Systemic Resonse to Burns: Difference between revisions

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<div class="editorbox"> '''Original Editor '''- [[User:Carin Hunter|Carin Hunter]] based on the course by [https://members.physio-pedia.com/instructor/carin-hunter// Carin Hunter]<br>'''Top Contributors''' - {{Special:Contributors/{{FULLPAGENAME}}}}</div>


== Overview of the Skin ==
[[File:Skin layers.gif|Figure 1. The layers of the skin|thumb]]
Our [[skin]], which is part of the [[Integumentary System|integumentary system]], is a cutaneous membrane that covers the surface of the body. It is the largest organ system in the human body in terms of weight and surface area. However, it is often overlooked and underappreciated for the role it plays in overall health.<ref name=":5">Palmer, D. Skin Anatomy, Physiology, and Healing Course. Physiotherapy Wound Care Programme. Plus, 2022.</ref> 


Pathophysiology of Burns
=== Layers of the Skin ===
 
The skin has two principal layers: the epidermis and the dermis. The hypodermis is considered an extension or third layer of the skin by some sources, but not by others.<ref name=":5" /> Table 1 provides a summary of the main features of each layer. These layers are also illustrated in Figure 1.
A burns injury depending on the severity of the injury can result in both local and debilitating systemic effects on all other organs and systems distant to the burn area.
 
Cutaneous membrane which  
 
covers the surface of the  
 
body
 
∙ Largest organ of the body in  
 
terms of weight and surface  
 
area
 
∙ Epidermis
 
o Superficial layer  
 
o Composed of epithelial tissue o Avascular
 
Figure 2. Layers of the skin (MD 2009)
 
o Deepest layer (Stratum Basale) contains ‘Stem cells’
 
▪ Capable of regeneration
 
▪ New skin cannot regenerate if injury destroys a large portion of this  layer
 
∙ Dermis
 
o Deeper, thicker layer
 
o Connective tissue
 
o Contains blood vessels, nerves, glands and hair follicles
 
∙ Subcutaneous layer
 
o Areolar and adipose tissue
 
o Storage for fat/ insulation
 
o Contains large blood vessels
 
o Attaches to underlying facia
 
▪ Connective tissue overlying muscle and bone
 
An in depth knowledge of pathophysiology of burns, and their effects both locally and  systemically is necessary to ensure effective management of a patient with a burn injury.
 
== 1.61 Normal Healing ==
∙ Use knowledge of tissue healing to decide when rest is required and when exercise,  stretching and strengthening will be beneficial to the patient.  
 
∙ Timescales are variable according to the size of the burn and surgical intervention.  Clinical reasoning is essential when applying the following in practice.  
{| class="wikitable"
{| class="wikitable"
|STAGE
|+Table 1. Layers of the skin.
|TIMESCALE
|PROCESS
|SIGNS AND  
 
SYMPTOMS
|TREATMENT
|-
|-
|Inflammation
|'''Epidermis'''
|0-5 days
|Superficial layer<ref name=":3">McCann C, Watson A, Barnes D. [https://www.bjaed.org/article/S2058-5349(21)00129-3/fulltext Major burns: Part 1. Epidemiology, pathophysiology and initial management.] BJA education. 2022 Mar 1;22(3):94-103.</ref>
|Vasoconstriction  
|Composed of five layers, provides a waterproof barrier and contributes to skin tone
 
|Composed of epithelial tissue
followed by  
|Avascular
 
vasodilatation and influx  of inflammatory  
 
mediators and WBCs.  Increased capillary  
 
permeability. Exudate  leaks into tissues. Pus  may be produced.
|Redness, Heat, Swelling,  Pain
|Reduce heat and  oedema and pain.  
 
Prevent infection and disruption of  wound.  
 
(immobilisation,  positioning,  
 
splinting)
|-
|-
|Proliferation  (fibroplasia)
|'''Dermis'''
|Begins day 3- 5. Lasts 2-6  
|Deeper, thicker layer<ref name=":3" />
 
|Composed of two layers
weeks.
|Contains blood vessels, nerves, glands and hair follicles
|Fibroblasts synthesize  collagen. Laid down  
|Highly vascularised
 
haphazardly.  
 
Angiogenesis continues.
|Moist red raised tissue  over wound
|Early: positioning  and  
 
immobilisation
 
Later: gentle  
 
stress (splinting,  exercise)
 
Reduce oedema and prevent  
 
contracture
|-
|-
|Remodelling  (maturation)
|'''Hypodermis'''
|Begins week  4-6.
|Deepest layer<ref name=":3" />
 
|Storage for fat/ insulation
Lasts up to 2  years.
Attaches to underlying facia
|Synthesis of collagen  balanced by degradation.  Organisation of collagen  fibres along lines of  
|Made up of loose connective tissue and adipose tissue
 
|Contains large blood vessels
stress.
|Wound closure
 
Scar red and raised  
 
progresses to flat pale and  pliable. Scar tissue  
 
tightens.
|Optimise function Splinting
 
Positioning
 
Exercise
 
Stretching
 
Strengthening.
|}
|}
Table 2 Tissue healing process following burn injury (Glassey 2004)
For more information on the skin, please see [[Skin Anatomy, Physiology, and Healing Process]]. This page provides a detailed discussion of the role of the skin, its layers and normal tissue healing.
 
== Systemic Response ==
In severe burn injury, >30% TBSA complex reaction occurs both from the burn area and in the area distant to the burn. Cytokines, chemokines and other inflammatory mediators are released in excess resulting in extensive inflammatory reactions within a few hours of injury. The initial response depending on the size of the burn injury is similar to the inflammation that is triggered after tissue destruction such as trauma or major surgery. Different factors contribute to the magnitude of the host response, they include: burn severity (percentage TBSA and burn depth), burn cause, inhalation injury, exposure to toxins, other traumatic injuries, and patient-related factors such as age, pre-existing chronic medical conditions, drug or alcohol intoxication, and timing of presentation to medical aid. This inflammatory response leads to rapid oedema formation which is caused by increased microvascular permeability, increased hydrostatic microvascular pressure, vasodilation, and increased extravascular osmotic activity. These reactions are due to the direct heat effect on the microvasculature and to the chemical mediators of inflammation. Vasodilation and increased venous permeability at the early stage of the injury are caused by the release of histamine. Also, prostaglandin is released by damage to the cell membranes which causes the release of oxygen-free radicals released from polymorphonuclear leucocytes which activate the enzymes catalyzing the hydrolysis of prostaglandin precursor. These hemodynamic changes lead to continuous loss of fluid from the blood circulation causing increased haematocrit levels and a rapid fall in plasma volume, leading to a decrease in cardiac output and hypoperfusion on the cellular level. [[Burn Shock|Burn shock]] occurs if fluid loss is not adequately restored.
 
Besides [[Burn Shock|burn shock]], the burn injury can result in other types of injury which include [[Inhalation Injury|inhalation injury]]. Inhalation injury is caused by heat or inhalation of smoke or chemical products of combustion leading to various degrees of damage. Usually, it is present in conjunction with the burn and can range from a minor injury to a severe injury. Inhalation injury can be divided into three types: systemic toxicity due to products of combustion (carbon monoxide (CO) and cyanide poisoning); upper airway thermal injury; and lower (bronchi and distal) airway chemical injury. Patients can sustain all of these in a closed-space fire. CO poisoning, more accurately categorised as a systemic intoxication, is easily diagnosed from the serum carboxyhaemoglobin level determined as part of the arterial blood gas measurement at hospital admission.
 
In addition to the effects above, a severe burn injury has an effect on different organs and systems in the body. The effects include:
 
Effect on the Cardiovascular System
 
The initial response to a severe burn injury is characterised by hypovolemia and reduced venous return. This concomitantly leads to a decrease in cardiac output, increased heart rate, and peripheral resistance. In addition to the cardiac dysfunction, pulmonary resistance increases causing an increase in right and left-ventricular work-load.
 
Effect on the Respiratory System
 
Following smoke inhalation, inflammatory mediators are released in the lungs leading to bronchoconstriction and adult respiratory distress syndrome.
 
Effect on the Renal System
 
The renal system is affected following alterations in the cardiovascular system. Renal blood flow and glomerular filtration rate are reduced secondary to hypovolemia, diminished cardiac output, and the effects of angiotensin, vasopressin and aldosterone. These alterations are usually translated in the form of oliguria as an early sign of renal compromise. Failure to promptly and adequately manage these cases may lead to acute tubular necrosis, renal failure, and mortality.
 
Effect on the Liver
 
There is substantial depletion of the hepatic proteins, alterations in serum levels of triglycerides and free fatty acids are highlighted, both of which are significantly increased secondary to a decrease in fat transporter proteins rendering the liver susceptible for fatty infiltration and hepatomegaly with resultant increased risk of sepsis and burn mortality.
 
Effects on Gastrointestinal System/Metabolism
 
The basal metabolic rate increases up to three times its original rate. This coupled with splanchnic hypoperfusion, necessitates early and aggressive enteral feeding to decrease catabolism and maintain gut integrity. It causes mucosal atrophy, reduced absorptive capacity, and increased surface permeability.
 
Effect on the Endocrine System
 
The stress hormones i.e. catecholamine, glucagon and cortisol among other hormones are actively involved at the onset of burns injuries. These hormones display an exponential increase in their levels; sometimes reaching 10 fold their normal values. The significance of such an upsurge resides in its influence on the cardiovascular system and the resultant fluid shifts that follow these changes. The stress hormones are thereby considered as the initiators of the hypermetabolic-catabolic and proteolytic-response.
 
1.52 Systemic effects
 
Once the burn covers more than 30% of TBSA, the injury has a systemic effect due to  
 
∙ Molecular structural alterations  
 
o Release of toxic metabolites  
 
o Release of antigen and immunomodulatory agents
 
▪ Histamine, Serotonin, Bradykinin, Nitric oxide, etc.
 
Causes systemic shock, cardiovascular, respiratory and renal failure, immunosuppression and hypermetabolism. (Evers et al 2010)
 
Cardiovascular Changes
 
∙ Myocardial depression
 
o Myocardial contractility decreased
 
∙ Oedema formation
 
o Capillary permeability is increased
 
o leads to loss of intravascular proteins and fluids to the interstitial compartment ∙ Hypovolemia
 
o Secondary to oedema and rapid fluid loss from surface of wound
 
∙ Peripheral and splanchnic vasoconstriction occurs
 
o May cause renal failure
 
These changes may lead to systemic hypotension and end organ hypoperfusion. (Evers et al,  2010)
 
Respiratory Changes
 
Inflammatory mediators cause bronchoconstriction and pulmonary oedema
 
∙ severely burnt adults acute respiratory distress syndrome (ARDS) can occur ∙ Exacerbated in the case of inhalation injury (Evers et al 2010)
 
Metabolic Changes
 
Hypermetabolism begins approximately five days post burn
 
o Metabolic state is initially suppressed by the effects of acute shock
 
7
 
o Can persist for up to two years post injury  
 
Inflammatory, hormonal and cytokine milieu cause
 
∙ Increased body temperature
 
∙ Increased oxygen and glucose consumption
 
∙ Increased CO2 and minute ventilation
 
∙ Increased heart rate for up to 2 years post burn  
 
(Jeschke et al 2007; Grisbrook et al 2012a; Hurt et al 2000)
 
This hyper metabolic state leads to energy substrate release from protein and fat stores  Protein catabolism
 
∙ Loss of lean muscle mass and wasting
 
∙ Potentially fatal if structure and function of organs are compromised (Jeschke et al  2007; Hurt et al 2000)
 
In adults with burns of 25% TBSA, metabolic rate ranges from 118-210% that of predicted  values. At 40% TBSA, the resting metabolic rate in a thermoneutral environment is  
 
o 180% at acute admission
 
o 150% at full healing  
 
o 140% post 6 months
 
o 120% at 9 months
 
o 110% at 10 months (Jeschke et al 2007; Herndon and Tomkins 2004) Gastrointestinal Changes
 
∙ Impaired gastrointestinal motility
 
∙ Impaired digestion and absorption
 
∙ Increased intragastric pH
 
∙ Feeding difficulties exacerbate effects of hyper metabolism (Evers et al 2010) Immunological Changes: (Hettiaratchy and Dziewulski 2004)
 
∙ Immune deficiency occurs despite the activation of the immune system. High risk of  infection, particularly while wounds are open.
 
== 1.62 Complications of Healing in Burn Patients ==
1.621 Oedema
 
Oedema may increase post burn for up to 36 hours  
 
∙ Increased vascular permeability which occurs during the inflammatory response  ∙ Exacerbated if the burn is severe enough to warrant fluid resuscitation (Weinzweig  and Weinzweig 2004; Kamolz et al 2009).
 
Post severe burn
 
∙ The resulting scar (eschar) is inflexible
 
∙ Does not allow skin expansion  
 
∙ Tissue beneath continues to expand as  
 
oedema increases  
 
∙ Rapid increase in compartment pressure
 
∙ May result in circulatory compromise/nerve  Damage/ necrosis of distal muscles.  
 
Figure 5. Hand escharotomy (Weinzweig  and Weinzweig 2004)
 
∙ Severe cases require a surgical procedure known as an escharotomy o Splits the scar and allows for the expansion of the tissues beneath, relieving  pressure (Kamolz et al 2009,Weinzweig and Weinzweig 2004)..
 
10
 
Recognising Vascular Insufficiency: Where oedema and compartment syndrome is causing  vascular insufficiency, the following symptoms may be present
 
∙ Pain
 
∙ Loss of sensation
 
∙ Pale white skin on the dorsum of the hand/ distal to eschar
 
∙ Loss of peripheral pulses (may also be caused by hypovolaemia or insufficient fluid  resuscitation) (Kamolz et al, 2009)
 
As compartment syndrome requires immediate attention, all health care professionals must  remain vigilant.
 
Oedema and the Hand:  
 
Oedema in the hand results in the position of intrinsic minus (Kamolz et al 2009)  ∙ Wrist flexion
 
∙ MCP extension
 
∙ PIP/DIP flexion
 
MCP joint extension primary position assumed
 
∙ Joint contact areas minimised  
 
∙ Joint capsules and ligaments lax
 
∙ Therefore, in this position, the joint accommodates the maximum amount of intra articular fluid
 
Figure 6 Intrinsic Minus hand  position (American Society for  Surgery of the hand 2013)
 
∙ Increases tension in finger/wrist flexors , relaxes extensors
 
Therefore, PIP/DIP/ Wrist flexion follow (Weinzweig and Weinzweig 2004) ∙ Joint predisposed to contracture
 
∙ May have significant functional implications
 
∙ Even after wound healing appears complete, sub-acute and chronic oedema may be  caused by scar maturation and contraction: therefore, oedema management is a long  term concern.
 
11
 
1.622 Hypertrophic scarring
 
Hypertrophic scars are a common complication of burn injuries. A healing wound requires a  balance of several opposing reactions
 
∙ Degradation of necrotic tissue/proliferation of new cells
 
∙ Building up/ breaking down of collagen
 
∙ Creating/controlling of new blood supplies (Linares et al 1996).  
 
Disequilibrium of any of these processes may result in abnormal scarring. There is a high risk  of a scar becoming hypertrophic if early wound closure is not achieved. Estimates for optimal  closure time vary from 10 days (ANZBA 2007) to 21 days (Procter 2010). Hypertrophic  scarring is accompanied by:
 
∙ Exaggerated angiogenesis with high blood flow
 
∙ Increased deposition of collagen
 
∙ High rates of contraction
 
∙ Pruritus (Itch)
 
∙ Dryness
 
∙ Lack of pliability. (Procter 2010).  
 
∙ The orientation of new collagen bundles remain  
 
haphazard  
 
∙ haphazard structure persists for several months post  
 
Figure 7. Hypertrophic scar on  dorsum of hand (Procter 2010)
 
Injury.  
 
∙ Some degree of chronic inflammation may also persist.
 
Identifying Hypertrophic Scarring
 
(Linares et al 1996).
 
∙ Shapes and sizes depend on location on the body and nature of injury ∙ Edges are raised and end abruptly
 
∙ Initially may be red or pink in colour
 
o Blanch over time, as the scar matures


o Never returns to original colour/texture
== Healing Process ==
[[File:Stages of Healing.jpg|thumb|Figure 2. Stages of wound healing.|450x450px]]
When treating a burns patient, it is crucial to understand tissue healing. Your knowledge of tissue healing and the information gathered from your assessment will influence clinical decisions, including when to rest, exercise, stretch and strengthen during the recovery period. 


∙ May exceed the limits of the original injury (Keloid scars).  (Linares et al 1996; Procter 2010)
There are four stages of healing (see Figure 2). Each stage can be impacted by factors such as the size of the burn, surgical intervention and other complications. Clinical reasoning is essential when applying these principles in practice.


12
=== Haemostasis ===


== 1.7 Burn Associated Pain ==
* The process of wound closure by clotting
“The quality of outcome must be worth the pain of survival”
* This process starts when [[Blood Physiology|blood]] leaks out of the body, and the blood vessels constrict to restrict blood flow
* Platelets quickly aggregate and adhere to the sub-endothelium surface
* Within 60 seconds, the first fibrin strands begin to adhere
* As the fibrin mesh begins to form, blood is transformed from a liquid to a gel through pro-coagulants and the release of prothrombin
* The formation of a thrombus / clot traps the platelets and blood cells in the wound area
* Treatment at this stage focuses on:
** reducing heat, oedema and pain
** preventing infection and disruption of the wound
* Useful interventions include:
** immobilisation
** positioning
** splinting<ref name=":13">Hale A, O’Donovan R, Diskin S, McEvoy S, Keohane C, Gormley G. Impairment and Disability Short Course. Physiotherapy in Burns, Plastics and Reconstructive Surgery, 2013.</ref>


~Prof FM Wood, James Laing Memorial Essay, 1995
=== Inflammation ===


∙ 84% of major burn patients suffer “severe or excruciating pain”
* Occurs 0-5 days post-injury
* Vasoconstriction is followed by vasodilatation and an influx of inflammatory mediators and white blood cells
* There is an increased capillary permeability and exudate leaks into the tissues - pus may also be produced
* Signs include:
** redness
** heat
** swelling
** pain
* Treatment focuses on:
** reducing heat, oedema and pain
** preventing infection and disruption of  the wound
* Useful interventions include:
** immobilisation
** positioning
** splinting<ref name=":13" />


∙ 100% suffer daily pain
=== '''Proliferation (Fibroplasia)''' ===


∙ 92% are woken at night with pain (ANZBA 2007)
* Begins days 3-5 and lasts 2-6 weeks
* Fibroblasts synthesise collagen (laid down haphazardly at this stage) and angiogenesis continues
* Signs include moist red raised tissue over the wound
* Treatment focuses on:
** reducing oedema
** preventing contractures
* Early interventions include:
** positioning
** immobilisation
* Later interventions include gentle stress with splinting and exercise<ref name=":13" />


== 1.71 Types of Pain in Burns: (Summer et al 2007; Richardson and Mustard 2009) ==
=== Remodelling (Maturation) ===
Procedural pain: (Primary mechanical hyperalgesia): intense burning and stinging that  continues to a lesser degree, but may be accompanied by intermittent sharp pain for minutes  or hours following dressing changes or physiotherapy/occupational therapy. Throbbing,  excruciating pain may be associated with positioning of burned extremities (i.e. positioned  below the level of the heart); this is thought to be related to pressure associated with  inflamed, oedematous tissue. Procedural pain is the most intense and most undertreated pain associated with burn injuries.


Procedural pain and associated pain anxiety: research indicates pain-anxiety increases over  time in burn injured patients. Strong correlations have been established between pain,  physiological distress and physical and psychological outcomes in both adults and children.  
* Begins weeks 4-6 and lasts up to 2 years
* Collagen synthesis is balanced by degradation
* Collagen fibres are organised along the lines of stress
* Signs include:
** wound closure
** red and raised scar, progressing to a flat, pale and pliable scar
** scar tissue tightens
* Treatment focuses on:
** '''optimising function'''
** splinting
** positioning
** exercise
** stretching
** strengthening<ref name=":13" />


Background pain: patients with high anxiety have increased levels of background pain.  There is a wide variability in the pain intensity following injury. Background pain is  characterised by prolonged duration, relatively constant mild-moderate intensity pain. The  pain has been described as continuous burning or throbbing, present even when the patient is  relatively immobile. This pain is best treated with regularly scheduled analgesics.
For more information on the healing process, please see:


Breakthrough pain: transient worsening of pain frequently associated with movement.  Patients also report spontaneous pain that may be related to changing mechanisms of pain,  over time or inadequate analgesia. The pain can be described as stinging, shooting, pricking  or pounding. Pain following movement can be associated with primary mechanical  hyperalgesia, but most care providers for those with burns consider pain with movement to be  breakthrough pain. Breakthrough pain can be much worse following periods of immobility,  particularly if skin over joints is affected.
* [[Skin Anatomy, Physiology, and Healing Process#Normal Tissue Healing|Normal tissue healing]]
* [[Wound Healing]]
* [[Soft Tissue Healing]]


13
== Systemic Response to Burns ==
Different factors contribute to the magnitude of the host response to a burn wound, including:
* burn severity (percentage total body surface area (TBSA) of the burn and burn depth)<ref>Kumar R, Keshamma E, Kumari B, Kumar A, Kumar V, Janjua D, Billah AM. [https://jrasb.com/index.php/jrasb/article/view/60 Burn Injury Management, Pathophysiology and Its Future Prospectives]. Journal for Research in Applied Sciences and Biotechnology. 2022 Oct 31;1(4):78-89.</ref>
* burn cause
* inhalation injury
* exposure to toxins
* other traumatic injuries
* patient-related factors
** age
** pre-existing chronic medical conditions
** drug or alcohol intoxication
** timing of presentation to care


For optimal analgesia, it is recommended that patients are assessed for each type of pain  separately and repeatedly throughout the course of the recovery.  
=== Pathophysiology of Burn Wounds ===
In severe burn injuries (i.e. >30% TBSA), complex reactions occur both at the burn and away from the burn. Excess cytokines, chemokines, histamines, prostaglandins and other inflammatory and vasoactive mediators are released.<ref>Schaefer TJ, Nunez Lopez O. Burn Resuscitation and Management. [Updated 2023 Jan 23]. In: StatPearls [Internet]. Treasure Island (FL): StatPearls Publishing; 2023 Jan-. Available from: https://www.ncbi.nlm.nih.gov/books/NBK430795/</ref> This results in '''extensive inflammatory reactions''' within a few hours of the burn injury. As well as the inflammatory response, burn injuries, particularly severe burns, also cause an immune response, metabolic changes and distributive shock.<ref name=":9">Jeschke MG, van Baar ME, Choudhry MA, Chung KK, Gibran NS, Logsetty S. [https://www.nature.com/articles/s41572-020-0145-5 Burn injury]. Nat Rev Dis Primers. 2020 Feb 13;6(1):11.</ref> Depending on the size of the burn injury, a patient's initial response is similar to the response that occurs after "other inflammatory conditions triggered by tissue destruction such as trauma or major surgery".<ref>Jeschke MG. Pathophysiology of burn injury. Springer International Publishing; 2021.</ref>


Pre-disposition:
The pathophysiology of burn wounds can be summarised as follows.


Genetics
The inflammatory response leads to rapid oedema formation. This is caused by:<ref name=":6">Arturson G. Pathophysiology of the burn wound. Ann Chir Gynaecol.1980;69(5):178-90.</ref>


Psychosis
* increased microvascular permeability
* increased hydrostatic microvascular pressure
* vasodilation
* increased extravascular osmotic activity


Substance abuse
These reactions are caused by the direct effect of heat on the microvasculature and the chemical mediators of inflammation:<ref name=":6" />


Drugs factors: Timing
* the release of histamine tends to cause early vasodilation and increased venous permeability
* prostaglandin is rapidly formed because of damage to the cell membranes
** this damage is caused in part by oxygen-free radicals that are released from polymorphonuclear leucocytes
** this activates the enzymes that catalyse the hydrolysis of prostaglandin precursor
* prostaglandins inhibit the release of noradrenaline (also known as norepinephrine) - this may have a modulatory impact on the adrenergic nervous system, which is activated by thermal injuries
* there are further changes in the structure of the blood-lymph barrier, such as an increase in the number of vacuoles and more open endothelial intercellular junctions
* there are changes in the interstitial tissue


Tailoring
* there is a continuous loss of fluid from the blood circulation, resulting in increased haematocrit levels and a fall in plasma volume - this leads to decreased cardiac output and hypoperfusion at the cellular level
* burn shock occurs if fluid loss is not adequately restored<ref name=":0">Noreen S, Maqbool I, Ijaz S. [https://www.researchgate.net/profile/Sobia-Noreen-2/publication/353018959_Skin_Burns_pathophysiology_types_and_Therapeutic_Approaches/links/623b6f1b42cbca4e75c52727/Skin-Burns-pathophysiology-types-and-Therapeutic-Approaches.pdf Skin Burns: Pathophysiology, types and Therapeutic Approaches.] Pathophysiology. 2010;1(3).</ref> (to learn more about the complexities of burn shock, please see: [[Burn Shock]])


Side effects
=== Impact of Burn Injuries on Body Systems ===


Burn wound: Dressing type Dressing tension Infection
==== 1. Effect on the Cardiovascular System ====
The initial cardiovascular response to the catecholamine-mediated surge from a severe burn injury is hypovolaemia (decrease in blood volume) with myocardial depression and reduced venous return.<ref name=":7">Panchal A, Casadonte J. [https://onlinelibrary.wiley.com/doi/full/10.1002/ccr3.2667 Burn-induced myocardial depression in a pediatric patient leading to fulminant cardiogenic shock and multiorgan failure requiring extracorporeal life support]. Clin Case Rep. 2020 Feb 22;8(4):602-605. </ref> This leads to decreased cardiac output, increased heart rate, and peripheral resistance. In addition to the cardiac dysfunction, pulmonary resistance increases, which causes an increase in right- and left-ventricular workload.<ref name=":1">Abu-Sittah GS, Sarhane KA, Dibo SA, Ibrahim A. Cardiovascular dysfunction in burns: a review of the literature. Ann Burns Fire Disasters. 2012;25(1):26-37.</ref><ref>Williams FN, Herndon DN, Suman OE, Lee JO, Norbury WB, Branski LK, Mlcak RP, Jeschke MG. Changes in cardiac physiology after severe burn injury. J Burn Care Res. 2011;32(2):269-74.Abu-Sittah GS, Sarhane KA, Dibo SA, Ibrahim A. Cardiovascular dysfunction in burns: a review of the literature. Ann Burns Fire Disasters. 2012;25(1):26-37.</ref>


Movement
This then progresses to a "hyperdynamic-hypermetabolic phase with increased cardiac output."<ref name=":7" /> This second phase is characterised by tachycardia, increased myocardial oxygen consumption, and increased cardiac output. It is important to note that cardiac stress continues for at least two years after a burn injury.<ref>Williams FN, Herndon DN, Suman OE, Lee JO, Norbury WB, Branski LK, Mlcak RP, Jeschke MG. [https://academic.oup.com/jbcr/article-abstract/32/2/269/4598542 Changes in cardiac physiology after severe burn injury.] Journal of burn care & research. 2011 Mar 1;32(2):269-74.</ref>


Donor sites
Compromised cardiac function can:<ref name=":1" />
* cause hypoperfusion of organs
* affect peripheral microcirculation
* lead to an extension of the burn zone
* result in decreased resistance to bacterial infections at the wound
'''Burn Shock:''' "Burns exceeding 30% of total body surface area (TBSA) result in considerable hypovolemia coupled with formation and release of inflammatory mediators with subsequent systemic effect, namely a distinctive cardiovascular dysfunction known as burn shock."<ref name=":8">Kaddoura I, Abu-Sittah G, Ibrahim A, Karamanoukian R, Papazian N. [https://www.ncbi.nlm.nih.gov/pmc/articles/PMC5627559/ Burn injury: review of pathophysiology and therapeutic modalities in major burns]. Ann Burns Fire Disasters. 2017 Jun 30;30(2):95-102.</ref> Burn shock is a complex process that affects the circulatory and microcirculatory systems,<ref name=":8" /> with "rapid and extensive fluid transfer in burn and non-burn tissues".<ref name=":2">Chi Y, Liu X, Chai J. [https://www.ncbi.nlm.nih.gov/pmc/articles/PMC8106041/ A narrative review of changes in microvascular permeability after burn]. Ann Transl Med. 2021 Apr;9(8):719.</ref> <blockquote>"Burn shock is a unique combination of hypovolemic and distributive shock, accompanied by cardiogenic shock."<ref>Ishikawa T. Maeda H. Systemic response to trauma. In Siegel JA, Saukko PJ, Houck MM editors. Encyclopedia of Forensic Sciences (Second Edition),


Personality type Context: Expectations
Academic Press, 2013. p47-53.</ref></blockquote>
* In severe burn wounds, there is an increase in local and systemic vascular permeability, which causes intravascular fluid to leak out
* Ultimately, this causes a gradual decrease in circulation volume, increased systemic vascular resistance, decreased cardiac output and peripheral tissue oedema<ref name=":2" />


Culture
* Management of burn shock requires fluid resuscitation and close monitoring to ensure there are adequate (though not excessive) IV fluids<ref name=":7" />
'''** Hypovolaemic shock:''' occurs when there is a loss of approximately one-fifth or more of the normal amount of blood in the body.


Past experience
==== 2. Effect on the Respiratory System ====
* '''Heat injury to the upper airway:'''<ref name=":4">Galeiras R. [https://www.ncbi.nlm.nih.gov/pmc/articles/PMC8794442/ Smoke inhalation injury: a narrative review. Mediastinum.] 2021;5.</ref>
** heat injury to airway structures causes extensive swelling of the tongue, epiglottis, and aryepiglottic folds, resulting in obstruction
* '''Chemical injury to the lower airway:'''<ref name=":4" />
** inflammatory mediators are released in the lungs, leading to bronchoconstriction, pulmonary oedema and [[Acute Respiratory Distress Syndrome (ARDS)|acute respiratory distress syndrome (ARDS)]]
* '''Systemic toxicity:'''<ref name=":4" />
** inhalation of chemicals, cytotoxic liquids, fumes, mist and gases can cause systemic toxic changes
** smoke can combine with these toxins, resulting in increased mortality because of tissue hypoxia, metabolic acidosis, decreased oxygen supply to the brain and decreased metabolism<ref>Physiopedia. [[Inhalation Injury]].</ref>


Environment
For more information, please read [[Inhalation Injury]].


Rapport with staff
==== 3. Effect on the Renal System ====
Early kidney injury is due to:


Cognition:
* low blood volume
* inflammatory mediators
* increased release of protein in the bloodstream
* extensive tissue damage
* medications that are toxic to the kidneys


Attention
The renal system is affected by changes in the cardiovascular system caused by a burn injury. Blood flow to the kidneys is decreased due to hypovolaemia, reduced cardiac output and the effects of angiotensin, vasopressin and aldosterone. This marks the beginning of kidney failure. Appropriate fluid resuscitation can help prevent these issues. The rehabilitation team should always keep an eye out for decreased urine output (oliguria) as this is an early sign of renal compromise.<ref>Physiopedia. [[Burns Overview]].</ref>


Distraction
==== 4. Effect on the Endocrine System ====
The endocrine system is a network of glands in the body, which secrete hormones. The endocrine system can be affected after severe burn injuries.<ref>D'Asta F, Cianferotti L, Bhandari S, Sprini D, Rini GB, Brandi ML. The endocrine response to severe burn trauma. Expert Rev Endocrinol Metab. 2014 Jan;9(1):45-59.</ref>


Self-belief
Trauma can affect the HPA Axis (hypothalamic-pituitary-adrenal axis), which controls the '''interaction between the hypothalamus, pituitary gland, and adrenal glands'''. The hypothalamus and pituitary gland are located just above the brainstem, while the adrenal glands are found on top of the kidneys.


reappraisal
Burn injuries commonly cause patients to have an elevated sympathetic drive. This is due to an increase in the release of '''cortisol and glucagon'''. These hormones affect the metabolic system (see below). Prolonged excess cortisol (hypercortisolaemia) is associated with increased infection rates in burn patients and lengthened duration of severe infection.<ref>Norbury WB, Herndon DN, Branski LK, Chinkes DL, Jeschke MG. [https://www.ncbi.nlm.nih.gov/pmc/articles/PMC2291486/ Urinary cortisol and catecholamine excretion after burn injury in children]. J Clin Endocrinol Metab. 2008 Apr;93(4):1270-5. </ref>


Mood:  
Severe burn injuries can alter a patient's urine output. Glucose readings also need to be monitored closely, as misdiagnosis can have life-threatening consequences.<ref name=":12">D’Asta F, Cianferotti L, Bhandari S, Sprini D, Rini GB, Brandi ML. [https://www.tandfonline.com/doi/abs/10.1586/17446651.2014.868773#:~:text=The%20endocrine%20system%20is%20frequently,perturbed%20within%20a%20few%20days The endocrine response to severe burn trauma.] Expert review of endocrinology & metabolism. 2014 Jan 1;9(1):45-59.</ref>


Depression
Hypoparathyroidism, following a severe burn, can also affect the metabolism of bone and minerals. This also needs to be rectified by supplementing with calcium, magnesium, and phosphate.<ref name=":12" />


Anxiety
==== 5. Effects on the Metabolic System ====
In the initial period, for around 72-96 hours post-burn,<ref name=":9" /> individuals with severe burn wounds enter a '''hypometabolic''' state (known as the ebb phase). This may be caused by various intracellular processes. It results in:<ref>Clark A, Imran J, Madni T, Wolf SE. [https://burnstrauma.biomedcentral.com/articles/10.1186/s41038-017-0076-x Nutrition and metabolism in burn patients]. Burns & trauma. 2017 Dec 1;5.</ref><ref name=":9" />


Catastrophising
* decreased metabolic rate
* reduced intravascular volume
* poor perfusion of the tissues
* low cardiac output


Figure 8. Factors influencing the patient’s perception of pain from a burn wound. (Richardson and Mustard 2009)
'''Hypermetabolism''' (an increase, often of up to 100-150%, in the metabolic rate) begins approximately five days post-burn in patients with severe burns.<ref>Herndon DN, Barrow RE, Rutan TC, Minifee PA, Jahoor FA, Wolfe RR. [https://www.ncbi.nlm.nih.gov/pmc/articles/PMC1493755/ Effect of propranolol administration on hemodynamic and metabolic responses of burned pediatric patients.] Annals of surgery. 1988 Oct;208(4):484.</ref> It can result in organ catabolism, greater incidence of organ failure, infections and death.<ref name=":9" /> It occurs in response to "a series of events triggered by a significant and persistent rise in secretions of cateholamine, cortisol, glucagon and dopamine."<ref name=":8" /> Effects can be seen for up to three years post-burn.<ref name=":9" />


14
Hypermetabolism can cause:<ref name=":9" /><ref>Grisbrook TL, Elliott CM, Edgar DW, Wallman KE, Wood FM, Reid SL. [https://www.sciencedirect.com/science/article/abs/pii/S030541791200294X Burn-injured adults with long term functional impairments demonstrate the same response to resistance training as uninjured controls]. Burns. 2013 Jun 1;39(4):680-6.</ref><ref>Jeschke MG, Mlcak RP, Finnerty CC, Norbury WB, Gauglitz GG, Kulp GA, Herndon DN. [https://ccforum.biomedcentral.com/articles/10.1186/cc6102 Burn size determines the inflammatory and hypermetabolic response.] Critical care. 2007 Aug;11(4):1-1.</ref>


1.72 Pain Mechanisms
* increased resting energy expenditure
* increased body temperature
* increased oxygen and glucose consumption
* increased CO2 and minute ventilation
* increased heart rate
* muscle wasting, etc


(Richardson and Mustard 2009)
==== 6. Immunological Changes ====
Burn injuries have a significant impact on the immune system. For example, in burn injuries, the actions of neutrophils, natural killer cells and macrophages are impaired, and there are reductions in the numbers of T lymphocytes. For a detailed discussion of immune system changes, please see: [https://academic.oup.com/burnstrauma/article/doi/10.1093/burnst/tkaa047/6128653?login=false The pathogenesis and diagnosis of sepsis post burn injury].<ref name=":11">Zhang P, Zou B, Liou YC, Huang C. [https://academic.oup.com/burnstrauma/article/doi/10.1093/burnst/tkaa047/6128653?login=false The pathogenesis and diagnosis of sepsis post burn injury]. Burns Trauma. 2021 Feb 4;9:tkaa047. </ref>


The pain mechanisms associated with the inflammation process post burn are:  
Ultimately, "the compromised alterations in innate and adaptive immune responses result in enhanced susceptibility to infection, sepsis and multiple organ failure."<ref name=":11" />


∙ Primary hyperalgesia
==== 7. Oedema formation ====
Oedema formation is a characteristic response to burn injuries. It has two phases:<ref name=":8" />


∙ Secondary hyperalgesia
* in the first hour after the burn, there is an increase in water content of the affected tissue
* in the second phase, there is a gradual increase in "fluid flux of both burned and intact skin and soft tissues 12-24 hours post-burn"<ref name=":8" />


∙ Neuropathic pain
Rapid oedema formation is caused by:<ref name=":10">Wurzer P, Culnan D, Cancio LC, Kramer GC.


∙ Chronic pain/Central Sensitisation
8 - Pathophysiology of Burn Shock and Burn Edema. In: Herndon DN editor. Total burn care (Fifth Edition). Elsevier, 2018. p66-76.e3.</ref>


Other factors to consider in pain are:
* strongly negative interstitial fluid pressure developing
* greater microvascular permeability
* loss of glycocalyx
* endothelial activation


1.73 Pain intensity: As the inflammation recedes, the quality of the pain may change. The  reporting of pain intensity varies widely and is reported highest in areas of upper/mid-dermal  skin loss, such as areas of skin donation and decreases with wound closure. Infection may  result in increased pain again following revival of the inflammatory process. Growth of new  tissue is associated with paraesthesia and local discomfort. The healed areas show enhanced  mechanical hyperalgesia following subsequent injury.  
Fluid resuscitation (in terms of type, timing, total amount) will affect these shifts in fluid.<ref name=":10" />


1.74 Anxiety and pain experience: result in increased pain perception. The pain experience  will alter according with the burn treatment. Surgery/debridement/excision of the burn will  alter the depth of the burn injury. Covering the burn with grafts or synthetic dressings  typically reduce pain, with the harvest site often being more painful than the burn injury  itself. Poor pain management during therapeutic procedures is associated with poor  compliance with treatment and post-traumatic stress disorder. It then increases anxiety and  worsens the pain experience in subsequent treatment.
== References ==
[[Category:Physioplus Content]]
[[Category:Course Pages]]
[[Category:Course Pages]]
[[Category:Burns]]
[[Category:Burns]]
<references />
[[Category:SRSHS Course Pages]]

Latest revision as of 09:54, 16 January 2024

Original Editor - Carin Hunter based on the course by Carin Hunter
Top Contributors - Carin Hunter, Jess Bell and Kim Jackson

Overview of the Skin[edit | edit source]

Figure 1. The layers of the skin

Our skin, which is part of the integumentary system, is a cutaneous membrane that covers the surface of the body. It is the largest organ system in the human body in terms of weight and surface area. However, it is often overlooked and underappreciated for the role it plays in overall health.[1]

Layers of the Skin[edit | edit source]

The skin has two principal layers: the epidermis and the dermis. The hypodermis is considered an extension or third layer of the skin by some sources, but not by others.[1] Table 1 provides a summary of the main features of each layer. These layers are also illustrated in Figure 1.

Table 1. Layers of the skin.
Epidermis Superficial layer[2] Composed of five layers, provides a waterproof barrier and contributes to skin tone Composed of epithelial tissue Avascular
Dermis Deeper, thicker layer[2] Composed of two layers Contains blood vessels, nerves, glands and hair follicles Highly vascularised
Hypodermis Deepest layer[2] Storage for fat/ insulation

Attaches to underlying facia

Made up of loose connective tissue and adipose tissue Contains large blood vessels

For more information on the skin, please see Skin Anatomy, Physiology, and Healing Process. This page provides a detailed discussion of the role of the skin, its layers and normal tissue healing.

Healing Process[edit | edit source]

Figure 2. Stages of wound healing.

When treating a burns patient, it is crucial to understand tissue healing. Your knowledge of tissue healing and the information gathered from your assessment will influence clinical decisions, including when to rest, exercise, stretch and strengthen during the recovery period.

There are four stages of healing (see Figure 2). Each stage can be impacted by factors such as the size of the burn, surgical intervention and other complications. Clinical reasoning is essential when applying these principles in practice.

Haemostasis[edit | edit source]

  • The process of wound closure by clotting
  • This process starts when blood leaks out of the body, and the blood vessels constrict to restrict blood flow
  • Platelets quickly aggregate and adhere to the sub-endothelium surface
  • Within 60 seconds, the first fibrin strands begin to adhere
  • As the fibrin mesh begins to form, blood is transformed from a liquid to a gel through pro-coagulants and the release of prothrombin
  • The formation of a thrombus / clot traps the platelets and blood cells in the wound area
  • Treatment at this stage focuses on:
    • reducing heat, oedema and pain
    • preventing infection and disruption of the wound
  • Useful interventions include:
    • immobilisation
    • positioning
    • splinting[3]

Inflammation[edit | edit source]

  • Occurs 0-5 days post-injury
  • Vasoconstriction is followed by vasodilatation and an influx of inflammatory mediators and white blood cells
  • There is an increased capillary permeability and exudate leaks into the tissues - pus may also be produced
  • Signs include:
    • redness
    • heat
    • swelling
    • pain
  • Treatment focuses on:
    • reducing heat, oedema and pain
    • preventing infection and disruption of  the wound
  • Useful interventions include:
    • immobilisation
    • positioning
    • splinting[3]

Proliferation (Fibroplasia)[edit | edit source]

  • Begins days 3-5 and lasts 2-6 weeks
  • Fibroblasts synthesise collagen (laid down haphazardly at this stage) and angiogenesis continues
  • Signs include moist red raised tissue over the wound
  • Treatment focuses on:
    • reducing oedema
    • preventing contractures
  • Early interventions include:
    • positioning
    • immobilisation
  • Later interventions include gentle stress with splinting and exercise[3]

Remodelling (Maturation)[edit | edit source]

  • Begins weeks 4-6 and lasts up to 2 years
  • Collagen synthesis is balanced by degradation
  • Collagen fibres are organised along the lines of stress
  • Signs include:
    • wound closure
    • red and raised scar, progressing to a flat, pale and pliable scar
    • scar tissue tightens
  • Treatment focuses on:
    • optimising function
    • splinting
    • positioning
    • exercise
    • stretching
    • strengthening[3]

For more information on the healing process, please see:

Systemic Response to Burns[edit | edit source]

Different factors contribute to the magnitude of the host response to a burn wound, including:

  • burn severity (percentage total body surface area (TBSA) of the burn and burn depth)[4]
  • burn cause
  • inhalation injury
  • exposure to toxins
  • other traumatic injuries
  • patient-related factors
    • age
    • pre-existing chronic medical conditions
    • drug or alcohol intoxication
    • timing of presentation to care

Pathophysiology of Burn Wounds[edit | edit source]

In severe burn injuries (i.e. >30% TBSA), complex reactions occur both at the burn and away from the burn. Excess cytokines, chemokines, histamines, prostaglandins and other inflammatory and vasoactive mediators are released.[5] This results in extensive inflammatory reactions within a few hours of the burn injury. As well as the inflammatory response, burn injuries, particularly severe burns, also cause an immune response, metabolic changes and distributive shock.[6] Depending on the size of the burn injury, a patient's initial response is similar to the response that occurs after "other inflammatory conditions triggered by tissue destruction such as trauma or major surgery".[7]

The pathophysiology of burn wounds can be summarised as follows.

The inflammatory response leads to rapid oedema formation. This is caused by:[8]

  • increased microvascular permeability
  • increased hydrostatic microvascular pressure
  • vasodilation
  • increased extravascular osmotic activity

These reactions are caused by the direct effect of heat on the microvasculature and the chemical mediators of inflammation:[8]

  • the release of histamine tends to cause early vasodilation and increased venous permeability
  • prostaglandin is rapidly formed because of damage to the cell membranes
    • this damage is caused in part by oxygen-free radicals that are released from polymorphonuclear leucocytes
    • this activates the enzymes that catalyse the hydrolysis of prostaglandin precursor
  • prostaglandins inhibit the release of noradrenaline (also known as norepinephrine) - this may have a modulatory impact on the adrenergic nervous system, which is activated by thermal injuries
  • there are further changes in the structure of the blood-lymph barrier, such as an increase in the number of vacuoles and more open endothelial intercellular junctions
  • there are changes in the interstitial tissue
  • there is a continuous loss of fluid from the blood circulation, resulting in increased haematocrit levels and a fall in plasma volume - this leads to decreased cardiac output and hypoperfusion at the cellular level
  • burn shock occurs if fluid loss is not adequately restored[9] (to learn more about the complexities of burn shock, please see: Burn Shock)

Impact of Burn Injuries on Body Systems[edit | edit source]

1. Effect on the Cardiovascular System[edit | edit source]

The initial cardiovascular response to the catecholamine-mediated surge from a severe burn injury is hypovolaemia (decrease in blood volume) with myocardial depression and reduced venous return.[10] This leads to decreased cardiac output, increased heart rate, and peripheral resistance. In addition to the cardiac dysfunction, pulmonary resistance increases, which causes an increase in right- and left-ventricular workload.[11][12]

This then progresses to a "hyperdynamic-hypermetabolic phase with increased cardiac output."[10] This second phase is characterised by tachycardia, increased myocardial oxygen consumption, and increased cardiac output. It is important to note that cardiac stress continues for at least two years after a burn injury.[13]

Compromised cardiac function can:[11]

  • cause hypoperfusion of organs
  • affect peripheral microcirculation
  • lead to an extension of the burn zone
  • result in decreased resistance to bacterial infections at the wound

Burn Shock: "Burns exceeding 30% of total body surface area (TBSA) result in considerable hypovolemia coupled with formation and release of inflammatory mediators with subsequent systemic effect, namely a distinctive cardiovascular dysfunction known as burn shock."[14] Burn shock is a complex process that affects the circulatory and microcirculatory systems,[14] with "rapid and extensive fluid transfer in burn and non-burn tissues".[15]

"Burn shock is a unique combination of hypovolemic and distributive shock, accompanied by cardiogenic shock."[16]

  • In severe burn wounds, there is an increase in local and systemic vascular permeability, which causes intravascular fluid to leak out
  • Ultimately, this causes a gradual decrease in circulation volume, increased systemic vascular resistance, decreased cardiac output and peripheral tissue oedema[15]
  • Management of burn shock requires fluid resuscitation and close monitoring to ensure there are adequate (though not excessive) IV fluids[10]

** Hypovolaemic shock: occurs when there is a loss of approximately one-fifth or more of the normal amount of blood in the body.

2. Effect on the Respiratory System[edit | edit source]

  • Heat injury to the upper airway:[17]
    • heat injury to airway structures causes extensive swelling of the tongue, epiglottis, and aryepiglottic folds, resulting in obstruction
  • Chemical injury to the lower airway:[17]
  • Systemic toxicity:[17]
    • inhalation of chemicals, cytotoxic liquids, fumes, mist and gases can cause systemic toxic changes
    • smoke can combine with these toxins, resulting in increased mortality because of tissue hypoxia, metabolic acidosis, decreased oxygen supply to the brain and decreased metabolism[18]

For more information, please read Inhalation Injury.

3. Effect on the Renal System[edit | edit source]

Early kidney injury is due to:

  • low blood volume
  • inflammatory mediators
  • increased release of protein in the bloodstream
  • extensive tissue damage
  • medications that are toxic to the kidneys

The renal system is affected by changes in the cardiovascular system caused by a burn injury. Blood flow to the kidneys is decreased due to hypovolaemia, reduced cardiac output and the effects of angiotensin, vasopressin and aldosterone. This marks the beginning of kidney failure. Appropriate fluid resuscitation can help prevent these issues. The rehabilitation team should always keep an eye out for decreased urine output (oliguria) as this is an early sign of renal compromise.[19]

4. Effect on the Endocrine System[edit | edit source]

The endocrine system is a network of glands in the body, which secrete hormones. The endocrine system can be affected after severe burn injuries.[20]

Trauma can affect the HPA Axis (hypothalamic-pituitary-adrenal axis), which controls the interaction between the hypothalamus, pituitary gland, and adrenal glands. The hypothalamus and pituitary gland are located just above the brainstem, while the adrenal glands are found on top of the kidneys.

Burn injuries commonly cause patients to have an elevated sympathetic drive. This is due to an increase in the release of cortisol and glucagon. These hormones affect the metabolic system (see below). Prolonged excess cortisol (hypercortisolaemia) is associated with increased infection rates in burn patients and lengthened duration of severe infection.[21]

Severe burn injuries can alter a patient's urine output. Glucose readings also need to be monitored closely, as misdiagnosis can have life-threatening consequences.[22]

Hypoparathyroidism, following a severe burn, can also affect the metabolism of bone and minerals. This also needs to be rectified by supplementing with calcium, magnesium, and phosphate.[22]

5. Effects on the Metabolic System[edit | edit source]

In the initial period, for around 72-96 hours post-burn,[6] individuals with severe burn wounds enter a hypometabolic state (known as the ebb phase). This may be caused by various intracellular processes. It results in:[23][6]

  • decreased metabolic rate
  • reduced intravascular volume
  • poor perfusion of the tissues
  • low cardiac output

Hypermetabolism (an increase, often of up to 100-150%, in the metabolic rate) begins approximately five days post-burn in patients with severe burns.[24] It can result in organ catabolism, greater incidence of organ failure, infections and death.[6] It occurs in response to "a series of events triggered by a significant and persistent rise in secretions of cateholamine, cortisol, glucagon and dopamine."[14] Effects can be seen for up to three years post-burn.[6]

Hypermetabolism can cause:[6][25][26]

  • increased resting energy expenditure
  • increased body temperature
  • increased oxygen and glucose consumption
  • increased CO2 and minute ventilation
  • increased heart rate
  • muscle wasting, etc

6. Immunological Changes[edit | edit source]

Burn injuries have a significant impact on the immune system. For example, in burn injuries, the actions of neutrophils, natural killer cells and macrophages are impaired, and there are reductions in the numbers of T lymphocytes. For a detailed discussion of immune system changes, please see: The pathogenesis and diagnosis of sepsis post burn injury.[27]

Ultimately, "the compromised alterations in innate and adaptive immune responses result in enhanced susceptibility to infection, sepsis and multiple organ failure."[27]

7. Oedema formation[edit | edit source]

Oedema formation is a characteristic response to burn injuries. It has two phases:[14]

  • in the first hour after the burn, there is an increase in water content of the affected tissue
  • in the second phase, there is a gradual increase in "fluid flux of both burned and intact skin and soft tissues 12-24 hours post-burn"[14]

Rapid oedema formation is caused by:[28]

  • strongly negative interstitial fluid pressure developing
  • greater microvascular permeability
  • loss of glycocalyx
  • endothelial activation

Fluid resuscitation (in terms of type, timing, total amount) will affect these shifts in fluid.[28]

References[edit | edit source]

  1. 1.0 1.1 Palmer, D. Skin Anatomy, Physiology, and Healing Course. Physiotherapy Wound Care Programme. Plus, 2022.
  2. 2.0 2.1 2.2 McCann C, Watson A, Barnes D. Major burns: Part 1. Epidemiology, pathophysiology and initial management. BJA education. 2022 Mar 1;22(3):94-103.
  3. 3.0 3.1 3.2 3.3 Hale A, O’Donovan R, Diskin S, McEvoy S, Keohane C, Gormley G. Impairment and Disability Short Course. Physiotherapy in Burns, Plastics and Reconstructive Surgery, 2013.
  4. Kumar R, Keshamma E, Kumari B, Kumar A, Kumar V, Janjua D, Billah AM. Burn Injury Management, Pathophysiology and Its Future Prospectives. Journal for Research in Applied Sciences and Biotechnology. 2022 Oct 31;1(4):78-89.
  5. Schaefer TJ, Nunez Lopez O. Burn Resuscitation and Management. [Updated 2023 Jan 23]. In: StatPearls [Internet]. Treasure Island (FL): StatPearls Publishing; 2023 Jan-. Available from: https://www.ncbi.nlm.nih.gov/books/NBK430795/
  6. 6.0 6.1 6.2 6.3 6.4 6.5 Jeschke MG, van Baar ME, Choudhry MA, Chung KK, Gibran NS, Logsetty S. Burn injury. Nat Rev Dis Primers. 2020 Feb 13;6(1):11.
  7. Jeschke MG. Pathophysiology of burn injury. Springer International Publishing; 2021.
  8. 8.0 8.1 Arturson G. Pathophysiology of the burn wound. Ann Chir Gynaecol.1980;69(5):178-90.
  9. Noreen S, Maqbool I, Ijaz S. Skin Burns: Pathophysiology, types and Therapeutic Approaches. Pathophysiology. 2010;1(3).
  10. 10.0 10.1 10.2 Panchal A, Casadonte J. Burn-induced myocardial depression in a pediatric patient leading to fulminant cardiogenic shock and multiorgan failure requiring extracorporeal life support. Clin Case Rep. 2020 Feb 22;8(4):602-605.
  11. 11.0 11.1 Abu-Sittah GS, Sarhane KA, Dibo SA, Ibrahim A. Cardiovascular dysfunction in burns: a review of the literature. Ann Burns Fire Disasters. 2012;25(1):26-37.
  12. Williams FN, Herndon DN, Suman OE, Lee JO, Norbury WB, Branski LK, Mlcak RP, Jeschke MG. Changes in cardiac physiology after severe burn injury. J Burn Care Res. 2011;32(2):269-74.Abu-Sittah GS, Sarhane KA, Dibo SA, Ibrahim A. Cardiovascular dysfunction in burns: a review of the literature. Ann Burns Fire Disasters. 2012;25(1):26-37.
  13. Williams FN, Herndon DN, Suman OE, Lee JO, Norbury WB, Branski LK, Mlcak RP, Jeschke MG. Changes in cardiac physiology after severe burn injury. Journal of burn care & research. 2011 Mar 1;32(2):269-74.
  14. 14.0 14.1 14.2 14.3 14.4 Kaddoura I, Abu-Sittah G, Ibrahim A, Karamanoukian R, Papazian N. Burn injury: review of pathophysiology and therapeutic modalities in major burns. Ann Burns Fire Disasters. 2017 Jun 30;30(2):95-102.
  15. 15.0 15.1 Chi Y, Liu X, Chai J. A narrative review of changes in microvascular permeability after burn. Ann Transl Med. 2021 Apr;9(8):719.
  16. Ishikawa T. Maeda H. Systemic response to trauma. In Siegel JA, Saukko PJ, Houck MM editors. Encyclopedia of Forensic Sciences (Second Edition), Academic Press, 2013. p47-53.
  17. 17.0 17.1 17.2 Galeiras R. Smoke inhalation injury: a narrative review. Mediastinum. 2021;5.
  18. Physiopedia. Inhalation Injury.
  19. Physiopedia. Burns Overview.
  20. D'Asta F, Cianferotti L, Bhandari S, Sprini D, Rini GB, Brandi ML. The endocrine response to severe burn trauma. Expert Rev Endocrinol Metab. 2014 Jan;9(1):45-59.
  21. Norbury WB, Herndon DN, Branski LK, Chinkes DL, Jeschke MG. Urinary cortisol and catecholamine excretion after burn injury in children. J Clin Endocrinol Metab. 2008 Apr;93(4):1270-5.
  22. 22.0 22.1 D’Asta F, Cianferotti L, Bhandari S, Sprini D, Rini GB, Brandi ML. The endocrine response to severe burn trauma. Expert review of endocrinology & metabolism. 2014 Jan 1;9(1):45-59.
  23. Clark A, Imran J, Madni T, Wolf SE. Nutrition and metabolism in burn patients. Burns & trauma. 2017 Dec 1;5.
  24. Herndon DN, Barrow RE, Rutan TC, Minifee PA, Jahoor FA, Wolfe RR. Effect of propranolol administration on hemodynamic and metabolic responses of burned pediatric patients. Annals of surgery. 1988 Oct;208(4):484.
  25. Grisbrook TL, Elliott CM, Edgar DW, Wallman KE, Wood FM, Reid SL. Burn-injured adults with long term functional impairments demonstrate the same response to resistance training as uninjured controls. Burns. 2013 Jun 1;39(4):680-6.
  26. Jeschke MG, Mlcak RP, Finnerty CC, Norbury WB, Gauglitz GG, Kulp GA, Herndon DN. Burn size determines the inflammatory and hypermetabolic response. Critical care. 2007 Aug;11(4):1-1.
  27. 27.0 27.1 Zhang P, Zou B, Liou YC, Huang C. The pathogenesis and diagnosis of sepsis post burn injury. Burns Trauma. 2021 Feb 4;9:tkaa047.
  28. 28.0 28.1 Wurzer P, Culnan D, Cancio LC, Kramer GC. 8 - Pathophysiology of Burn Shock and Burn Edema. In: Herndon DN editor. Total burn care (Fifth Edition). Elsevier, 2018. p66-76.e3.
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