AIMS: To determine the effects of surface cell concentration and phase of growth on the inactivation of Escherichia coli cells using an atmospheric nonthermal plasma. METHODS AND RESULTS: Cells of E. coli K12 were deposited onto the surface of membrane filters and exposed to the plume from a cold atmospheric gas plasma. Scanning electron microscopy revealed severe loss in structural integrity of plasma-treated cells, and optical emission spectra indicated that inactivation was brought about by reactive plasma species. The survival of E. coli cells was found to depend on the cell surface density: as the surface density increased from 10(7) to 10(11) CFU cm(-2), the rate constant in the Baranyi inactivation model decreased from 19.59 to 1.03 min(-1). Cells harvested from mid-exponential, late exponential and stationary phases of growth displayed differences in their resistances to the effects of the plasma however, exponential phase cells were not more susceptible than those from the stationary phase. CONCLUSIONS: High surface concentrations of cells affects the penetration of plasma species and treatment effectiveness. The physiological state of cells, as determined by phase of growth, affects their resistance to plasma inactivation. SIGNIFICANCE AND IMPACT OF THE STUDY: In designing inactivation treatments, surface concentration and cell physiology need to be taken into account.
AIMS: To determine the effects of surface cell concentration and phase of growth on the inactivation of Escherichia coli cells using an atmospheric nonthermal plasma. METHODS AND RESULTS: Cells of E. coli K12 were deposited onto the surface of membrane filters and exposed to the plume from a cold atmospheric gas plasma. Scanning electron microscopy revealed severe loss in structural integrity of plasma-treated cells, and optical emission spectra indicated that inactivation was brought about by reactive plasma species. The survival of E. coli cells was found to depend on the cell surface density: as the surface density increased from 10(7) to 10(11) CFU cm(-2), the rate constant in the Baranyi inactivation model decreased from 19.59 to 1.03 min(-1). Cells harvested from mid-exponential, late exponential and stationary phases of growth displayed differences in their resistances to the effects of the plasma however, exponential phase cells were not more susceptible than those from the stationary phase. CONCLUSIONS: High surface concentrations of cells affects the penetration of plasma species and treatment effectiveness. The physiological state of cells, as determined by phase of growth, affects their resistance to plasma inactivation. SIGNIFICANCE AND IMPACT OF THE STUDY: In designing inactivation treatments, surface concentration and cell physiology need to be taken into account.
Authors: C Schaudinn; D Jaramillo; M O Freire; P P Sedghizadeh; A Nguyen; P Webster; J W Costerton; C Jiang Journal: Int Endod J Date: 2013-03-11 Impact factor: 5.264
Authors: Ji Hoon Park; Naresh Kumar; Dae Hoon Park; Maksudbek Yusupov; Erik C Neyts; Christof C W Verlackt; Annemie Bogaerts; Min Ho Kang; Han Sup Uhm; Eun Ha Choi; Pankaj Attri Journal: Sci Rep Date: 2015-09-09 Impact factor: 4.379
Authors: Saga Helgadóttir; Santosh Pandit; Venkata R S S Mokkapati; Fredrik Westerlund; Peter Apell; Ivan Mijakovic Journal: Front Cell Infect Microbiol Date: 2017-02-22 Impact factor: 5.293
Authors: Susanne Gorynia; Ina Koban; Rutger Matthes; Alexander Welk; Sabine Gorynia; Nils-Olaf Hübner; Thomas Kocher; Axel Kramer Journal: GMS Hyg Infect Control Date: 2013-04-29
Authors: Lu Han; Dana Ziuzina; Caitlin Heslin; Daniela Boehm; Apurva Patange; David M Sango; Vasilis P Valdramidis; Patrick J Cullen; Paula Bourke Journal: Front Microbiol Date: 2016-06-22 Impact factor: 5.640