Bacterial micro-aggregates as inoculum in animal models of implant-associated infections
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Bacterial micro-aggregates as inoculum in animal models of implant-associated infections. / Top Hartmann, Katrine; Lund Nielsen, Regitze; Mikkelsen, Freja Cecilie; Aalbæk, Bent; Lichtenberg, Mads; Holm Jakobsen, Tim; Bjarnsholt, Thomas; Kvich, Lasse; Ingmer, Hanne; Odgaard, Anders; Elvang Jensen, Henrik; Kruse Jensen, Louise.
In: Biofilm, Vol. 7, 100200, 06.2024.Research output: Contribution to journal › Journal article › Research › peer-review
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TY - JOUR
T1 - Bacterial micro-aggregates as inoculum in animal models of implant-associated infections
AU - Top Hartmann, Katrine
AU - Lund Nielsen, Regitze
AU - Mikkelsen, Freja Cecilie
AU - Aalbæk, Bent
AU - Lichtenberg, Mads
AU - Holm Jakobsen, Tim
AU - Bjarnsholt, Thomas
AU - Kvich, Lasse
AU - Ingmer, Hanne
AU - Odgaard, Anders
AU - Elvang Jensen, Henrik
AU - Kruse Jensen, Louise
N1 - Publisher Copyright: © 2024 The Authors
PY - 2024/6
Y1 - 2024/6
N2 - Is it time to rethink the inoculum of animal models of implant-associated infections (IAI)? Traditionally, animal models of IAI are based on inoculation with metabolically active overnight cultures of planktonic bacteria or pre-grown surface-attached biofilms. However, such inoculums do not mimic the clinical initiation of IAI. Therefore, the present study aimed to develop a clinically relevant inoculum of low metabolic micro-aggregated bacteria. The porcine Staphylococcus aureus strain S54F9 was cultured in Tryptone Soya Broth (TSB) for seven days to facilitate the formation of low metabolic micro-aggregates. Subsequently, the aggregated culture underwent filtration using cell strainers of different pore sizes to separate micro-aggregates. Light microscopy was used to evaluate the aggregate formation and size in the different fractions, while isothermal microcalorimetry was used to disclose a low metabolic activity. The micro-aggregate fraction obtained with filter size 5–15 μm (actual measured mean size 32 μm) was used as inoculum in a porcine implant-associated osteomyelitis (IAO) model and compared to a standard overnight planktonic inoculum and a sham inoculum of 0.9 % saline. The micro-aggregate and planktonic inoculums caused IAO with the re-isolation of S. aureus from soft tissues, bones, and implants. However, compared to their planktonic counterpart, neither of the micro-aggregate inoculated animals showed signs of osteomyelitis, i.e., sequester, osteolysis, and pus at gross inspection. Furthermore, inoculation with low metabolic micro-aggregates resulted in a strong healing response with pronounced osteoid formation, comparable to sham animals. In conclusion, the formation and separation of low metabolic bacterial micro-aggregates into various size fractions is possible, however, planktonic bacteria were still seen in all size fractions. Inoculation with micro-aggregates caused a less-aggressive osteomyelitis i.e. combination of infected tissue and strong healing response. Therefore, the use of low metabolic micro-aggregates could be a relevant inoculum for animal models of less-aggressive and thereby slower developing IAI and add in to our understanding of the host-implant-bacteria interactions in slow-onset low-grade infections.
AB - Is it time to rethink the inoculum of animal models of implant-associated infections (IAI)? Traditionally, animal models of IAI are based on inoculation with metabolically active overnight cultures of planktonic bacteria or pre-grown surface-attached biofilms. However, such inoculums do not mimic the clinical initiation of IAI. Therefore, the present study aimed to develop a clinically relevant inoculum of low metabolic micro-aggregated bacteria. The porcine Staphylococcus aureus strain S54F9 was cultured in Tryptone Soya Broth (TSB) for seven days to facilitate the formation of low metabolic micro-aggregates. Subsequently, the aggregated culture underwent filtration using cell strainers of different pore sizes to separate micro-aggregates. Light microscopy was used to evaluate the aggregate formation and size in the different fractions, while isothermal microcalorimetry was used to disclose a low metabolic activity. The micro-aggregate fraction obtained with filter size 5–15 μm (actual measured mean size 32 μm) was used as inoculum in a porcine implant-associated osteomyelitis (IAO) model and compared to a standard overnight planktonic inoculum and a sham inoculum of 0.9 % saline. The micro-aggregate and planktonic inoculums caused IAO with the re-isolation of S. aureus from soft tissues, bones, and implants. However, compared to their planktonic counterpart, neither of the micro-aggregate inoculated animals showed signs of osteomyelitis, i.e., sequester, osteolysis, and pus at gross inspection. Furthermore, inoculation with low metabolic micro-aggregates resulted in a strong healing response with pronounced osteoid formation, comparable to sham animals. In conclusion, the formation and separation of low metabolic bacterial micro-aggregates into various size fractions is possible, however, planktonic bacteria were still seen in all size fractions. Inoculation with micro-aggregates caused a less-aggressive osteomyelitis i.e. combination of infected tissue and strong healing response. Therefore, the use of low metabolic micro-aggregates could be a relevant inoculum for animal models of less-aggressive and thereby slower developing IAI and add in to our understanding of the host-implant-bacteria interactions in slow-onset low-grade infections.
KW - Animal model
KW - Bacterial aggregates
KW - Biofilm
KW - Implant-related infections
KW - Infection
U2 - 10.1016/j.bioflm.2024.100200
DO - 10.1016/j.bioflm.2024.100200
M3 - Journal article
AN - SCOPUS:85193075960
VL - 7
JO - Biofilm
JF - Biofilm
SN - 2590-2075
M1 - 100200
ER -
ID: 392579216