Beth L Hahn1, Peter G Sohnle. 1. Division of Infectious Diseases, Department of Medicine, Medical College of Wisconsin, Milwaukee, WI 53226, USA.
Abstract
BACKGROUND: Staphylococcus aureus can invade the bloodstream and cause bacteremic infections, but this organism frequently produces serious deep infections without bacteremia or an identifiable portal of entry. METHODS: We used experimental cutaneous S. aureus infections in mice to determine if the bacteria could reach deep organs without travel through the bloodstream. RESULTS: After skin surface application the bacteria rapidly distributed to lymph nodes, spleen, kidneys and other organs. In these animals, blood cultures were negative, dissemination was more efficient after surface application than injection near dermal blood vessels, and kidney bacterial localization sites were unlike those of bacteremic infections. Whereas normal mice eventually cleared bacteria from the deep sites, those with prolonged immunosuppression became moribund from these infections; they also had negative blood cultures and kidney localization not consistent with hematogenous dissemination. Bacteria were also found in the intervening abdominal wall outside the spleen and kidney sites, suggesting direct movement of the organisms from the skin surface through connecting tissues. CONCLUSIONS: Although capable of hematogenous dissemination, S. aureus can also spread from skin to deep organs by a non-bacteremic process. In this case the bacteria appear to migrate directly from the skin surface to the deep organs below. Published by Elsevier Ltd.
BACKGROUND:Staphylococcus aureus can invade the bloodstream and cause bacteremic infections, but this organism frequently produces serious deep infections without bacteremia or an identifiable portal of entry. METHODS: We used experimental cutaneous S. aureus infections in mice to determine if the bacteria could reach deep organs without travel through the bloodstream. RESULTS: After skin surface application the bacteria rapidly distributed to lymph nodes, spleen, kidneys and other organs. In these animals, blood cultures were negative, dissemination was more efficient after surface application than injection near dermal blood vessels, and kidney bacterial localization sites were unlike those of bacteremic infections. Whereas normal mice eventually cleared bacteria from the deep sites, those with prolonged immunosuppression became moribund from these infections; they also had negative blood cultures and kidney localization not consistent with hematogenous dissemination. Bacteria were also found in the intervening abdominal wall outside the spleen and kidney sites, suggesting direct movement of the organisms from the skin surface through connecting tissues. CONCLUSIONS: Although capable of hematogenous dissemination, S. aureus can also spread from skin to deep organs by a non-bacteremic process. In this case the bacteria appear to migrate directly from the skin surface to the deep organs below. Published by Elsevier Ltd.
Authors: Michael Zakrewsky; Katherine S Lovejoy; Theresa L Kern; Tarryn E Miller; Vivian Le; Amber Nagy; Andrew M Goumas; Rashi S Iyer; Rico E Del Sesto; Andrew T Koppisch; David T Fox; Samir Mitragotri Journal: Proc Natl Acad Sci U S A Date: 2014-08-25 Impact factor: 11.205
Authors: Romina S Goldszmid; Amiran Dzutsev; Sophie Viaud; Laurence Zitvogel; Nicholas P Restifo; Giorgio Trinchieri Journal: Cancer Immunol Res Date: 2015-02 Impact factor: 11.151
Authors: Gregor Reid; Patrizia Brigidi; Jeremy P Burton; Nikhat Contractor; Sylvia Duncan; Emilie Fargier; Colin Hill; Sarah Lebeer; Rocio Martín; Andrew J McBain; Gil Mor; Catherine O'Neill; Juan Miguel Rodríguez; Jonathan Swann; Saskia van Hemert; Juliett Ansell Journal: Am J Reprod Immunol Date: 2014-09-24 Impact factor: 3.886
Authors: Philipp Starkl; Martin L Watzenboeck; Lauren M Popov; Sophie Zahalka; Anastasiya Hladik; Karin Lakovits; Mariem Radhouani; Arvand Haschemi; Thomas Marichal; Laurent L Reber; Nicolas Gaudenzio; Riccardo Sibilano; Lukas Stulik; Frédéric Fontaine; André C Mueller; Manuel R Amieva; Stephen J Galli; Sylvia Knapp Journal: Immunity Date: 2020-09-09 Impact factor: 43.474