Fluid management is a critical aspect of patient care, especially in the inpatient medical setting. What makes fluid management both challenging and interesting is that each patient demands careful consideration of their individual fluid needs. Unfortunately, it is impossible to apply a single, perfect formula universally to all patients. However, one general principle for all patient scenarios is to replace whatever fluid is being lost as accurately as possible. These fluid losses can differ depending on patients’ medical conditions and differ by both volume and composition. For example, a patient admitted to the hospital with severe burns will have much greater fluid losses than a relatively healthy patient who is allowed nothing by mouth and awaiting a procedure. A patient admitted for dehydration from severe diarrhea might require different fluid compositions than a patient admitted in hypovolemic shock from a brisk upper gastrointestinal (GI) bleed.

An important distinction in managing fluids is differentiating between maintenance fluids and fluid replacement. Maintenance fluids should address the basic physiologic needs of the patient including both sensible and insensible fluid losses. Sensible fluid losses refer to typical routes of excretion such as urination and defecation. Insensible losses refer to other routes of fluid loss such as in sweat and from the respiratory tract. Fluid replacement goes beyond the normal physiologic losses and includes such conditions as vomiting, diarrhea, or severe cutaneous burns. One must consider these 2 categories of fluid loss separately when devising a fluid management strategy for an individual patient.

Fluid management is an essential part for any patient admitted to the hospital. If possible, it is preferable that patients take fluids enterally since this is the natural route of fluid intake. However, many patients who are sick enough needing admission to the hospital might have a reason they cannot tolerate oral intake. Alternative routes of administration such as intravenous access can deliver fluids directly to the vascular system.

There are many ways to assess a patient’s volume status to determine their fluid needs. Often, one can determine the patient’s fluid status clinically based on a variety of physical exam findings and objective data from their vital signs. Laboratory markers are helpful as adjunctive data. The following is a list of findings which can be useful in determining whether a patient is fluid depleted or volume overloaded.[1]

Vital signs

• Weight: One of the most sensitive indicators of changes to the patient's volume status is their weight. Patient weight changes approximate a gold standard to determine fluid status. Unfortunately, due to differences in scales available to hospital staff, this can be a challenging target to measure. It is ideal to weigh a patient daily on the same scale to determine trends in his or her weight changes. One can see weight gain in states of fluid excess, and weight loss in states of fluid deficit. It is also helpful to look at patient records to see any recent outpatient visits before hospitalization which might provide an idea of a patient's normal baseline weight.
• Heart rate: Tachycardia can represent a compensatory physiologic response to maintain perfusion in the setting of hypovolemia. This can be an early finding in compensated hypovolemic shock. However, there are many other reasons for tachycardia such as pain, fever, and anxiety.
• Blood pressure: Falling blood pressure is an ominous finding in the setting of tachycardia indicating that the cardiovascular system can no longer compensate adequately for hypovolemia. Conversely, elevated blood pressures can be seen in hypervolemia.
• Orthostatic vital signs: A drop of at least 20 mm Hg systolic blood pressure or 10 mm Hg diastolic blood pressure within 2 to 5 minutes of quiet standing after 5 minutes of supine rest indicates orthostatic hypotension. Dehydrated or elderly patients who have lost sensitivity in their baroreceptors in their blood vessels might display these findings.
• Respiratory rate: Increased respiratory rate indicates a compensatory response to metabolic acidosis from lactic acidosis due to poor tissue perfusion. This is an early finding in hypovolemic shock.
• Urine output: Expect a minimum of 1.5 mL/kg per hour in children and greater than 1 mL/kg per hour in adults. Special situations such as administration of nephrotoxic medications such as acyclovir warrant higher thresholds for urine output to minimize renal toxicity.

Physical exam findings

• Capillary refill: Normally less than 2 seconds. Easy to test on fingertips and toes
• Fontanelle: Sunken fontanelle on the skull of an infant suggests hypovolemia
• Edema: Peripheral edema can be a sign of volume overload or third spacing of intravascular fluid      
• Tear production: Relevant in infants and children; Important to ask parents for their observations and evaluate the child while in the exam room
• Peripheral pulses: Check brachial and femoral pulses in infants; Check radial or dorsalis pedis pulses in older patients; Can see fast and thready pulses in dehydration states
• Skin turgor and eyeball appearance: Severe cases of dehydration might present with flaccid or tented skin; Eyeballs might also appear sunken back into orbital cavities
• Tactile temperature of skin: Classically find cool and clammy skin found in hypovolemic shock due to peripheral vasoconstriction causing hypoperfusion of skin especially at the extremities (i.e., hands or feet)
• Mucous membranes: Appreciate dry, sandpaper-like texture of the oral mucosa or tongue in states of dehydration
• Jugular vein appearance:  Appreciate a distended jugular vein in volume overload state; Can also be found in patients with congestive heart failure who are euvolemic but not pumping blood appropriately

Laboratory findings

• BUN/creatinine: Can be elevated secondary to prerenal acute kidney injury from decreased renal blood flow due to decreased intravascular volume
• Transaminases: Can see an elevation in AST or ALT due to hypoperfusion of hepatic tissue and subsequent tissue hypoxia causing hepatocyte injury, also known as “shock liver”
• Hemoconcentration: Can see elevated hematocrit due to a relative abundance of red blood cells relative to intravascular fluid volume

Intravenous (IV) fluid solutions

• 5% Dextrose in 0.9% Sodium Chloride (Normal Saline) +/- potassium additive
• 5% Dextrose in 0.45% Sodium Chloride (Half Normal Saline) +/- potassium additive
• Lactated Ringer's

Enteral tubes

• Nasogastric tube
• Orogastric tube
• Gastric tube
• Nasoduodenal tube
• Gastrojejunal tube

Enteral fluid solutions

• Commerical rehydration solutions
• WHO rehydration solution
• Infant feeds (breastmilk or formula)
• Commercially available sports drinks