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How Biofilm Affects the Patient Recovery at the Hospital
Jani Mesa Gil
Barry University
How Biofilm Affects the Patient Recovery at the Hospital
Regulating biofilms for injury and insertion can have various adverse effects on patient well-being,
including delayed recovery and implant evacuation. Currently, Biofilm drugs do not destroy or prevent
microbial colonization, indicating the need for further research. The final review of drugs for biofilms
focuses on components of nanotechnology-based drug delivery, combination therapy, and coupling repair.
Ultrasonic cleaning and hydrogels and recent improvements in incorporation have great potential for use
in discrete trauma and medicine applications. This study analyzes the impacts of Biofilms on patient
recovery in hospitals by providing various literature reviews on the development of microorganisms in
biofilms and how it affects patient recovery at the hospital, as well as methodologies applied during the
research study.
Problem statement
Patients with biofilms wounds excrete various microbes from their skin and current state. If they
receive hospitalization for treatment, they are likely to receive MRE and HAI from surfaces, patients,
staff, and emergency department equipment (Wu et al., 2018). Since biofilms no longer destroy or prevent
microbial colonization, there is a need for medical researchers to carry out further research to establish
how biofilms can affect or impact patient recovery in hospitals.
Research question
What is a biofilm, and how is it treated?
How do biofilms affect patient recovery at the hospital?
Purpose of the study
The purpose of this study is to understand how biofilms can impact the process of recovery among
patients in hospitals.
Significance of the study
This study is significant because it provides researchers with further understanding of the impacts
of biofilms on patient recovery. Furthermore, it helps researchers develop an alternative drug to
administer to patients to protect them against microbial colonization.
Hypothesis
i. Microbial biofilms cause prolonged healing and recovery in patients ii. The host can lead to an extended healing process because the body treats microbial biofilms as a
logical consequence of the inability to rebuild skin integrity.
Description of published literature on the topic
According to Wu and his colleagues, patients with biofilms wounds excrete various microbes from
their skin and current state. If they receive hospitalization for treatment, they are likely to receive MRE
and HAI from surfaces, patients, staff, and emergency department equipment (Wu et al., 2018). This
literature states that such patients have high levels of biofilm contamination for biofilm reduction
applications in consuming patients, including silver and various metals. Other elements indicating this
condition include disinfectants, hydrogels, and light and sonic treatments to initiate atomic sensitization to
deliver dynamic oxygen (Wu et al., 2018). Small particles of these contaminants allow penetration into
the dividing layer of cells, glycans, lactobacilli, and treatment with phages.
Other scholars such as Muhammad et al. (2020) and Barzegari et al. (2020) assert that the
accumulation of microorganisms can be immobile and live and attached to the surface. The regimen of
this group of people is not the same as that of planktonic development, where microorganisms are isolated
and flexible in the environment (Muhammad et al., 2020). Cecillus cells differ from planktonic cells in
morphology, physiology, and qualitative articulation. The ability to adhere to and thrive on surfaces such
as biofilms is a gradual survival process that allows microorganisms to colonize the zone (Muhammad et
al., 2020). Microbes are constantly changing from planktonic aggregates to passive ones. This variety of
conditions is key for cells as they allow rapid changes in their natural state.
Wound swelling can be characterized as the ability of microorganisms to thrive when antimicrobial
compounds are present in the climate. The obstructive component is hereditary and prevents the antitoxin
from working for its purpose (Barzegari et al., 2020). This literature indicates that the term resistance
should be used for microbes that may be caused by high-class antibiotics but whose development is
delayed. This element, which explicitly describes the life of sessile bacteria, is reversible, phenotypic, and
non-obtainable. Biofilm bacterial cells re-suspended in liquid media will regain them in vitro
susceptibility to antimicrobial agents.
The journal by Thi et al. (2020) shows that the size of bacterial biofilm is a major break in the
phagocytic cycle. During internal immune reactions, macrophages and neutrophils are rapidly activated
upon direct contact with microorganisms (Thi et al., 2020). Here, the rapid, safe response leads to
significant neutrophil accumulation around the biofilm structure associated with oxygen exhaustion due to
functional stimulation of oxidative digestion when subatomic oxygen is reduced to superoxide.
Phagocytic cells infiltrate with extracellular tissue problems. Thi et al. (2020) assert that these cells
recover and are more susceptible to inactivation by bacterial chemicals. In addition, prolonged neutrophil
lysis causes the flux to a noxious mixed environment responsible for subsequent tissue damage. Resistant
host response is the main reason behind hard tissue damage by bacterial contamination.
Regarding the memory of resistant scaffold reactions, it has been reported that CF patients emit
specific antibodies against bacterial mixtures such as elastase, LPS, or flagella. This information indicates
that the antigenic determinant has been killed by continued lung contamination (Magana et al., 2018).
Unfortunately, these antibodies have been shown to contribute to the accelerated assembly of immune
structures in the parenchyma and result in extreme tissue damage through complementary initiation and
opsonization of neutrophils, particularly bypass. This literature postulate that the resistance of biofilms to
external influences, especially antitoxin drugs, is an unusual element. According to this research, the
MICs of antimicrobial formulations that were successful against sessile microbes were ten times greater
than those dynamic in their planktonic presentation (Magana et al., 2018). This decrease in antimicrobial
resistance can have several causes. Usually inherent in biofilms, but can also be acquired through the
inheritance of opposing factors.
Magana et al. (2018) state that the extracellular lattice provides a mechanical barrier that limits the
spread of infection within the biofilm and its access to microorganisms. The electrostatic charge or part of
the lattice binds and traps the antimicrobial atoms. The overall high consistency of the polymer network
may also prevent the anti-infective from reaching its focus in the deeper layers of the local area of the
bacteria (Magana et al., 2018). Thus, microscopic organisms in the outer layers of the biofilm pass after
antimicrobial treatment, while those in the deeper layers have a chance to react. This study shows that the
polymer binds to antimicrobial compounds in the periplasm, causing the antitoxin to diffuse into the cell
and preventing it from reaching its activity site.
Methodology
Design
In this research study, the researcher will use repeated measures experimental research design as a
methodology. Repeated measures are an experimental design where the same participants take part in
every condition of the independent variable. Therefore, every condition in the experiment will use a
similar set of participants. This type of experimental design is also known as the within-group or subject
design with the advantage of reduced participant variables and time-saving.
Variables
This research study has both independent and dependent variables. The independent variable is the
impacts or effects of biofilms, while the dependent variable is patient recovery.
Participants
The research will select its participants from one of the nearby hospitals. The participants are
supposed to be patients recovering from surgical wounds. More so, these patients must be facing
challenges with biofilms during their recovery period.
Controls
The control group in this experiment will be patients recovering from surgery but not infected with
biofilms. This will help in understanding how biofilms impact the recovery process among patients.
Sampling
The researcher in this study will utilize the random sampling method in selecting participants. This
sampling method is time-saving, requires few resources, and is reliable. The researcher intends to use at
least 30 experimental samples and 15 control samples to maximize the results.
Validity and Reliability
Throughout this study, the researcher will ensure that the research experiments and findings are
valid and drawn from existing knowledge. The researcher will ensure that the study is reliable through the
tools and methods he will use in carrying out the experiment, collecting data, and analyzing the collected
data.
Data Collection Technique
Observation and interviews will be utilized as data collection techniques in this research. The
researcher will observe the participants and not down their recovery duration in the presence of biofilms.
More so, the researcher will interview the participants to get their first-hand reactions to their recovery
process.
Research ethics
Throughout this research, the researcher will assure the participants that the research is voluntary
and they can opt out of it without any form of punishment. There will be no reward for the participants;
however, their information will remain confidential throughout the study and after the study since the
researcher intends to lock up the findings in his private study room for three years. There are minimal
risks associated with this research, including emotional discomfort, anxiety, and fear to open up about the
kinds of surgery.
References
Barzegari, A., Kheyrolahzadeh, K., Hosseiniyan Khatibi, S. M., Sharifi, S., Memar, M. Y., & Zununi
Vahed, S. (2020). The Battle of probiotics and their derivatives against Biofilms. Infection and
Drug Resistance, 13, 659-672. https://doi.org/10.2147/idr.s232982
Magana, M., Sereti, C., Ioannidis, A., Mitchell, C. A., Ball, A. R., Magiorkinis, E.,Chatzipanagiotou, S.,
Hamblin, M. R., Hadjifrangiskou, M., & Tegos, G. P. (2018). Options and limitations in clinical
investigation of bacterial Biofilms. Clinical Microbiology Reviews, 31(3).
https://doi.org/10.1128/cmr.00084-16
Muhammad, M. H., Idris, A. L., Fan, X., Guo, Y., Yu, Y., Jin, X., Qiu, J., Guan, X., & Huang, T. (2020).
Beyond risk: Bacterial Biofilms and their regulating approaches. Frontiers in Microbiology, 11.
https://doi.org/10.3389/fmicb.2020.00928
Thi, M. T., Wibowo, D., & Rehm, B. H. (2020). Pseudomonas aeruginosa Biofilms. International Journal
of Molecular Sciences, 21(22),8671. https://doi.org/10.3390/ijms21228671
Wu, Y., Cheng, N., & Cheng, C. (2018). Biofilms in chronic wounds: Pathogenesis and diagnosis. Trends
in Biotechnology, 37(5), 505-517. https://doi.org/10.1016/j.tibtech.2018.10.011