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- Introduction:
In the globe, various health issues have been faced by mankind. Skin burns are one of the common problems found all over the world. These result in many deaths due to improper facilities in the medical field. The infections after the burning of skin are responsible for serious health complications. The diabetic burn patient has a higher probability of getting nosocomial infection [1]. After the biopsy, 105 organisms were in the patients suffering from nosocomial burn wounds [1].
Nowadays, interdisciplinary research is being promoted that has created opportunities for scientists across the globe to work on treatment against the health problem in question. Currently, robotics is a suitable way to work in delicate environments. The burns, especially, third-degree burns take the patient’s life at greater risk and modern available medical facilities are not able to save the life of a person in such cases. This review focuses on the cause of infection and treatment of burnt patients, and the use of microbial robots to treat third-degree burnt patients.
- Need of study:
About 450,000 people are in search of treatment of injury by burn per year of which 40,000 were admitted to hospital and 3,000 died in the United States [3]. Inhalation injury increases the mortality and morbidity of the patients affected by burn injuries [4]. Surgical treatment is required by burn-injured patients [4], which is not cost-effective and not always results in saving a life. Risk factors such as difficulty in airway anatomy, burn shock as well as resuscitation, and inhalation injury leads to an increased probability of both morbidity and mortality [4].
There is a need to investigate altered pharmacodynamics and pharmacokinetics in patients suffering from a burn injury [4]. Unfortunately, there is the probability of losses of the volume of blood along with body temperature in the intraoperative period [4]. More size of burning, injury of inhalation, and connected trauma are responsible for increasing deaths after-burn incidences [6]. Social help may assist in the survival of patients [6].
- Causes of deaths/infections after burn:
Streptococcus, Pseudomonas, Proteus, methicillin-resistant Staphylococcus aureus (MRSA),Enterobacter, Enterococcuscause diabetic wound burn, wound cellulitis [1]. Piperacillin sodium, tazobactam sodium, sulbactam sodium, ampicillin sodium are used as antibiotics in this regard [1]. Moreover, nosocomial infections including sepsis, bacteremia, pneumonia, burn wound infections, urinary tract infections occur in both non-diabetic as well as diabetic patients, and infections may be caused by S. aureus, Pseudomonas, Klebsiella, Enterococcus along with Enterobacter.
Shockingly, the patients suffering from diabetes are infected by Proteus, Acinetobacter, MRSA as well as Candida whereas E. coli, Streptococcus, Hemophilus influenza, Candida were considered as major culprits [1]. As well, the burnt diabetic patients may have cardiac as well as hypertensive comorbidities [1]. It was reported that 1 million patients with burn injury were found in the United States [8]. Shockingly, 60,000-80,000 people get admitted to hospitals and 5,000 patients die per year [8]. Advanced critical care and early excision, as well as grafting increased survival rates of patients in the burn centers [7]. Additionally, rapid treatment related to pulmonary injury, proper early resuscitation can improve the health of burned patients [6].
Injuries by burn are potential problems across the world even if there are advanced protocols for the prevention as well as safety of burn care [9]. Rapid as well as expert care is recommended for improving the health of burn injured patients [9]. Although modern therapies provide a warranty of burn injury treatments, the clinical practice may help the survival of patients [9]. Advanced measures in not only burn as well as critical care that include excision as well as grafting, fast resuscitation, as well as improvements in microbial therapy played a crucial role in reducing morbidity as well as mortality [10]. In contrast to this, death occurs [10]. Patients may die due to sepsis, injuries, and failure of many organs [10].
When a person suffers from a burn injury, sepsis occurs which is a major cause of death in which multiple drug-resistant bacteria are involved [10]. Modified strategies are recommended to increase the survival of patients. Burn injury leads to damage to protein and muscle catabolism, dysfunction of the heart, insulin resistance as well as considerable retardation in growth creating problems in proper development [11,12]. As well, patients suffer from supraphysiologic metabolic rates, accelerated levels of cytokines responsible for inflammation, failure of multi-organ system, and increased acute phase proteins [12]. Failure in attenuation of hypermetabolic response may lead to unrecoverable damage and even death [10].
The updated research in pharmacological, as well as non-pharmacological modulations of responses after burning improved not only morbidity but also mortality [13]. Unluckily, the victim of severe burns may survive but death takes place still [10]. Trauma by burn results into not only physical but also physiologic derangements [10]. Many deaths by burn may be prevented with better management of the airway along with appropriate resuscitative attempts [10].
The studies are required to know the proteomic as well as genomic changes that arise after burn in the affected individuals for identification of increased risk of having the probability of getting recalcitrant persons in relation with treatment modalities for multi-organ failure, sepsis along with constant respiratory failure [10]. There are various reasons for deaths of burn patients who are more than 65 years of age viz. related inhalation injury as well as earlier existing cardiopulmonary diseases [14].
Moreover, the deaths of burn patients who are aged can be occurred by earlier resuscitation of fluid, earlier excision of deep burn wounds as well as grafting, treatment or prevention of diverse complications which are life-threatening along with nutritional supplementation [14]. The syndrome in which many organs get failed after the burn incidence in the first 24 to 48 hours is responsible for major complications [15]. Unfortunately, the syndrome in which multiple organs get failed leads to incomplete fluid resuscitation [16]. The advanced studies in the resuscitation of burn shock have reduced deaths after injury within forty-eight hours [15].
Shockingly, infections are major causes of deaths in the patients after receiving enough control on the burn shock at the initial stage [15]. Infection of the bloodstream, pneumonia, and infection to the wound of burn are more common complications of patients [15] along with species of Candida as well as filamentous fungi, for instance, Aspergillus species that are responsible for the colonization of burn wound [18,19].
Acinetobacter calcoaceticus-baumannii (multiple drug resistant) is a regular reason for infections found in patients [15]. Bacteremia caused by K. pneumoniae can predict mortality [17]. The local microflora causes infection after burn with rapid colonization [18,20,21,22]. After burn injury, skin microbes such as Staphylococcus aureus as well as Streptococcus pyogenes that reside in skin appendages at deep, make the colonies in the wound within 24-48 hours [18,20]. Also, endogenous bacteria viz. Escherichia coli, Klebsiella pneumoniae, Pseudomonas aeruginosa make their colonies in the wound within 48-72 hours [18,20].
Multidrug-resistant pathogens including K. pneumoniae (produces beta-lactamase which is extended-spectrum) and complex of Acinetobacter calcoaceticus-baumannii is the problem that is going on [15]. Filamentous fungi are the causes of invasive diseases [23,26], for example, Aspergillus sp. and Fusarium sp. as well as individuals of Mucorales [28]. There are case reports of invasive wound infection due to a variety of dematiaceous fungi such as Curvularia sp. [22].
Unluckily, fungal infections prove laborious to precisely identify as distinguishing colonization from infection is challenging. A recent retrospective review found that a positive culture of mold, such as Aspergillus, increased the odds ratio of death nearly 12-fold. The most frequently isolated organism but had the lowest associated mortality was Candida [4]. Viral infection of burn wounds is rarely reported but does occur. The most regular culprits are herpes simplex virus (HSV) and varicella-zoster virus (VZV) from the herpes virus family.
- Treatment:
Palliative care service can provide an advantage to some patients suffering from burn injuries. Treatment varies according to degree of burn (table 1) [2]. There are different treatments to treat burn patients (figure 1).
4.1 Skin grafting:
The utmost swift and productive procedure for closure of excised full-thickness burns is skin grafting [33]. It is the type of graft surgery that involves skin transplantation. Skin grafting is the quality treatment for full-thickness skin loss, generally experienced in patients with critical burns. The earliest known report of skin grafting is in the Ebers Papyrus, an ancient Egyptian medical papyrus dating to 1500 BC. In India, skin grafting became very developed where reconstruction of noses and lips were done using pedicled flaps from the cheek or forehead and grafts containing skin and subcutaneous fat from the buttocks [35].
Sealing of wounds and conducting fast rehabilitation practices of the patient are the most constructive ways to enhance the function of the wounded people. One of the most widely used flaps is the superficial temporal fascia flap for the mending of burns and other wounds in the plastic surgery field. It is mainly used in maxillofacial surgery because of the acceptable features of this flap which include tenacity, elasticity, and extensibility. The fusing of the superficial temporal fascia free flap with thin split-skin grafting represents a satisfying strategy. It is very much suitable for the mending of deep injuries in the posterior talocrural area in critical burns patients [36].
The Nile tilapia is a fish from the species tilapia (Oreochromis niloticus). In Brazil, the Nile tilapia skin is available and in previous studies, it is demonstrated that it gives satisfactory results when used as a xenograft in the treatment of experimental burns in an animal model. Noninfectious microflora and morphological structure having similarities with human skin are eye-catching features of tilapia skin. Bruno Almeida Costa et al. [34] concluded that with the help of tilapia skin as xenograft, 3 year-old patient who was suffering from the superficial partial thickness burn was operated (figure 2). Tilapia skin represents good attachment to the burned area. It also showed a lack of toxicity and antigenicity. It promotes the formation of epithelium on the burn wound [34].
4.2. Phage therapy:
A crucial public health issue is antibiotic resistance and the antibiotics are running out of storage. Bacteriophages (phages) may provide an advanced means of infection treatment, which can be used with antibiotic treatment in combined or alternated ways and may amplify our abilities to successfully treat bacterial infections. Bacteriophages are the most copious and omnipresent organisms on Earth and are the natural predators of bacteria. Phages are the viruses that infect and can lyse bacteria.
Figure 2: The Nile tilapia skin used as xenograft for skin grafting in burn patient [34].
Despite the antibiotic susceptibility of S. aureus or P. aeruginosa, these strains among others get infected by phages [29]. Phages are naturally safe in humans because they are appealingly specific in aiming and infecting bacterial cells. These infect bacteria to the species and frequently the strain level [31]. In the early 1921 in Tbilisi, Georgia, and Poland, phage therapy that was also known as bacteriophage therapy was utilized. In the 1930s and 1940s, it was extensively used around the world; especially in Eastern European countries and in the former Soviet Union.
In a particular Medline citation search from 1966-1996, for the treatment of a vast range of pathogens in adults as well as children, the Soviet and Polish people delivered a mixture of bacteriophages topically, systematically, and orally. Proteus, Escherichia coli, Staphylococcus, Streptococcus,Klebsiella,Pseudomonas, Shigella, and Salmonella spps were treated. 80-90% was success rate accompanied by occasional allergic and reversible gastrointestinal side effects [30]. Burned mice were saved from infection caused by P.aeruginosa and Klebsiella pneumonia with the help of phages. In 1990, 30 patients suffering from burn injuries were treated using dressings that are phage saturated in just 5-17 days [29].
Constant systematic and well-timed applications are required for antibiotic theory and in comparison, to this; phages keep working so long on their prey. In this case, the population of bacteria sensitive to phages has been abolished because these capture their host, rise in number, breakdown the bacterial cell and come out, attack other cells and the cycle continues until its resistance has developed by the host [30].
A case report narrates the fruitful decolonization of Pseudomonas aeruginosa from the burn area using topical phage potentiating subsequent skin grafting 3-days later. The targeting topical phages were applied via impregnation of filter paper discs (103 pfu) once to the burned surface. The discs were observed and raised concentrations of phages were recorded by authors indicating effective killing of bacteria which involves phages. Subsequently, the application of phage to the total burn surface results in negative results for bacterial culture and enhanced successful skin transplantation [31].
4.3. Fluid resuscitation:
Fluid resuscitation is fluid replacement. It is used to replenish body fluids. Hypovolaemic, cardiogenic and distributive shock happens due to burning injuries. Elevated capillary permeability and fluid shifts are the reasons for the primary depletion of the intravascular volume. The ground step of severe burn management is proper management of fluids. Burns involving greater than 15 to 20% total body surface area (TBSA) will result in hypovolaemic shock without preliminary and effective treatment [32]. Fast and effectual intravascular volume replenishment is crucial for the mitigation of burn shock.
Late or insufficient fluid replacement results in hypovolemia, tissue hypoperfusion, shock, and multiple organ failure [4]. Besides the local lesion, the burn encourages the discharge of inflammatory mediators that bring out an extreme systemic inflammatory response and results in the increase in vascular permeability in both the healthy and the affected tissue [37]. Resuscitation of severe major burns is a demanding task to the burn care providers especially in the first 24 hours from the time of burns.
It is one of the important predictors of survival of burn patients. Various resuscitation formulae are accessible at the request of the burn care provider. Despite many important advances in the fluid management field, smooth resuscitation is not ensured by any method [38]. The Parkland formula is accepted worldwide and it the consensus formula that is used currently [32].
Baxter and Shires in 1968 gave the Parkland formula. Consequently, the little progress has been made in the field of fluid therapy for burn resuscitation, despite advances in hemodynamic monitoring, the establishment of the ‘goal-directed therapy’ concept, and the development of new colloid and crystalloid solutions. Initial resuscitation is based on crystalloids. Colloids seem unsuitable during the first few hours. These are not suitable because of the high capillary permeability of burn patient. The electrolytic balance in large replacement is protected by Ringer’s acetate, and the crystalloids are the first choice for initial fluid replacement in patients suffering from burn injuries. Severe burn resuscitation should ideally be performed with thermodilution methods according to goal-directed therapy [37].
4.4. Microrobots:
Self-propelled micro-robots are developed by fusing motile bacteria with micro synthetic structures. The advancement of technology for the fabrication of these bacteria-based robots is a first stepping stone towards the understanding of functional minute and self-governing moving robots [41]. The most common type of tumor treatment is chemotherapy and is an efficacious standard therapy against actively multiplying tumor cells. However, other types of rapidly growing, healthy normal cells, such as blood and hair cells get damaged by chemotherapy. It induces different adverse reactions and side effects. Further, chemotherapy can be the resistance to therapeutic response in the slowly cell proliferating hypoxic region by deficient angiogenesis.
The continuous, specified delivery of ideal quantities of drugs to target cells is one of the most important challenges in chemotherapy. Many research groups have examined the progression of a drug delivery system (DDS) by using biocompatible and biodegradable materials, which can administer the drug release from microstructures to reduce side effects which will help to overcome the challenge [40]. Lack of tumor selectivity, multidrug resistance, and non-specific toxicity are major drawbacks of conventional anti-cancer agents [39].
A new approach for the construction of a bacteria-based microrobot and check the tumor aiming feature of a bacteria-based microrobot was proposed by a group of scientists. They called this microbial robot ‘‘bacteriobot’’. A microbial robot was developed using high-motility attenuated bacteria and a microstructure. These bacteria help the microbial robot to head in direction of tumors and at the same time, they play the role of microactuator, therapeutic agent, and microsensor.
Bacteria act as microsensor to sense the presence of tumor and microactuator is responsible for movement and the microstructure acts as a therapeutic molecule. High amounts of drugs are carried in microstructure for treating the tumor. To treat incurable diseases like cancer, a brand-new drug delivery system with the different useful features of microorganisms, which are called as bacteriobots can be used. A new anti-tumor therapy is represented by microbial robots which are created by the fusion of biotechnology and robot technology [40].
Sunghoon cho et al. [39] proposed a method using cross junction microfluidic channels for the production of biologically accepted polyethylene glycol microbeads. Hydrophilicity is not the reason behind the attachment between bacteria and the surface of polyethylene glycol microbeads. The Poly-L-lysine (PLL) was used to modify PEG microbead’s selective surface, which enhanced the attenuated Salmonella typhimurium adhesion using the submerging property of PEG microbeads on agarose gel: the bacteria could thus be attached to the PLL-coated surface region of the PEG microbeads. In comparison with PEG microbeads not coated with the poly-L-lysine and microbeads completely coated with poly-L-lysine, PEG microbeads which are selectively coated with poly-L-lysine showed higher motility [39].
A well-built conjugation system that is based on streptavidin/biotin between bacteria and microstructures was suggested and utilized for the assembly of the bacteria-based microrobot. Additionally, the motility and targeting properties of microrobot were assessed using new chemotactic microfluidic channels and syngeneic mouse tumor models, in vitro and in vivo respectively.
Attenuated S. typhimurium expresses green fluorescent protein or bacterial luciferases. The bacteria were firmly attached to the microstructure by making use of the high-affinity interlinkage between biotin and streptavidin. In this case, bacteria were set up to display biotin in the outer membrane proteins (omps), which are thoroughly distributed on the surface of the bacterial cell.
Microstructures consisting of rhodamine-containing fluorescent PS carboxylated microbeads that were covalently fused to streptavidin-conjugated tandem fluorochrome composed of peridinin chlorophyll protein, which was further labeled by Cy5.5 (PerCP-Cy5.5) were linked with bacteria (figure 3)[40].
- Conclusion:
Treatments are given to first-degree and second-degree patients are giving satisfactory results but third-degree burn patients need intensive care and more critical treatment. To deal with sensitive burnt areas these treatments are not suitable. Here, we propose robotics as a suitable way of dealing with the delicate environment like third-degree burnt areas. Bacteria-based microrobots referred to as “bacteriobots” are used in cancer therapy as a drug delivery system. Bacteriobots act as microsensors, microactuators, and therapeutic agents in therapy.
Chemotactic movement and tumor-specific targeting ability of bacteriobots were confirmed in experiments. These properties can be used to treat dainty burnt areas. The drug delivery system of bacteriobots can be used to combat many bacterial infections in burn patients. The use of microrobots for the treatment of third-degree burn patients is a promising approach in the field of medical science.