Statistical Analysis of Long- and Short-Range Forces Involved in Bacterial Adhesion to Substratum Surfaces as Measured Using Atomic Force Microscopy

Chen, Yun; Busscher, Henk J.; Mei, Henny C. van der; Norde, Willem

doi:10.1128/aem.00502-11

Cited by 73 publications

(77 citation statements)

References 41 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Moreover, in a long-range approach, surface appendages may be less important, as the concept of distance between bacteria and substratum surfaces is lost upon close approach. Long-range Lifshitz-Van der Waals adhesion forces can be derived from contact angles with liquids on the interacting surfaces and surface thermodynamic modeling (25,26) or decoupling of AFM adhesion force measurements using Poisson analysis (27)(28)(29)(30). However, among different strains, long-range adhesion forces vary considerably less than short-range forces (27)(28)(29)(30).…”

Section: Discussionmentioning

confidence: 99%

“…Long-range Lifshitz-Van der Waals adhesion forces can be derived from contact angles with liquids on the interacting surfaces and surface thermodynamic modeling (25,26) or decoupling of AFM adhesion force measurements using Poisson analysis (27)(28)(29)(30). However, among different strains, long-range adhesion forces vary considerably less than short-range forces (27)(28)(29)(30). Similarity in long-range adhesion forces is to be expected, because these forces arise from the entire bacterial cell, i.e., its DNA content, cytoplasm, cell membrane, peptidoglycan layer, and outermost cell wall structures (Fig.…”

Section: Discussionmentioning

confidence: 99%

See 1 more Smart Citation

Nanoscale Cell Wall Deformation Impacts Long-Range Bacterial Adhesion Forces on Surfaces

Chen

Harapanahalli

Busscher

et al. 2014

Appl Environ Microbiol

Self Cite

View full text Add to dashboard Cite

Adhesion of bacteria occurs on virtually all natural and synthetic surfaces and is crucial for their survival. Once they are adhering, bacteria start growing and form a biofilm, in which they are protected against environmental attacks. Bacterial adhesion to surfaces is mediated by a combination of different short-and long-range forces. Here we present a new atomic force microscopy (AFM)-based method to derive long-range bacterial adhesion forces from the dependence of bacterial adhesion forces on the loading force, as applied during the use of AFM. The long-range adhesion forces of wild-type Staphylococcus aureus parent strains (0.5 and 0.8 nN) amounted to only one-third of these forces measured for their more deformable isogenic ⌬pbp4 mutants that were deficient in peptidoglycan cross-linking. The measured long-range Lifshitz-Van der Waals adhesion forces matched those calculated from published Hamaker constants, provided that a 40% ellipsoidal deformation of the bacterial cell wall was assumed for the ⌬pbp4 mutants. Direct imaging of adhering staphylococci using the AFM peak force-quantitative nanomechanical property mapping imaging mode confirmed a height reduction due to deformation in the ⌬pbp4 mutants of 100 to 200 nm. Across naturally occurring bacterial strains, long-range forces do not vary to the extent observed here for the ⌬pbp4 mutants. Importantly, however, extrapolating from the results of this study, it can be concluded that long-range bacterial adhesion forces are determined not only by the composition and structure of the bacterial cell surface but also by a hitherto neglected, small deformation of the bacterial cell wall, facilitating an increase in contact area and, therewith, in adhesion force. Bacteria adhere to virtually all natural and synthetic surfaces (1, 2), as adhesion is crucial for their survival. Bacterial adhesion to surfaces is followed by their growth and constitutes the first step in the formation of a biofilm, in which organisms are protected against antimicrobial treatment and environmental attacks. Accordingly, the biofilm mode of growth is highly persistent and biofilms are notoriously hard to remove, causing major problems in many industrial and biomedical applications, with high associated costs. On the other hand, biofilms can be beneficial, too, as in the bioremediation of soil, for instance. Surface thermodynamics and (extended) DLVO (Derjaguin and Landau, Verwey, and Overbeek) approaches have been amply applied in current microbiology to outline that bacterial adhesion to surfaces is mediated by an interplay of different fundamental physicochemical interactions, including Lifshitz-Van der Waals, electric double-layer, and acid-base forces (3-5). Assorted according to their different effective ranges, these different fundamental interactions can be alternatively categorized into two groups, short-range and long-range forces (6), that act over distances of a few nm up to 10s of nm, respectively.Long-range adhesion forces are generally associated with Lifshitz-Van der ...

show abstract

Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Nanoscale Cell Wall Deformation Impacts Long-Range Bacterial Adhesion Forces on Surfaces

Chen

Harapanahalli

Busscher

et al. 2014

Appl Environ Microbiol

Self Cite

View full text Add to dashboard Cite

show abstract

“…Minor unbinding events observed at 60 seconds surface delays were fitted to predict contour lengths according to the previously described worm-like chain (WLC) model. 28 Further decoupling of bacterial adhesion forces was performed with Poisson analysis according to a previously reported approach, 29 obtaining values for both short-range (F SR ) and long-range force (F LR ) components.…”

Section: Data Extraction and Statistical Analysismentioning

confidence: 99%

“…To decouple the adhesion between S. sanguinis and Ti, a previously reported statistical method known as Poisson analysis was employed 29 ( Figure 3B and C). By plotting a linear regression between mean adhesion force (nN) and variance (nN 2 ) of the minor unbinding peaks observed between four independent bacterial probes and substrate, it was possible to determine values for F SR and F LR .…”

Section: Poisson Analysis Of Unbinding Events For Force Decouplingmentioning

confidence: 99%

Probing the nanoadhesion of Streptococcus sanguinis to titanium implant surfaces by atomic force microscopy

Aguayo¹,

Donos²,

Spratt³

et al. 2016

IJN

View full text Add to dashboard Cite

As titanium (Ti) continues to be utilized in great extent for the fabrication of artificial implants, it is important to understand the crucial bacterium–Ti interaction occurring during the initial phases of biofilm formation. By employing a single-cell force spectroscopy technique, the nanoadhesive interactions between the early-colonizing Streptococcus sanguinis and a clinically analogous smooth Ti substrate were explored. Mean adhesion forces between S. sanguinis and Ti were found to be 0.32±0.00, 1.07±0.06, and 4.85±0.56 nN for 0, 1, and 60 seconds contact times, respectively; while adhesion work values were reported at 19.28±2.38, 104.60±7.02, and 1,317.26±197.69 aJ for 0, 1, and 60 seconds, respectively. At 60 seconds surface delays, minor-rupture events were modeled with the worm-like chain model yielding an average contour length of 668±12 nm. The mean force for S. sanguinis minor-detachment events was 1.84±0.64 nN, and Poisson analysis decoupled this value into a short-range force component of −1.60±0.34 nN and a long-range force component of −0.55±0.47 nN. Furthermore, a solution of 2 mg/mL chlorhexidine was found to increase adhesion between the bacterial probe and substrate. Overall, single-cell force spectroscopy of living S. sanguinis cells proved to be a reliable way to characterize early-bacterial adhesion onto machined Ti implant surfaces at the nanoscale.

show abstract

“…More recently, the adhesion forces between Gram negative with Gram positive bacterial biofilms have been compared [18], with the interesting result that Gram positive bacteria are densely packed with EPS, possessing high adhesion forces and short distance snap-off events, compared to the smaller adhesion forces and less dense packing found in Gram negative bacterial biofilms. Statistical analyses of Staphylococcus epidermis adhesion forces as measured by AFM, employing single bacterial cells immobilised at the cantilever apex, have offered insight into the mechanisms of bacterial adhesion, encompassing both long-range and short-range forces [19].…”

Section: Introductionmentioning

confidence: 99%

Characterisation of spin coated engineered Escherichia coli biofilms using atomic force microscopy

Tsoligkas

Bowen

Winn

et al. 2012

Colloids and Surfaces B: Biointerfaces

View full text Add to dashboard Cite

The ability of biofilms to withstand chemical and physical extremes gives them the potential to be developed as robust biocatalysts. Critical to this issue is their capacity to withstand the physical environment within a bioreactor; in order to assess this capability knowledge of their surface properties and adhesive strength is required. Novel atomic force microscopy experiments conducted under growth conditions (30 o C) were used to characterise Escherichia coli biofilms, which were generated by a recently developed spin-coating method onto a poly-L-lysine coated glass substrate. High-resolution topographical images were obtained throughout the course of biofilm development, quantifying the tip-cell interaction force during the 10 day maturation process. Strikingly, the adhesion force between the Si AFM tip and the biofilm surface increased from 0.8 nN to 40 nN within 3 days. This was most likely due to the production of extracellular polymer substance (EPS), over the maturation period, which was also observed by electron microscopy. At later stages of maturation, multiple retraction events were also identified corresponding to biofilm surface features thought to be EPS components. The spin coated biofilms were shown to have stronger surface adhesion than an equivalent conventionally grown biofilm on the same glass substrate.

show abstract

Statistical Analysis of Long- and Short-Range Forces Involved in Bacterial Adhesion to Substratum Surfaces as Measured Using Atomic Force Microscopy

Cited by 73 publications

References 41 publications

Nanoscale Cell Wall Deformation Impacts Long-Range Bacterial Adhesion Forces on Surfaces

Nanoscale Cell Wall Deformation Impacts Long-Range Bacterial Adhesion Forces on Surfaces

Probing the nanoadhesion of Streptococcus sanguinis to titanium implant surfaces by atomic force microscopy

Characterisation of spin coated engineered Escherichia coli biofilms using atomic force microscopy

Contact Info

Product

Resources

About