity for any later exposure to that antigen. to Ascaris Ascaris /As·ca·ris/ (-ris) a genus of nematode parasites of the large intestine. A. lumbricoi´des causes ascariasis. ascaris /as·ca·ris/ (-ris suum antigen as a surrogate for asthmatic patients and studied changes in pulmonary airflow resistance ([R.sub.L]) after inhalation challenge with lysed cultures of K. brevis (crude brevetoxins). Studies were done without and with clinically available drugs to determine which might prevent/reverse these effects. Crude brevetoxins (20 breaths at 100 pg/mL; n = 5) increased [R.sub.L] 128 [+ or -] 6% (mean [+ or -] SE) over baseline. This bronchoconstriction was significantly reduced (% inhibition) after pretreatment pretreatment, n the protocols required before beginning therapy, usually of a diagnostic nature; before treatment. pretreatment estimate, n See predetermination. with the glucocorticosteroid budesonide (49%), the [[beta].sub.2] adrenergic adrenergic /ad·ren·er·gic/ (ad?ren-er´jik) 1. activated by, characteristic of, or secreting epinephrine or related substances, particularly the sympathetic nerve fibers that liberate norepinephrine at a synapse when a nerve agent albuterol albuterol /al·bu·ter·ol/ (al-bu´ter-ol) a ß agonist used as the base or sulfate salt as a bronchodilator. al·bu·ter·ol n. (71%), the anticholinergic anticholinergic /an·ti·cho·lin·er·gic/ (-ko?lin-er´jik) parasympatholytic; blocking the passage of impulses through the parasympathetic nerves; also, an agent that so acts. an·ti·cho·lin·er·gic n. agent atropine atropine (ăt`rəpēn, –pĭn), alkaloid drug derived from belladonna and other plants of the family Solanaceae (nightshade family). (58%), and the histamine [H.sub.1]-antagonist diphenhydramine diphenhydramine /di·phen·hy·dra·mine/ (di?fen-hi´drah-men) a potent antihistamine, used as the hydrochloride salt in the treatment of allergic symptoms and for its anticholinergic, antitussive, antiemetic, antivertigo, and antidyskinetic (47%). The protection afforded by atropine and diphenhydramine suggests that both cholinergic cholinergic /cho·lin·er·gic/ (ko?lin-er´jik) 1. parasympathomimetic; stimulated, activated, or transmitted by choline (acetylcholine); said of the sympathetic and parasympathetic nerve fibers that liberate acetylcholine at a (vagal vagal /va·gal/ (va´gal) pertaining to the vagus nerve. va·gal adj. Of or relating to the vagus nerve. vagal pertaining to the vagus nerve. ) and [H.sub.1]-mediated pathways contribute to the bronchoconstriction. The response to cutaneous cutaneous /cu·ta·ne·ous/ (ku-ta´ne-us) pertaining to the skin. cu·ta·ne·ous adj. Of, relating to, or affecting the skin. Cutaneous Pertaining to the skin. toxin injection was also histamine mediated. Thus, the airway and skin data support the hypothesis that toxin activates mast cells Mast cells A type of immune system cell that is found in the lining of the nasal passages and eyelids, displays a type of antibody called immunoglobulin type E (IgE) on its cell surface, and participates in the allergic response by releasing histamine from in vivo in vivo /in vi·vo/ (ve´vo) [L.] within the living body. in vi·vo adj. Within a living organism. in vivo adv. . Albuterol given immediately after toxin challenge rapidly reversed the bronchoconstriction. Toxin inhalation increased airway kinins, and the response to inhaled toxin was enhanced after allergen allergen /al·ler·gen/ (al´er-jen) an antigenic substance capable of producing immediate hypersensitivity (allergy).allergen´ic pollen allergen challenge. Both factors could contribute to the increased sensitivity of asthmatic patients to toxin exposure. We conclude that K. brevis aerosols are potent airway constrictors. Clinically available drugs may be used to prevent or provide therapeutic relief for affected individuals. Key words: animal models, asthma, brevetoxin, bronchoconstriction, clinical therapies. doi:10.1289/ehp.7498 available via http://dx.doi.org/ [Online 10 February 2005] ********** Florida red tide is a harmful algal bloom A harmful algal bloom (HAB) can refer to a dense aggregation of phytoplankton, algae or cyanobacteria in a marine or aquatic environment, such that it causes negative impacts to other organisms via biotoxins, mechanical damage or other means. caused by the dinoflagellate Karenia brevis (previously Gymnodinium breve BREVE, practice. A writ in which the cause of action is briefly stated, hence its name. Fleta, lib. 2, c. 13, Sec. 25; Co. Lit. 73 b. 2. Writs are distributed into several classes. ). K brevis produces at least nine structurally related polyether pol·y·e·ther n. A polymer in which the repeating unit contains two carbon atoms linked by an oxygen atom. brevetoxins (PbTxs; Baden 1989; Baden et al. 1995; Pierce and Kirkpatrick 2001), which are lipid-soluble, fused polyethers with molecular weights of approximately 900 Da. During red tide events, toxins released from disrupted organisms are concentrated in seawater droplets that subsequently can become aerosolized (Pierce et al. 1990, 2003). Onshore winds then carry these aerosols inland, where exposed individuals report both upper and lower airway low·er airway n. The portion of the respiratory tract that extends from the subglottis through the terminal bronchioles. symptoms, such as nonproductive non·pro·duc·tive adj. 1. Not yielding or producing: nonproductive land. 2. Not engaged in the direct production of goods: nonproductive personnel. n. cough, shortness of breath Shortness of Breath Definition Shortness of breath, or dyspnea, is a feeling of difficult or labored breathing that is out of proportion to the patient's level of physical activity. , rhinorrhea, and sneezing To verbally tell somebody about a new and interesting Web site. See viral marketing. (Asai et al. 1982; Backer et ah 2003; Kirkpatrick et al. 2004). There is a suggestion that the frequency of these adverse respiratory events is increased in "susceptible populations," that is, in those with pre-existing airway disease, as indicated from a clinical survey where 80% of patients with bronchial asthma bronchial asthma n. A condition of the lungs characterized by widespread narrowing of the airways due to spasm of the smooth muscle, edema of the mucosa, and the presence of mucus in the lumen of the bronchi and bronchioles. were reportedly affected during a red tide event, with some having overt asthma attacks (Asai et al. 1982). Although the data from these clinical surveys and our own field studies (Backer et al. 2003; Baden and Tomas 1988; Fleming et al. 2005; Kirkpatrick et al. 2004; Pierce et al. 1992, 2003) indicate that aerosolized toxins. are respiratory irritants and that the effects may be more severe in asthmatics, there is a paucity of data examining the effects of aerosolized toxin in asthmatic airways under controlled conditions. To address this problem, we initially studied the airway responses to inhaled PbTxs in a sheep model of asthma (Abraham et al. 2005). This model shares many characteristics of the disease in humans, including the development of early airway responses (EAR) and late airway responses (LAR) and postantigen-induced airway hyperresponsiveness (AHR AHR Aryl Hydrocarbon Receptor AHR American Historical Review (Journal of the American History Association) AHR Anchor AHR airway hyper-responsiveness AHR Assisted Human Reproduction AHR Air-Conditioning Heating Refrigeration ) after inhalation challenge with Ascaris suum antigen (Abraham 2000). The model also demonstrates nonspecific nonspecific /non·spe·cif·ic/ (non?spi-sif´ik) 1. not due to any single known cause. 2. not directed against a particular agent, but rather having a general effect. nonspecific 1. bronchial hyperresponsiveness bronchial hyperresponsiveness Exaggerated bronchial constriction most common in asthma, in response to nonspecific provocation, inhalation of various bronchoconstrictors, but also to physical challenges–eg, exercise, dry or cold air, hypertonic or hypotonic aerosols to a variety of agents, and we have previously used it to study the pulmonary consequences of pollutant exposures (Abraham et al. 1980, 1981). Furthermore, the antigen-induced effects in this model can be ameliorated with the current armamentarium ar·ma·men·tar·i·um n. pl. ar·ma·men·tar·i·ums or ar·ma·men·tar·i·a The complete equipment of a physician or medical institution, including drugs, books, supplies, and instruments. of clinically available asthma medications, including glucocorticosteroids, [[beta].sub.2] adrenergic agents, and leukotriene antagonists (Abraham 2000). Collectively, the characteristics of the model suggest that it can be used as a surrogate for patients with compromised airways to study the effects of inhaled toxin. In our initial studies, allergic sheep that inhaled environmentally relevant concentrations (picogram picogram /pi·co·gram/ (pg) (pi´ko-gram) one-trillionth (10-12) of a gram. pi·co·gram n. Abbr. pg One-trillionth (10-12) of a gram. per milliliter milliliter /mil·li·li·ter/ (mL) (-le?ter) one thousandth (10-3) of a liter. mil·li·li·ter n. Abbr. ) of lysed cultures of K. brevis (i.e., crude brevetoxins, which contains all toxins and cell debris) or purified PbTx-2 or PbTx-3 developed significant bronchoconstriction (Abraham et al. 2005). The magnitude of the response was similar for the three toxins (Abraham et ah 2005). Previous in vitro in vitro /in vi·tro/ (in ve´tro) [L.] within a glass; observable in a test tube; in an artificial environment. in vi·tro adj. In an artificial environment outside a living organism. studies using canine tracheal tracheal pertaining to or emanating from trachea. tracheal aspiration see transtracheal aspiration. tracheal band sign on contrast radiography of a dilated esophagus, the impression made ventrally by the trachea. and human bronchial bronchial /bron·chi·al/ (brong´ke-al) pertaining to or affecting one or more bronchi. bron·chi·al adj. Relating to the bronchi, the bronchial tubes, or the bronchioles. smooth muscle (Asai et al. 1982; Shimoda et al. 1988), demonstrated that brevetoxin-induced contractile contractile /con·trac·tile/ (kon-trak´til) able to contract in response to a suitable stimulus. con·trac·tile adj. Capable of contracting or causing contraction, as a tissue. effects can be blocked with atropine but not with a histamine antagonist, suggesting that toxin-induced constriction constriction /con·stric·tion/ (kon-strik´shun) 1. a narrowing or compression of a part; a stricture.constric´tive 2. a diminution in range of thinking or feeling, associated with diminished spontaneity. results from stimulation of parasympathetic parasympathetic /para·sym·pa·thet·ic/ (-sim?pah-thet´ik) see under system. par·a·sym·pa·thet·ic adj. Of, relating to, or affecting the parasympathetic nervous system. postganglionic postganglionic /post·gan·gli·on·ic/ (post?gang-gle-on´ik) distal to a ganglion. post·gan·gli·on·ic adj. Located posterior or distal to a ganglion. neurons. In contrast to the prior in vitro findings, however, our in vivo studies showed that protective effects were achieved with the mast cell stabilizer Mast cell stabilizers are cromone medications used to prevent or control certain allergic disorders. They block a calcium channel essential for mast cell degranulation, stabilizing the cell and so prevent the release of histamine[1] and related mediators. cromolyn sodium cro·mo·lyn sodium n. A drug usually administered by inhalation and used to prevent certain allergic attacks, especially those associated with asthma or hay fever. and the histamine [H.sub.1]-antagonist diphenhydramine. These data support a role for a histamine [H.sub.1]-mediated pathway contributing to the bronchoconstrictor response in vivo (Abraham et al. 2005). Because mast cells and basophils are the most prominent source of histamine in the airways, our findings suggest that toxin, either directly or indirectly, causes mast cell/basophil activation. Such a mechanism could in part explain the reported increased incidence of asthma attacks after natural red tide episodes. Another factor that could play a role in asthma exacerbations is the generation of kinins in the airway. The pattern of airway responses and the pharmacologic profile seen with inhaled toxin (Abraham et al. 2005) are similar to those seen previously by us with inhaled bradykinin bradykinin /brady·ki·nin/ (-ki´nin) a nonapeptide kinin formed from HMW kininogen by the action of kallikrein; it is a very powerful vasodilator and increases capillary permeability; in addition, it constricts smooth muscle and (Abraham et ah 1991). Increased airway kinin kinin /ki·nin/ (ki´nin) any of a group of vasoactive straight-chain polypeptides formed by kallikrein-catalyzed cleavage of kininogens; causing vasodilation and also altering vascular permeability. levels occur after exposure to a variety of noxious stimuli (Lauredo et al. 2003), including allergen, ozone, bacterial products, and metabisulfite (Forteza et al. 1994, 1999; Mansour et al. 1992), and are associated with bronchoconstriction, AHR, and lung neutrophilia; all of these responses are seen after inhalation challenge with PbTx-3 (Zaias et al. 2004). The evidence suggesting that toxin stimulates mast cells/basophils and/or increases airway kinins heightens the importance of understanding toxin effects in allergic airways. Therefore, in this study we used allergic sheep to study further the effects of inhaled toxin in compromised airways. Specifically, we determined a) if toxin alone could induce airway responses similar to that seen with allergen, b) if preexposure to toxin could exacerbate allergen-induced responses, and c) the effects of clinically available drugs and experimental pharmacologic agents on toxin-induced airway constriction. In addition, we showed that toxin activates skin mast cells and so provide further support for the in vivo mast cell mast cell n. A cell found in connective tissue that contains numerous basophilic granules and releases substances such as heparin and histamine in response to injury or inflammation of bodily tissues. Also called labrocyte, mastocyte. hypothesis. Materials and Methods Adult ewes (Quin Tindall, Okeechobee, FL) that were naturally sensitive to A. suum antigen and had demonstrated airway hypersensitivity to this antigen were used (Abraham 2000). The animals were conscious and restrained in a cart in an upright position with their heads immobilized for the described studies. Instrumentation was performed under local anesthesia Anesthesia, Local Definition Local or regional anesthesia involves the injection or application of an anesthetic drug to a specific area of the body, as opposed to the entire body and brain as occurs during general anesthesia. . The study was conducted at Mount Sinai Medical Center under the approval of the Mount Sinai Medical Center Animal Research Committee. Pulmonary resistance. These methods have been reported in detail (Abraham et al. 1994, 2000, 2004). Briefly, a balloon catheter balloon catheter n. A catheter with an inflatable balloon at its tip, used especially to expand a partially obstructed blood vessel or bodily passage and to measure blood pressure in a blood vessel. Also called balloon-tip catheter. was advanced through one nostril nostril /nos·tril/ (nos´tril) either of the nares. nos·tril n. A naris. nostril either of the two apertures (nares) of the nose that lead into the nasal cavity. into the lower esophagus, and the animals were intubated with a cuffed endotracheal tube endotracheal tube n. A tube inserted into the trachea to provide a passageway for air. Also called tracheal tube. Endotracheal tube through the other nostril. Animals remained intubated throughout the course of a particular experiment, but to avoid discomfort during these studies, the cuff of the endotracheal tube was inflated only during the measurements of pulmonary resistance ([R.sub.L]) and during delivery of nebulized agents. We have shown previously that this intubation intubation /in·tu·ba·tion/ (in?too-ba´shun) the insertion of a tube into a body canal or hollow organ, as into the trachea. endotracheal intubation procedure does not affect [R.sub.L] or airway responsiveness in these animals for periods of up to 9 hr (Russi et al. 1984). Pleural Pleural Pleural refers to the pleura or membrane that enfolds the lungs. Mentioned in: Pneumothorax pleural emanating from or pertaining to the pleura. pressure was measured via the esophageal catheter. Lateral pressure in the trachea trachea (trā`kēə) or windpipe, principal tube that carries air to and from the lungs. It is about 4 1-2 in. (11.4 cm) long and about 3-4 in. (1.9 cm) in diameter in the adult. was measured with a side-hole catheter advanced through and positioned distal to the tip of the endotracheal tube. Transpulmonary pressure transpulmonary pressure Physiology The difference between airway pressure and pleural pressure–PAW—PPL, a clinically important respiratory measure in ICU Pts; it is also derived by multiplying the airway pressure by the ratio of , the difference between tracheal and pleural pressure, was measured with a differential pressure transducer. To measure [R.sub.L], the proximal end of the endotracheal tube was connected to a pneumotachograph pneu·mo·tach·o·graph n. An apparatus for recording the rate of airflow to and from the lungs. Also called pneumotachometer. pneumotachograph an instrument for recording the velocity of respired air. , and the signals of flow and transpulmonary pressure were recorded on a computer. Respiratory volume was obtained by digital integration of the flow signal so that [R.sub.L] was calculated from the transpulmonary pressure and flow, at isovolumetric points. Analysis of 5-10 breaths was used for each determination of [R.sub.L]. Agents. Crude brevetoxins and purified PbTx-3 were obtained from the Center for Marine Science at the University of North Carolina North Carolina, state in the SE United States. It is bordered by the Atlantic Ocean (E), South Carolina and Georgia (S), Tennessee (W), and Virginia (N). Facts and Figures Area, 52,586 sq mi (136,198 sq km). Pop. at Wilmington. Crude brevetoxin was diluted in NH-15 buffer. PbTx-3 was first diluted in a small volume of Alkamuls (Emulphor EL-620: ethoxylated castor oil and water; Chemtec Chemical Co., Chatsworth, CA), followed by suspension in phosphate-buffered saline (PBS PBS in full Public Broadcasting Service Private, nonprofit U.S. corporation of public television stations. PBS provides its member stations, which are supported by public funds and private contributions rather than by commercials, with educational, cultural, ). Atropine sulfate injection (Baxter Health Care, Deerfield, IL) was given at a dose of 0.2 mg/kg, iv,; the histamine [H.sub.1]-antagonist diphenhydramine hydrochloride (Elkins-Sinn Inc., Cherry Hill, NJ) was diluted in PBS and given at a dose of 2 mg/kg, iv. Albuterol sulfate inhalation solution (2.5 mg/3 mL; Dey, Napa, CA) was given as an aerosol. A. suum extract (Greer Diagnostics, Lenoir, NC) was diluted with PBS to a concentration of 82,000 protein nitrogen units/mL and delivered as an aerosol (20 breaths/min). The following agents were all obtained from Sigma (St. Louis, MO): The bradykinin [B.sub.2] receptor antagonist HOE-140 was diluted in PBS, and given as an aerosol (400 nM/kg); budesonide was first diluted in 1 mL ethanol and then in PBS to give a 1 mg/3 mL solution and was given as an aerosol; carbamylcholine (carbachol) was dissolved in PBS at concentrations of 0.25, 0.50, 1.0, 2.0, and 4.0% wt/vol and delivered as an aerosol. As reported previously in detail (Abraham et al. 1994, 2004; Scuri et al. 2002), we used a dosimeter-piston ventilator system with a Raindrop nebulizer nebulizer /neb·u·liz·er/ (neb´u-li?zer) atomizer; a device for throwing a spray. neb·u·liz·er n. (Nelcor Puritan Bennett, Carlsbad, CA) to deliver the aerosols directly into the endotracheal tube only during inspiration at a tidal volume of 500 mL and a rate of 20 breaths/minute. Assessment of nonspecific airway responsiveness. Airway responsiveness to carbachol was determined from cumulative concentration-response curves as previously described (Abraham et al. 1994, 2004; Scuri et al. 2002). [R.sub.L] was measured immediately after inhalation of PBS and within 5 min after each consecutive administration of 10 breaths of increasing concentrations of carbachol (0.25, 0.5, 1.0, 2.0, and 4.0% wt/vol PBS). The provocation test was discontinued when [R.sub.L] increased > 400% from the post-PBS value or after the highest carbachol concentration had been administered. The cumulative carbachol concentration (in breath units) that increased [R.sub.L] by 400% over the post-PBS value (PC400) was calculated by interpolation interpolation In mathematics, estimation of a value between two known data points. A simple example is calculating the mean (see mean, median, and mode) of two population counts made 10 years apart to estimate the population in the fifth year. from the dose-response curve. One breath unit was defined as one breath of a 1% wt/vol carbachol aerosol solution. A decrease in the PC400 indicates the development of AHR. Airway responsiveness to Pb Tx-3. Baseline [R.sub.L] was measured, and then the sheep were challenged with 20 breaths of increasing concentrations of PbTx-3: 0.1, 0.3, 1, and 10 pg/mL of PbTx-3. [R.sub.L] was measured within 5 min after the delivery of each concentration of toxin. Airway responses to toxin. Baseline [R.sub.L] was measured, and then the sheep were challenged with 20 breaths of 100 pg/mL of crude brevetoxins. [R.sub.L] was measured immediately after challenge and then 15, 30, and 60 min after challenge. Responses to crude brevetoxins alone were compared with the responses obtained after treating the animals with the histamine [H.sub.1]-antagonist diphenhydramine, the anticholinergic agent atropine, the glucocorticosteroid budesonide, or the bradykinin [B.sub.2] receptor antagonist HOE-140. All drugs were given 30 min before challenge. Repeat challenges were separated by a minimum of 48 hr. In a separate study, albuterol aerosol was given immediately after inhalation of crude brevetoxins to determine if the drug could reverse the toxin-induced bronchoconstriction. Drug doses chosen for these studies were based on our previous use of these compounds (Abraham 2000). Allergen-Pb Tx-3 interaction. To determine if multiple exposures to PbTx-3 affected antigen-induced responses, we challenged sheep in the morning with 20 breaths of 100 pg/mL PbTx-3 for 3 consecutive days and then on the fourth day challenged the animals with allergen to determine if the antigen-induced EAR, LAR, and AHR were affected. For these studies a baseline PC400 to carbachol was determined 1-3 days before the start of PbTx-3 exposures. One day after the last PbTx-3 exposure (day 4), baseline [R.sub.L] was measured, and then the sheep were challenged with antigen. [R.sub.L] was measured immediately after, hourly for 1-6 hr after, and then on the half-hour from 6.5 to 8 hr after challenge. On the next day, the postantigen PC400 was determined. The results were compared with those obtained without PbTx-3 exposure in the same sheep. To determine if allergen challenge affected the response to PbTx-3, a baseline PC400 to carbachol and a concentration-response curve to PbTx-3 were determined. One to 3 days later, baseline [R.sub.L] was measured, and then the sheep were challenged with antigen. [R.sub.L] was measured immediately after, hourly for 1-6 hr after, and then on the half-hour from 6.5 to 8 hr after challenge. On the next day, the postantigen response to PbTx-3 was determined. Two to 3 hr later when [R.sub.L] had returned to normal, the postantigen PC400 to carbachol was measured. The changes in the postchallenge compared with prechallenge responses to PbTx-3 and PC400 were assessed to determine if they were affected by the allergen provocation. Cutaneous responses. To further investigate the potential for a generalized [H.sub.1]-mediated response to toxin, we performed skin tests with crude brevetoxins and pure PbTx-3 to determine if they would induce a wheal wheal (hwel) a localized area of edema on the body surface, often attended with severe itching and usually evanescent; it is the typical lesion of urticaria. wheal n. response and if the response was histamine mediated (Lucio et al. 1992; Molinari et al. 1995). Immediate cutaneous responses (ICRs) were induced by intradermal injections of 0.05 mL of 5% wt/vol histamine, 100 pg/mL crude brevetoxins, or PbTx-3 solutions using insulin syringes with 28-gauge needles. These studies were repeated, but the sheep were treated with diphenhydramine (2 mg/kg, iv) 2 hr before intradermal intradermal /in·tra·der·mal/ (-der´mal) 1. within the dermis. 2. intracutaneous. in·tra·der·mal adj. Within or between the layers of the skin. challenge or with atropine (0.2 mg/kg, iv) 30 min before challenge. Statistical analysis. Overall effects of airway responses with and without pharmacologic intervention were analyzed with a multifactorial multifactorial /mul·ti·fac·to·ri·al/ (mul?te-fak-tor´e-al) 1. of or pertaining to, or arising through the action of many factors. 2. analysis of variance for repeated measures. If the null hypothesis was rejected, then Tukey's post hoc test was used to determine the statistical significance of differences. In the event only two treatments were compared, a paired t-test was used. Analysis of the ICR (Intelligent Character Recognition or Image Character Recognition) The machine recognition of hand-printed characters as well as machine printing that is difficult to recognize. was determined as described previously by our group (Molinari et al. 1995; Lucio et al. 1992). Wheal sizes were measured 20 and 60 min after injection of active test solutions. The surface area ([mm.sup.2]) of the wheal was determined by measuring the largest wheal diameter ([D.sub.1]) and its perpendicular ([D.sub.2]) and then calculating the surface area using the equation [PI][[([D.sub.1] + [D.sub.2])/4].sup.2]. Results were compared by one-way analysis of variance followed by Tukey's post hoc test if the null hypothesis was rejected. For all analyses, significance was accepted when p < 0.05 using a two-tailed analysis. Values in the text and figures are reported as mean [+ or -] SE. Results Airway responses to toxin with and without pharmacologic intervention. Inhalation of crude brevetoxins resulted in an immediate bronchoconstriction ([R.sub.L] increased 128 [+ or -] 6% over baseline), which then resolved over the next 60 min (Figure 1). The constrictor con·stric·tor n. One that constricts, especially a muscle that contracts or compresses a part or organ of the body. effects of toxin were significantly reduced by pretreating the animals with the anticholinergic agent atropine (58% inhibition), the glucocorticosteroid budesonide (49% inhibition), the [[beta].sub.2] adrenergic agent albuterol (71% inhibition), and the histamine [H.sub.1]-antagonist diphenhydramine (47% inhibition). The reduced response in the presence of either diphenhydramine or atropine suggests that both cholinergic (vagal) and [H.sub.1]-mediated pathways play a role in the toxin-induced bronchoconstriction. It is important to note that we previously showed that the dose of atropine used in these studies does not block histamine-induced bronchoconstriction (Abraham et al. 2005). These results are consistent with histamine stimulation of [H.sub.1] receptors on nerves. The protective effects of albuterol and budesonide are also consistent with the involvement of mast cells/basophils because both agents have been reported to reduce mediator release (Wanner et al. 1987). Although albuterol can inhibit mediator release, its primary action is to relax smooth muscle. As illustrated in Figure 2, giving albuterol immediately after toxin challenge causes a rapid reversal of the response. The dual action of albuterol may account for its increased efficacy when compared with diphenhydramine (Figure 1). [FIGURES 1-2 OMITTED] Figure 3 illustrates that HOE-140, a bradykinin [B.sub.2] receptor antagonist, significantly reduces the toxin-mediated bronchoconstriction. The 34% protection was significant when compared with the response when the animals were untreated but is significantly less than that seen with atropine (58%). These data indicate that, as with other types of irritants, brevetoxin increases kinin levels in the airways and that this inflammatory mediator contributes to toxin-induced airway responses. [FIGURE 3 OMITTED] Cutaneous responses to toxin. The in vivo airway data support a role for a histamine [H.sub.1]-mediated component in the bronchoconstrictor response. To further investigate the potential for a generalized [H.sub.1]-mediated event, we performed skin tests with crude brevetoxins and pure PbTx-3. Both crude brevetoxins and PbTx-3 induced an ICR, which was reduced when the animals were pretreated with the [H.sub.1]-antagonist diphenhydramine (Figure 4). As expected, atropine had no effect on the ICR (data not shown). Thus, the collective data obtained with inhaled and injected toxins support the hypothesis that histamine [H.sub.1]-mediated pathways contribute to the in vivo effects of toxin. [FIGURE 4 OMITTED] Allergen-toxin interactions. Our results indicate that inhaled toxin induces histamine and kinin release in the airways. Because these mediators are key components of allergen-induced airway responses, we wanted to determine if toxin challenge would induce a LAR and AHR similar to that seen with allergen. We also wanted to determine if preexposure to toxin could accentuate the response to allergen or if allergen challenge affected the response to toxin. We found that although PbTx-3 (20 breaths of 100 pg/mL) caused an early bronchoconstriction, there was no subsequent LAR or AHR in sheep that demonstrated these responses to inhaled allergen (data not shown). To determine if toxin exposure would enhance the response to allergen and/or affect the postantigen-induced AHR, we exposed three sheep to PbTx-3 (20 breaths of 100 pg/mL) for 3 consecutive days and then, on the day 4, measured the response to allergen challenge. On the next day, we measured their PC400 to carbachol to determine if the postantigen-induced AHR was affected. Figure 5 shows that the 3-day exposure to PbTx-3 did not alter the airway responses to allergen (EAR, LAR, or AHR) in these animals when compared with the control allergen responses in these same sheep. [FIGURE 5 OMITTED] Although preexposure to PbTx-3 did not accentuate antigen-induced responses, allergen challenge did increase the sensitivity to PbTx-3. Figure 6 shows that the concentration-response curve for PbTx-3 was significantly enhanced 24-hr after allergen exposure in sheep that develop a LAR (138 [+ or -] 9%). The sheep were also hyperresponsive to carbachol at this time as evidenced by the decrease in the post challenge PC400 (15 [+ or -] 1 breath units) when compared with the prechallenge PC400 (28 [+ or -] 2 breath units, p < 0.05). These data suggest that, as seen with other irritants, the airways are more sensitive to toxin after an asthma exacerbation. [FIGURE 6 OMITTED] Discussion The results of this study confirm and extend our previous work with brevetoxin aerosols (Abraham et al. 2005). We confirm that both cholinergic and histamine [H.sub.1]-mediated pathways contribute to the bronchoconstrictor responses to toxin at concentrations 10-100 times greater than those used previously (Abraham et al. 2005). In addition, we identified standard asthma medications that protect against and/or reverse the constrictor effects of inhaled toxin. Our previous work showing that cromolyn sodium can block toxin-induced constrictor effects (Abraham et al. 2005) in conjunction with our current evidence that both the airway and cutaneous responses to toxin are histamine mediated, provides further support for the hypothesis that toxin activates mast cells in vivo. We show that kinins are released in the airways after toxin inhalation. This is a novel finding and, combined with the demonstration that the response to inhaled toxin is greater in inflamed airways, suggests that kinins could be contributing factors to the reported increased sensitivity of asthmatic patients to toxin exposure. The methodology used in the airway provocation studies is designed to deliver toxin directly into the lung under controlled conditions. Although this technique does not mimic natural exposures because it bypasses the upper airways, it provides a reproducible controlled airway challenge system that eliminates dosing variability. This reproducibility is an important consideration when studying adverse lower airway effects and identifying protective pharmacologic agents. Given this, our findings should be applicable to humans experiencing lower airway symptoms during a red tide event. Field studies indicate that humans with normal or healthy airways as well as those with compromised airways respond to a red tide event (Backer et al. 2003, 2005; Fleming et al. 2005; Kirkpatrick et al. 2004). Data from our previous study, using both allergic and nonallergic sheep, are consistent with these observations (Abraham et al. 2005). We found that the constrictor response to aerosolized brevetoxins was not limited to allergic animals. Normal (i.e., nonallergic) animals responded with a dose-dependent bronchoconstrictor response to inhaled toxin, and although there was tendency for the allergic animals to be more responsive, the difference was not significant. The similarity in responsiveness between the two groups was attributed to the fact that the allergic sheep had not seen allergen during the course of the studies and so the inflammatory status of their airways was similar to that of the nonallergic animals (Abraham et al. 2005). However, when the airways of allergic sheep are inflamed, as is the case after an antigen challenge (Abraham et al. 1994, 2000), the response to brevetoxin is enhanced (Figure 6). Thus, the response to toxin is not linked to the allergic status per se but is affected by the inflammatory status of the airways at the time of toxin exposure. Even though toxin can elicit respiratory symptoms in both normal and compromised airways, a major aim of the present study was to identify asthma medications that could provide protective and/or therapeutic effects against toxin-induced bronchoconstriction. We used crude brevetoxins for these studies because we considered this aerosol more relevant to natural exposures experienced by persons living in coastal areas. To provide a more severe stimulus, higher concentrations of toxin were administered than used previously. The constrictor responses to PbTx-3 and crude brevetoxins at concentrations 10-to 100-fold lower were similar to those seen here and were inhibited by cromolyn sodium, atropine, and diphenhydramine (Abraham et al. 2005). Although atropine and diphenhydramine are not considered standard therapy for the treatment of asthma, the findings that these drugs blocked the responses to an increased toxin burden are important because they confirm that the protective effects seen previously were not dose dependent and that the same mechanisms are operative at higher toxin levels. Pretreatment with inhaled budesonide and albuterol provided significant protection against the toxin-induced bronchoconstriction. Acutely administered, the glucocorticosteroid budesonide is not a bronchodilator bronchodilator /bron·cho·di·la·tor/ (-di´la-ter) 1. expanding the lumina of the air passages of the lungs. 2. an agent which causes dilatation of the bronchi. nor does it affect cholinergic responsiveness; therefore, its acute protective effects may be related to the drug's ability to prevent mast cell activation in vivo (Denburg 1997; Kamada and Szefler 1995). This action would reduce the histaminergic component of the response. [[beta].sub.2] adrenergic agents, in addition to their bronchodilatory activity, can also reduce mediator release (Wanner et al. 1987); therefore, such a mechanism could contribute to and possibly explain the slightly enhanced protection afforded by albuterol (Figure 1). The bronchodilatory activity normally attributed to [beta].sub.2] adrenergic agents is illustrated in Figure 2, where the albuterol is shown to reverse the toxin-induced bronchoconstriction. The latter effect is relevant to affected individuals that require rescue medication when exposed to aerosolized red tide toxins. We previously reported that inhalation challenge with a variety of noxious agents results in increased tissue kallikrein activity and subsequent kinin generation in the airways. Increased kinin levels are associated with bronchoconstriction, inflammation, and AHR (Forteza et al. 1994, 1996; Scuri et al. 2000). Kinins also cause airway wall edema edema (ĭdē`mə), abnormal accumulation of fluid in the body tissues or in the body cavities causing swelling or distention of the affected parts. , which can influence the relaxation of the airways after a contractile stimulus (Wagner 1997). Asthmatic subjects are more sensitive to the effect of inhaled kinins than are normal individuals (Fuller et al. 1987). Inhaled bradykinin caused cough and retrosternal discomfort in both normal and asthmatic subjects, but caused bronchoconstriction only in the asthmatics (Fuller et al. 1987). Interestingly, this difference in kinin sensitivity could explain why Backer et al. 2003, 2005) were unable to demonstrate pulmonary function changes in normal subjects exposed to toxin even though they complained of chest discomfort, as opposed to Fleming et al. (2005), who were able to demonstrate pulmonary function changes in toxin-exposed asthmatics. Thus, kinin generation could be a contributing mechanism responsible for the heightened sensitivity of asthmatic subjects to toxin. Our data showing that the bradykinin [B.sub.2] receptor antagonist HOE-140 significantly reduced the bronchoconstrictor response to inhaled toxin suggest that toxin stimulated increased kinin levels in the airway. These findings may be of greater consequence in terms of repeated exposures where increased kinins could contribute to inflammation and AHR (Zaias et al. 2004). Given the increased sensitivity of asthmatics to bradykinin (Fuller et al. 1987), our findings suggest that activation of the kinin pathway by brevetoxins could be another mechanism that contributes to more severe responses in patients with compromised airways. In allergic sheep, the ICR to injected A. suum antigen is mast cell mediated, and antihistamines Antihistamines Definition Antihistamines are drugs that block the action of histamine (a compound released in allergic inflammatory reactions) at the H1 block this response (Ahmed et al. 1993; Lucia et al. 1992). We have used skin tests in combination with inhalation challenge tests to demonstrate that tryptase activates mast cells (Molinari et al. 1995, 1996). The data suggesting that inhaled toxin stimulates airway mast cells/basophils led us to test this hypothesis in the skin. Both crude brevetoxins and PbTx-3 induced ICRs, which were significantly reduced in the presence of diphenhydramine. These findings provide additional evidence that toxin activates mast cells in viva. We should caution, however, that although the collective airway and skin data strongly argue in favor of mast cell hypothesis, final validation must be withheld until histamine measurements are obtained from lung and skin fluids. Nevertheless, if the findings in the airways and skin can be extrapolated to humans, then one might speculate that normal subjects, who would not generally have access to inhaled steroids and/or [[beta].sub.2] adrenergics, might obtain relief from toxin-induced irritation with antihistamines. The collective data from the skin and the airways prompted a number of questions regarding toxin-allergen interactions. These questions were precipitated by reports of adverse respiratory events hours after the original toxin exposure in susceptible individuals. In an attempt to mimic this scenario in the laboratory, we determined if a single toxin exposure could stimulate the development of a LAR and AHR, similar to that seen with allergen. We were unable to demonstrate this effect. Similarly, we were unable to show that exposures for 3 consecutive days to PbTx-3 accentuated the response to allergen. These findings indicate that, although toxin elicits an acute bronchoconstriction, the stimulus and/ or signaling mechanisms are not the same as seen with allergen that can result in a LAR and AHR. Furthermore, under the conditions of the experimental protocol, repeated toxin exposure was an insufficient stimulus to prime the airways such that the response to allergen challenge was augmented. We did find that allergen challenge accentuated the response to toxin. The increased responsiveness occurred during the period when the airways are actively inflamed and when they demonstrate increased responsiveness to other constricting con·strict v. con·strict·ed, con·strict·ing, con·stricts v.tr. 1. To make smaller or narrower by binding or squeezing. 2. To squeeze or compress. 3. agents, as seen previously (Abraham et al. 1994, 2000) and here with carbachol. Although the data in the present study were generated in an acute setting, there is a parallel to the more chronic situation that exists in asthmatics whose airways are chronically inflamed and have heightened sensitivity to a variety of nonspecific bronchoconstrictors. Thus, the contention that the airways of asthmatics may be more sensitive to inhaled toxins than those of persons with normal airways may depend, in part, on the status of airway inflammation at the time of exposure. In summary, we have provided new data concerning the airway effects of inhaled brevetoxins. We have identified clinical drugs that may be useful in the prevention and treatment of toxin-induced bronchial responses. Confirmation of these results must await controlled clinical trials. Nevertheless, given the caveat that these findings are based on experimental data collected in animals, our results may be of benefit to individuals affected by aerosolized brevetoxins at environmentally relevant levels. REFERENCES Abraham WM. 2000. Animal models of asthma. In: Asthma and Rhinitis Rhinitis Definition Rhinitis is inflammation of the mucous lining of the nose. Description Rhinitis is a nonspecific term that covers infections, allergies, and other disorders whose common feature is the location of their symptoms. (Busse WW, Holgate ST, eds). Oxford: Blackwell Science, 1205-1227. Abraham WM, Ahmed A, Cortes A, Soler M, Farmer SG, Baugh LE, et al. 1991. Airway effects of inhaled bradykinin, substance P, and neurokinin A in sheep. J Allergy Clin Immunol 87:557-564. Abraham WM, Ahmed A, Serebriakov I, Carmillo AN, Ferrant J, de Fougerolles AR, et al. 2004. A monoclonal antibody to a1b1 blocks antigen-induced airway responses in sheep. Am J Respir Crit Care Meal 169:97-104. Abraham WM, Bourdelais AJ, Sabater JR, Ahmed A, Lee TA, Serebriakov I, et al. 2005. Airway responses to aerosolized brevetoxins in an animal model of asthma. Am J Respir Crit Care Med 171:26-34. Abraham WM, Gill A, Ahmed A, Sielczak MW, Lauredo IT, Botvinnikova Y, et al. 2000. A small-molecule, tight binding inhibitor of the integrin integrin /in·te·grin/ (in´te-grin) any of a family of heterodimeric cell adhesion receptors, each consisting of an a and a ß polypetide chain, that mediate cell-to-cell and cell-to–extracellular matrix interactions. alpha(4)beta(1) blocks antigen-induced airway responses and inflammation in experimental asthma in sheep. Am J Respir Crit Care Med 162:603-611. Abraham WM, Januskiewicz A J, Mingle M, Welker M, Wanner A, Sackner MA. 1980. The sensitivity of bronchoprovocation and tracheal mucous velocity in detecting airway responses to [O.sub.3]. J Appl Physiol 48:789-793. Abraham WM, Oliver W Jr, Welker M J, King M, Wanner A, Sackner MA. 1981. Differences in airway reactivity in normal and allergic sheep after exposure to sulfur dioxide. J Appl Physiol 51:1651-1656. Abraham WM, Sielczak MW, Ahmed A, Cortes A, Lauredo IT, Kim J, et al. 1994. [Alpha.sub.4]-integrins mediate antigen-induced late bronchial responses and prolonged airway hyperresponsiveness in sheep. J Clin Invest 93:776-787. Ahmed T, Syriste T, Lucio J, Abraham W, Robinson M, D'Brot J. 1993. Inhibition of antigen-induced airway and cutaneous responses by heparin: a pharmacodynamic study. J Appl Physiol 74(4):1492-1498. Asai S, Krzanowski JJ, Anderson WH. 1982. Effects of the toxin of red tide, Ptychodiscus brevis, on canine tracheal smooth muscle: a possible new asthma triggering mechanism. J Allergy Clin Immunol 69:418-428. Backer LC, Fleming LE, Rowan A, Cheng YS, Benson J, Pierce RH, et al. 2003. Recreational exposure to aerosolized brevetoxins during Florida red tide events. Harmful Algae algae (ăl`jē) [plural of Lat. alga=seaweed], a large and diverse group of primarily aquatic plantlike organisms. These organisms were previously classified as a primitive subkingdom of the plant kingdom, the thallophytes (plants that 2:19-28. Backer LC, Kirkpatrick B, Fleming LE, Cheng YS, Pierce R, Bean JA, et al. 2005. Occupational exposure to aerosolized brevetoxins during Florida red tide events: effects on a healthy worker population. Environ Health Perspect 113:644-649. Baden DG. 1989. Brevetoxins: unique polyether dinoflagellate toxins. FASEB FASEB Federation of American Societies for Experimental Biology 3:1807-1817. Baden DG, Melinek R, Sechet V, Trainer VL, Schultz DR, Rein KD, et al. 1995. Modified immunoassays for polyether toxins: implications of biological markers, metabolic states, and epitope epitope: see immunity. recognition. J AOAC AOAC Association of Official Analytical Chemists (now AOAC International) AOAC Association of Analytical Communities AOAC Association of Analytical Chemists AOAC Always On/Always Connected AOAC Aero-Optic Evaluation Center Int 78:499-508. Baden DG, Tomes CR. 1988. Variations in major toxin composition for six clones of Ptychodiscus brevis. Toxicon 26:961-983. Denburg JA. 1997. Effects of corticosteroids Corticosteroids Definition Corticosteroids are group of natural and synthetic analogues of the hormones secreted by the hypothalamic-anterior pituitary-adrenocortical (HPA) axis, more commonly referred to as the pituitary gland. on basophils and mast cells. In: Inhaled Glucocorticoids Glucocorticoids Any of a group of hormones (like cortisone) that influence many body functions and are widely used in medicine, such as for treatment of rheumatoid arthritis inflammation. in Asthma (Schleimer RP, Busse WW, O'Byrne PM, eds). New York: Marcel Dekker, 259-277. Fleming LE, Kirkpatrick B, Racker LC, Bean JA, Wanner A, Dalpra D, et al. 2005. Initial evaluation of the effects of aerosolized Florida red tide toxins (brevetoxins) in persons with asthma. Environ Health Perspect 113:650-657. Forteza R, Botvinnikova Y, Ahmed A, Cortes A, Gundel RH, Wanner A, et al. 1996. The interaction of [a.sub.1]-proteinase inhibitor and tissue kallikrein in controlling allergic ovine ovine pertaining to, characteristic of, or derived from sheep. ovine atopic dermatitis symmetrical erythema, alopecia, lichenification, excoriation on woolless areas; sporadic cases, recur each summer. airway hyperresponsiveness. Am J Respir Crit Care Med 154:36-42. Forteza R, Lauredo I, Abraham WM, Conner GE. 1999. Bronchial tissue kallikrein activity is regulated by hyaluronic acid binding. Am J Respir Cell Mol Biol 21:666-674. Forteza R, Lauredo IT, Burch R, Abraham WM. 1994. Extracellular metabolites Metabolites Substances produced by metabolism or by a metabolic process. Mentioned in: Interactions of Pseudomonas aeruginosa produce bronchoconstriction by different mechanisms. Am J Respir Crit Care Med 149:687-693. Fuller RW, Dixon CS, Cuss FMC See fixed mobile convergence. , Barnes P J. 1987. Bradykinin-induced bronchoconstriction in humans: mode of action. Am Rev Respir Dis 135:176-180. Kamada AK, Szefler SJ. 2000. Blucocorticoids in asthma and rhinitis. In; Asthma and Rhinitis (Busse WW, Holgate ST, eds). Oxford: Blackwell Science Ltd, 1569-1581. Kirkpatrick B, Fleming LE, Squicciarini D, Backer LC, Clark R, Abraham W, et al. 2004. Literature review of Florida red tide: implications for human health effects. Harmful Algae 3:99-115. Lauredo IT, Forteza RM, Botvinnikova Y, Abraham WM. 2003. Leukocytic leukocytic pertaining to or emanating from leukocytes. leukocytic pyrogen protein substances, e.g. interleukin-1, which stimulate the thermoregulator center of the hypothalamus via prostaglandins; produced by bone-marrow derived cell sources of airway tissue kallikrein. Am J Physiol Lung Cell Mol Physiol 286:L734-L740. Lucio J, D'Brot J, Guo C, Abraham WM, Lichtenstein LM, Kagey-Sobotka A, et al. 1992. Immunologic mast cell-mediated responses and histamine release are attenuated Attenuated Alive but weakened; an attenuated microorganism can no longer produce disease. Mentioned in: Tuberculin Skin Test attenuated having undergone a process of attenuation. by heparin. J Appl Physiol 73(3):1093-1101. Mansour E, Ahmed A, Cortes A, Caplan J, Burch RM, Abraham WM. 1992. Mechanisms of metabisulfite-induced bronchoconstriction: evidence for bradykinin [[beta].sub.2] receptor stimulation. J Appl Physiol 72:1831-1837. Molinari JF, Moore WR, Clark J, Tanaka R, Butterfield JH, Abraham WM. 1995. The role of tryptase in immediate cutaneous responses in allergic sheep. J Appl Physiol 79:1966-1970. Molinari JF, Scuri M, Moore WR, Clark J, Tanaka R, Abraham WM. 1996. Inhaled tryptase causes bronchoconstriction in sheep via histamine release. Am J Respir Crit Care Med 154:649-653. Pierce RH, Henry MS, Blum PC, Lyons J, Cheng YS, Yazzie D, et al. 2003. Brevetoxin concentrations in marine aerosol: human exposure levels during a Karenia brevis harmful algal bloom. Bull Environ Contain Toxicol 70:161-165. Pierce RH, Henry MS, Proffitt LS, deRosset AJ. 1992. Evaluation of solid sorbents for the recovery of polyether toxins (brevetoxins) in seawater. Bull Environ Contain Toxicol 49:479-484. Pierce RH, Henry MS, Proffitt LS, Hasbrouck PA. 1990. Red tide toxin (brevetoxin) enrichment in marine aerosol. In: Toxic Marine Phytoplankton phytoplankton Flora of freely floating, often minute organisms that drift with water currents. Like land vegetation, phytoplankton uses carbon dioxide, releases oxygen, and converts minerals to a form animals can use. (Graneli E, Sundstron S, Elder L, Anderson DM, eds). New York: Elsevier, 397-402. Pierce RH, Kirkpatrick GJ. 2001. Innovative techniques for harmful algal algal pertaining to or caused by algae. algal infection is very rare but systemic and udder infections are recorded. See protothecosis. algal mastitis the algae Prototheca trispora and P. toxin analysis. Environ Toxicol Chem 20:107-114. Russi EW, Perruchoud AP, Yerger LD, Stevenson JS, Tabak J, Marchette B, et al. 1984. Late phase bronchial obstruction following non-immunologic mast cell degranulation degranulation the loss of granules; usually refers to the secretory granules in certain cells, e.g. pituitary chromophobes, acidophils and basophils. In basophils and mast cells, it is associated with the release of active substances from the cells and is characteristic of type I . J Appl Physiol 57:1182-1188. Scuri M, Botvinnikova Y, Lauredo IT, Abraham WM. 2002. Recombinant [a.sub.1]-proteinase inhibitor blocks antigen- and mediator-induced airway responses in sheep. J Appl Physiol 93:1900-1906. Scuri M, Forteza R, Lauredo I, Sabater JR, Botvinnikova Y, Allegra L, et al. 2000. Inhaled porcine porcine /por·cine/ (por´sin) pertaining to swine. porcine pertaining to pig. See also hog (1), swine. porcine circovirus 1 a nonpathogenic virus. pancreatic elastase causes bronchoconstriction via a bradykinin-mediated mechanism. J Appl Physiol 89:1397-1402. Shimoda T, Krzanowski J Jr, Nelson R, Martin DF, Polson J, Duncan R, et al. 1988. In vitro red tide toxin effects on human bronchial smooth muscle. J Allergy Clin Immunol 81:1187-1191. Wagner EM. 1997. Effects of edema on small airway narrowing. J Appl Physiol 83:784-791. Wanner A, Ahmed T, Abraham WM 1987. Drug actions on mediators. Drug therapy for asthma. In; Lung Biology and Health and Disease (Jenne JW, Murphy S, eds). New York: Marcel Dekker, 413-461. Zaias J, Botvinnikova Y, Fleming LE, Bossart GD, Baden DG, Abraham WM. 2004. Aerosolized polyether brevetoxin (PbTx) causes airway hyperresponsiveness (AHR) and airway inflammation in both normal and allergic sheep [Abstract]. Am J Respir Crit Care Med 169:A639. William M. Abraham, (1) Andrea J. Bourdelais, (2) Ashfaq Ahmed, (1) Irakli Serebriakov, (1) and Daniel G. Baden (2) (1) Division of Pulmonary and Critical Care Medicine, University of Miami This article is about the university in Coral Gables, Florida. For the university in Oxford, Ohio, see Miami University. The University of Miami (also known as Miami of Florida,[2] UM,[3] or just The U at Mount Sinai Medical Center, Miami Beach, Florida “Miami Beach” redirects here. For the beach in Barbados, see Miami Beach, Barbados.
Wilmington is a city in New Hanover County, North Carolina, United States. The population was estimated at 100,000 as of 2006;[1] , USA This article is part of the mini-monograph "Aerosolized Florida Red Tide Toxins (Brevetoxins)." Address correspondence to W.M. Abraham, Department of Research, Mount Sinai Medical Center, 4300 Alton Rd., Miami Beach, FL 33140 USA. Telephone: (305) 674-2790. Fax: (305) 674-2790. E-mail: abraham@msmc.com This research was supported by National Institute of Environmental Health Sciences The National Institute of Environmental Health Sciences (NIEHS) is one of 27 Institutes and Centers of the National Institutes of Health (NIH),which is a component of the Department of Health and Human Services (DHHS). The Director of the NIEHS is Dr. David A. Schwartz. grant P01 ES 10594. The authors declare they have no competing financial interests. Received 2 August 2004; accepted 13 January 2005. |
|
||||||||||||||||||
Printer friendly
Cite/link
Email
Feedback
Reader Opinion