Cellular Environment 2023 PDF

Summary

This presentation covers intracellular and extracellular fluids, including plasma and interstitial fluid. It discusses the alterations of fluid movements, osmosis, diffusion, and active transport. The information is intended for a professional audience, likely paramedics or other healthcare professionals, and is relevant to understanding body fluid dynamics.

Full Transcript

By Steve Casarez
RN, MICN, Paramedic
Update 2023
▪ Needs a functioning system to distribute
nutrients to the right place so it can carry out
its duties and functions.
 Intracellular (ICF) Fluid inside the cell
 Extracellular (ECF) Fluid outside the cell. There are two types:
1. Intravascular Fluid in arteries and veins carrying plasma, blood
products, and nutrients.
2. Interstitial Fluid or 3rd Space commonly seen as Edema
 Both ICF and ECF should have the same concentration or (Osmolarity).
 Permeable Membranes are:
▪ A delicate membrane that separates the two and allows fluid to
move in and out.
Extracellular Fluid
Intravascular
Interstitial
Intracellular Fluid

Note: Elderly patients' total body% of water drops too around
45-40% estimated TOTAL
The body moves fluid and nutrients in three
ways, and diseases and trauma can alter these
normal processes:
1. Osmosis
2. Diffusion
3. Mediated Transport
Insensible Fluid Loss (approx. 1,600 mL in 24 hours)
 From the skin
 Respiratory tract
 Urine output
 Sweating (approx. 100mL)
 Fecal loss (approx. 200mL)

Replacement comes from three primary sources
 Oral intake of fluids like water, commonly called hydration
 Metabolic water production from oxidation of food
 And with medical interventions of intravenous (IV) fluids
  Both are Solute Concentrations
 Is the number of active particles in a kilogram or liter of water
 Salt (Sodium) is the most abundant in ECF
 NA+ = 135 – 145 mEq/ dL
 Serum Osmolality
 Serum Osmo 280 – 295 mEq/ dL
FUN FACT:

Why do we call 0.9% sodium chloride
Normal Saline?

It is because of Osmolality!
0.9% sodium chloride is 308
Circulating blood is 275-299

https://www.ncbi.nlm.nih.gov/pmc/articles/PMC4794509/
1st is Osmosis
Defines the movement of water between ICF /
ECF that moves from Hypo to Hyper solutes
 Isotonic
▪ Equal balance concentration between ICF / ECF
 Hypertonic
▪ Higher concentration in ECF than in ICF
▪ Example: seawater
 Hypotonic
▪ Lower concentration in ICF than in ECF
▪ Example: distilled water
▪ Water moves from lower solute concentration to a higher
solute concentration
Equal balance concentration between ICF / ECF
 Blood has approx. 290-300 mOsm/L
 Equal solutes
 Common Isotonic IV Fluids
 0.9% Sodium Chloride
 Lactated Ringers
 D5W (5% dextrose in water) as free water ONLY

 Treatment Goals
 Hydration
 Increase Preload in Shock
 Hypoglycemia
 Hypertonic
 More solutes outside the cell
 Pulls fluid from IC to EC
 Common Hypertonic IV fluids
 D5NS
 D5LR
 D5 0.45%
 10% Dextrose
 3.0% Sodium Chloride
 TX Goals
 Pull excess fluid off to treat edema
 Used in TBI when herniation is present
Hypotonic
 More solutes in the cell
 Pulls fluid from EC to IC
 Common Hypotonic IV fluids
▪ D5W (5% dextrose in water) when dextrose is metabolized
▪ 0.25% sodium chloride
▪ 0.45% sodium chloride
▪ 0.225% sodium chloride

 TX Goals
▪ Aggressive Cellular hydration
▪ Pulls fluid from the vascular
system into the ICF
2nd is the Diffusion of Solids and Gases
 Spreading of molecules from a higher concentration to a lower
concentration
 Bodies’ way to keep equilibrium by keeping the concentration gradient
equal as possible
 Example of locations: Lungs and Kidneys
Diffusion of Gases
Diffusion of Solids
▪ Measures Expired Carbon Dioxide (Co2)
▪ Co2 is a byproduct of cellular respiration
▪ eTCO2 can assess patient status for:
▪ Metabolic Status
▪ Adequate Circulation
▪ Adequate Ventilation
▪ Perfusion emergencies
▪ All four are independent of one another depending on your goals and
outcomes for the patient
▪ THIS IS NOT USED FOR CHECKING OR MONITORING OXYGENATION
 Moving solutes against a concentration gradient
 From lower to higher concentration
1st Active Transport 2nd Facilitated Diffusion
Active transport
 Faster then diffusion
 Uses A GREAT DEAL of energy
 Example:
▪Sodium/ Potassium pump
▪ATP production
Facilitated Diffusion
 Uses a helper protein to move against the concentration
 Example: Insulin helps glucose into the cell
 Arterial Venous
High Pressure side Low Pressure side
A-line Pressures Cuff Blood Pressure

Hydrostatic pressure Hydrostatic pressure
35mmHg 17mmHg
Interstitial space

Oncotic pressure Oncotic pressure
25mmHg 25mmHg

Membrane Capillary bed
1. This movement is related to pressures
▪ Hydrostatic pressures
▪ Pressure to the walls of the vessels
▪ Forces fluids out of capillaries
▪ Osmotic pressures Hemodynamics
▪ Pulls fluid into the capillaries
2. Intravascular
▪ has high pressures
3. Interstitial
▪ has lower pressures
 Pressure exerted by a fluid because of its weight
 Weight will be based on the pressure exerted by the pump and by
the diameter of the pipe onto the capillary
 Arterial Hydrostatic pressures 40 mmhg
 Venous Hydrostatic pressures 10 mmhg
 Example of this is Blood Pressures
Mean Arterial Pressure (MAP) normal at 60-120 mmHg.
MAP measures end-organ perfusion pressures.
 Dependent on Cardiac Output (CO=HRxSV)
 Dependent on Right Ventricular Filling
 Dependent on Systemic Vascular Resistance (SVR) or the
radius of the blood vessels.

Dilation Constriction

Normal Tone
 Dilation Constriction

The Patient :
= Low Blood Pressure The Patient:
= Low Cardiac Output = High Blood Pressure
= Low Mean Arterial Pressures = High Cardiac Output
= Low Systemic Vascular Resistance = High Mean Arterial Pressures
Causes: = High Systemic Vascular Resistance
= Loss of vagal tone Causes:
= Distributive Shock = Early stages of Shock
= Septic Shock = Compensated Shock
= Decompensated Shock
= Overdose of blood pressure medications
 What are some other injuries and diseases
that may change blood pressure or
hydrostatic pressures?
 Pressure difference between a semipermeable
membrane, through which it cannot penetrate
 Pressures related to the concentration of colloids in the
fluid
 Example: capillary pressures or Cap refill time
 Edema may be a result of these changes
 Tonicity
 Is the minimum pressure needed to prevent inward
flow across a semipermeable membrane
 Alteration in this permeability increases the space for
exchange:
▪ Sepsis
▪ Bacterial Infections
▪ Shock
▪ Pneumonia
Edema
 Collection of water in the interstitial space
 3rd spacing
 Causes
▪ Increased Capillary hydrostatic pressure
▪ Decreased Plasma Oncotic pressure (intravascular)
▪ Increased capillary membrane permeability
▪ Histamine Response
▪ Damage to cells make them “leaky”
▪ Lymphatic obstruction
Increased hydrostatic pressure
 Occlusion or Diminish of Venous flow
 Retention of salt and water
 Common Causes
▪ CHF
▪ End Stage Renal Disease
Decreased Plasma Osmotic Pressures
 Reduced plasma proteins
 Not enough pressure to pull fluid through the
interstitial space
 Common Causes
▪ Liver disease
▪ Resuscitation
▪ Hemorrhagic
Increased capillary membrane permeability
 Inflammation and Immune response
 Histamine response
 “Leaky” cells
 Common Causes
▪ Trauma
▪ Burns
▪ Crushing injuries
Lymphatic obstruction
 Lymphedema
 Blocked or impaired lymphatic system
 Common Causes
▪ Mastectomy
Localized edema can be deadly
 Cerebral edema
 Has no space to move the fluids
 Result is increase in ICP and herniation
 EMS S/S
▪ Acute decrease in GCS
▪ Cushing's Triad
▪ Unequal or Nonreactive
pupils
Localized edema can be deadly
Compartment Syndrome
 Increase edema in a compartment
 Decrease blood flow distal to the injury
 Sensory damage
 EMS S/S the 5 P’s
▪ Pain out of proportion to findings
▪ Paresthesia (pins and needles)
▪ Paralysis
▪ Pallor (pale)
▪ Pressure
Dependant Edema
 Pitting edema
 Is measurable
 Common areas
▪ Feet / lower extremities
▪ Presacral edema
 High
pressure

Hydrostatic
Cell Oncotic

Low
pressure