Orthostatic hypotension is characterised by symptoms that occur after standing (from lying or sitting), particularly when this is done rapidly. Many report lightheadedness (a feeling that one might be about to faint), sometimes severe. Generalized weakness or tiredness may also occur. Some also report difficulty concentrating, blurred vision, tremulousness, vertigo, anxiety, palpitations (awareness of the heartbeat), feeling sweaty or clammy, and sometimes nausea. A person may look pale.

The primary symptoms of hypotension are lightheadedness or dizziness.

If the blood pressure is sufficiently low, fainting may occur.

Low blood pressure is sometimes associated with certain symptoms, many of which are related to causes rather than effects of hypotension:

- chest pain

- shortness of breath

- irregular heartbeat

- fever higher than 38.3 °C (101 °F)

- headache

- stiff neck

- severe upper back pain

- cough with sputum

- Prolonged diarrhea or vomiting

- dyspepsia (indigestion)

- dysuria (painful urination)

- adverse effect of medications

- acute, life-threatening allergic reaction

- seizures

- loss of consciousness

- profound fatigue

- temporary blurring or loss of vision

- Black tarry stools

Orthostatic hypotension is caused primarily by gravity-induced blood pooling in the lower extremities, which in turn compromises venous return, resulting in decreased cardiac output and subsequent lowering of arterial pressure. For example, changing from a lying position to standing loses about 700 ml of blood from the thorax, with a decrease in systolic and diastolic blood pressures. The overall effect is an insufficient blood perfusion in the upper part of the body.

Still, the blood pressure does not normally fall very much, because it immediately triggers a vasoconstriction (baroreceptor reflex), pressing the blood up into the body again. (Often, this mechanism is exaggerated and is why diastolic blood pressure is a bit higher when a person is standing up, compared to a person in the horizontal position.) Therefore, a secondary factor that causes a greater than normal fall in blood pressure is often required. Such factors include low blood volume, diseases, and medications.

Orthostatic hypotension, also called "postural hypotension", is a common form of low blood pressure. It occurs after a change in body position, typically when a person stands up from either a seated or lying position. It is usually transient and represents a delay in the normal compensatory ability of the autonomic nervous system. It is commonly seen in hypovolemia and as a result of various medications. In addition to blood pressure-lowering medications, many psychiatric medications, in particular antidepressants, can have this side effect. Simple blood pressure and heart rate measurements while lying, seated, and standing (with a two-minute delay in between each position change) can confirm the presence of orthostatic hypotension. Orthostatic hypotension is indicated if there is a drop in 20 mmHg of systolic pressure (and a 10 mmHg drop in diastolic pressure in some facilities) and a 20 beats per minute increase in heart rate.

Vasovagal syncope is a form of dysautonomia characterized by an inappropriate drop in blood pressure while in the upright position. Vasovagal syncope occurs as a result of increased activity of the vagus nerve, the mainstay of the parasympathetic nervous system .

Another, but rarer form, is postprandial hypotension, a drastic decline in blood pressure that occurs 30 to 75 minutes after eating substantial meals. When a great deal of blood is diverted to the intestines (a kind of "splanchnic blood pooling") to facilitate digestion and absorption, the body must increase cardiac output and peripheral vasoconstriction to maintain enough blood pressure to perfuse vital organs, such as the brain. Postprandial hypotension is believed to be caused by the autonomic nervous system not compensating appropriately, because of aging or a specific disorder.

Hypotension is a feature of Flammer syndrome which is characterized by cold hands and feet and predisposes to normal tension glaucoma.

The tilt table test is an evaluative clinical test to help identify postural hypotension, a common cause of presyncope or syncope. A tilt angle of 60 and 70 degrees is optimal and maintains a high degree of specificity. A positive sign with the tilt table test must be taken in context of patient history, with consideration of pertinent clinical findings before coming to a conclusion.

The hallmark sign of POTS is a measured increase in heart rate by at least 30 beats per minute within 10 minutes of assuming an upright position. For people aged between 12 and 19, the minimum increase for diagnosis is 40 beats per minute. This symptom is known as orthostatic (upright) tachycardia (fast heart rate). It occurs without any coinciding drop in blood pressure, as that would indicate orthostatic hypotension. It should be noted, however, that certain medications to treat POTS may cause orthostatic hypotension. It is accompanied by other features of orthostatic intolerance—symptoms which develop in an upright position and are relieved by reclining. These orthostatic symptoms include palpitations, light-headedness, chest discomfort, shortness of breath, nausea, weakness or "heaviness" in the lower legs, blurred vision and cognitive difficulties. Symptoms may be exacerbated with prolonged sitting, prolonged standing, alcohol, heat, exercise, or eating a large meal.

In up to one third of people with POTS, fainting occurs in response to postural changes or exercise. Migraine-like headaches are common, sometimes with symptoms worsening in an upright position (orthostatic headache). Some people with POTS develop acrocyanosis, or blotchy, red/blue skin upon standing, especially over the feet (indicative of blood pooling). 48% of people with POTS report chronic fatigue and 32% report sleep disturbances. Others exhibit only the cardinal symptom of orthostatic tachycardia.

POTS can co-occur in all types of Ehlers–Danlos syndrome (EDS), a hereditary connective tissue disorder marked by loose hypermobile joints prone to subluxations and dislocations, skin that exhibits moderate or greater laxity, easy bruising, and many other symptoms. A trifecta of POTS, EDS, and Mast Cell Activation Syndrome (MCAS) is becoming increasingly more common, with a genetic marker common among all three conditions. POTS is also often accompanied by vasovagal syncope, with a 25% overlap being reported. There is significant overlap between POTS and chronic fatigue syndrome, with evidence of POTS in 25–50% of CFS cases. Fatigue and reduced exercise tolerance are prominent symptoms of both conditions, and dysautonomia may underlie both conditions.

Presyncope is a state of lightheadedness, muscular weakness, blurred vision, and feeling faint (as opposed to a syncope, which is actually fainting). Presyncope is most often cardiovascular in cause. In many people, lightheadedness is a symptom of orthostatic hypotension. Orthostatic hypotension occurs when blood pressure drops significantly when the patient stands from a supine (horizontal) or seatted position. If loss of consciousness occurs in this situation, it is termed syncope.

Presyncope is frequently reported in people with autonomic dysfunctions such as the postural orthostatic tachycardia syndrome (POTS).

The symptoms of POTS can be caused by several distinct pathophysiological mechanisms. These mechanisms are poorly understood, and can overlap, with many people showing features of multiple POTS types. Many people with POTS exhibit low blood volume (hypovolemia), which can decrease the rate of blood flow to the heart. To compensate for this, the heart increases its cardiac output by beating faster, leading to the symptoms of presyncope and reflex tachycardia.

In the 30% to 60% of cases classified as "hyperadrenergic POTS", norepinephrine levels are elevated on standing, often due to hypovolemia or partial autonomic neuropathy. A smaller minority of people with POTS have (typically very high) standing norepinephrine levels that are elevated even in the absence of hypovolemia and autonomic neuropathy; this is classified as "central hyperadrenergic POTS". The high norepinephrine levels contribute to symptoms of tachycardia. Another subtype, "neuropathic POTS", is associated with denervation of sympathetic nerves in the lower limbs. In this subtype, it is thought that impaired constriction of the blood vessels causes blood to pool in the veins of the lower limbs. Heart rate increases to compensate for this blood pooling.

Genetics likely plays a role, with one study finding that 1 in 8 POTS patients reported a history of orthostatic intolerance in their family. In up to 50% of cases, POTS is associated with recent viral illness. It may also be associated with physical deconditioning or chronic fatigue syndrome. During viral illness or prolonged bed rest, the body may become conditioned to orthostatic intolerance and excitability of the central nervous system, resulting in a failure to re-adapt to the normal demands of standing or exercise.

POTS is more common in females than males. It has also been shown to be linked in patients with acute stressors such as pregnancy, recent surgery, or recent trauma. POTS has been also linked to patients with a history of autoimmune diseases, IBS, anemia, hyperthyroidism, fibromyalgia, diabetes, amyloidosis, sarcoidosis, systemic lupus erythmatosus, and cancer.

If POTS is caused by another condition, it may be classified as "secondary POTS". Chronic diabetes mellitus is one frequently seen primary cause. POTS can also be secondary to gastrointestinal disorders that are associated with low fluid intake due to nausea or fluid loss through diarrhea, leading to hypovolemia.

There are a subset of patients that present with both POTS and mast cell activation syndrome (MCAS), and it is not yet clear whether MCAS is a secondary cause of POTS or simply comorbid, however treating MCAS for these patients can significantly improve POTS symptoms.

POTS can sometimes be a paraneoplastic syndrome associated with cancer. Autoantibodies have been found in some cases which occur after a viral infection raising the possibility of some cases being autoimmune in nature.

Symptoms of cardiogenic shock include:

- Distended jugular veins due to increased jugular venous pressure

- Weak or absent pulse

- Abnormal heart rhythms, often a fast heart rate

- Pulsus paradoxus in case of tamponade

- Reduced blood pressure

Patients who suffer from acute OI usually manifest the disorder by a temporary loss of consciousness and posture, with rapid recovery (simple faints, or syncope), as well as remaining conscious during their loss of posture. This is different from a syncope caused by cardiac problems because there are known triggers for the fainting spell (standing, heat, emotion) and identifiable prodromal symptoms (nausea, blurred vision, headache). As Dr. Julian M. Stewart, an expert in OI from New York Medical College states, "Many syncopal patients have no intercurrent illness; between faints, they are well."

Symptoms:

- Altered vision (blurred vision, "white outs"/gray outs, black outs, double vision)

- Anxiety

- Exercise intolerance

- Fatigue

- Headache

- Heart palpitations, as the heart races to compensate for the falling blood pressure

- Hyperpnea or sensation of difficulty breathing or swallowing (see also hyperventilation syndrome)

- Lightheadedness

- Sweating

- Tremulousness

- Weakness

A classic manifestation of acute OI is a soldier who faints after standing rigidly at attention for an extended period of time.

Patients with chronic orthostatic intolerance have symptoms on most or all days. Their symptoms may include most of the symptoms of acute OI, plus:

- Nausea

- Neurocognitive deficits, such as attention problems

- Pallor

- Sensitivity to heat

- Sleep problems

- Other vasomotor symptoms.

Distributive shock includes infectious, anaphylactic, endocrine (e.g., adrenal insufficiency), salicylate toxicity, and neurogenic causes. The SIRS features typically occur in early septic shock.

Neurogenic shock can result from severe central nervous system damage (brain injury, cervical or high thoracic spinal cord). In more simple terms: the trauma causes a sudden loss of background sympathetic stimulation to the blood vessels. This causes them to relax (vasodilation) resulting in a sudden decrease in blood pressure (secondary to a decrease in peripheral vascular resistance).

Neurogenic shock results from damage to the spinal cord above the level of the 6th thoracic vertebra. It is found in about half of people who suffer spinal cord injury within the first 24 hours, and usually doesn't go away for one to three weeks.

Distributive shock is a medical condition in which abnormal distribution of blood flow in the smallest blood vessels results in inadequate supply of blood to the body's tissues and organs. It is one of four categories of shock, a condition where there is not enough oxygen-carrying blood to meet the metabolic needs of the cells which make up the body's tissues and organs. Distributive shock is different from the other three categories of shock in that it occurs even though the output of the heart is at or above a normal level. The most common cause is sepsis leading to type of distributive shock called septic shock, a condition that can be fatal.

The upper threshold of a normal human resting heart rate is based on age. Cutoff values for tachycardia in different age groups are fairly well standardized; typical cutoffs are listed below:

- 1–2 days: Tachycardia > 159 beats per minute (bpm)

- 3–6 days: Tachycardia >166 bpm

- 1–3 weeks: Tachycardia >182 bpm

- 1–2 months: Tachycardia >179 bpm

- 3–5 months: Tachycardia >186 bpm

- 6–11 months: Tachycardia >169 bpm

- 1–2 years: Tachycardia >151 bpm

- 3–4 years: Tachycardia >137 bpm

- 5–7 years: Tachycardia >133 bpm

- 8–11 years: Tachycardia >130 bpm

- 12–15 years: Tachycardia >119 bpm

- >15 years – adult: Tachycardia >100 bpm

Heart rate is considered in the context of the prevailing clinical picture. For example: in sepsis >90 bpm is considered tachycardia.

When the heart beats excessively or rapidly, the heart pumps less efficiently and provides less blood flow to the rest of the body, including the heart itself. The increased heart rate also leads to increased work and oxygen demand by the heart, which can lead to rate related ischemia.

Relative tachycardia involves a greater increase in rate than would be expected in a given illness state.

The body has several feedback mechanisms to maintain adequate blood flow and blood pressure. If blood pressure decreases, the heart beats faster in an attempt to raise it. This is called reflex tachycardia. This can happen in response to a decrease in blood volume (through dehydration or bleeding), or an unexpected change in blood flow. The most common cause of the latter is orthostatic hypotension (also called postural hypotension). Fever, hyperventilation, diarrhea and severe infections can also cause tachycardia, primarily due to increase in metabolic demands.

An increase in sympathetic nervous system stimulation causes the heart rate to increase, both by the direct action of sympathetic nerve fibers on the heart and by causing the endocrine system to release hormones such as epinephrine (adrenaline), which have a similar effect. Increased sympathetic stimulation is usually due to physical or psychological stress. This is the basis for the so-called fight-or-flight response, but such stimulation can also be induced by stimulants such as ephedrine, amphetamines or cocaine. Certain endocrine disorders such as pheochromocytoma can also cause epinephrine release and can result in tachycardia independent of nervous system stimulation. Hyperthyroidism can also cause tachycardia. The upper limit of normal rate for sinus tachycardia is thought to be 220 bpm minus age.

Because it causes a loss of sympathetic tone, which plays a major role in other forms of shock, neurogenic shock causes a unique and atypical presentation.

Typically, in other forms of shock, the sympathetic nervous system triggers various compensatory mechanisms by releasing epinephrine and norepinephrine, its major chemical mediators. These neurotransmitters trigger an increased heart rate, faster breathing, and sweating. They also trigger vasoconstriction, to shunt blood away from the extremities and to the vital organs.

In neurogenic shock, the body loses its ability to activate the sympathetic nervous system and cannot trigger these compensatory mechanisms. Only parasympathetic tone remains. Consequently, neurogenic shock's unique presentation includes:

- Instantaneous hypotension due to sudden, massive vasodilation

- Warm, flushed skin due to vasodilation and inability to vasoconstrict

- Priapism, also due to vasodilation

- The patient will be unable to get tachycardic, and may become bradycardic

- If the injury is below the 5th cervical vertebra, the patient will exhibit diaphragmatic breathing due to loss of nervous control of the intercostal muscles (which are required for thoracic breathing).

- If the injury is above the 3rd cervical vertebra, the patient will go into respiratory arrest immediately following the injury, due to loss of nervous control of the diaphragm.

Usually in women with no heart problems, this syndrome is characterized by normal resting heart rate but exaggerated postural sinus tachycardia with or without orthostatic hypotension.

Elbers and Ince have identified five classes of abnormal microcirculatory flow in distributive shock using side stream dark field microscopy.

- Class I: all capillaries are stagnant when there is normal or sluggish venular flow.

- Class II: there are empty capillaries next to capillaries that have flowing red blood cells.

- Class III: there stagnant capillaries next to capillaries with normal blood flow.

- Class IV: hyperdynamic flow in capillaries adjacent to capillaries that are stagnant.

- Class V: widespread hyperdynamic flow in the microcirculatory system.

Signs and symptoms of CSWS include large amounts of urination (at least 3 liters of urine output over a 24-hour period for adults) due to inadequate sodium retention in the body, high amounts of sodium in the urine, low blood sodium concentration, excessive thirst, extreme salt cravings, dysfunction of the autonomic nervous system, and dehydration. Patients often self-medicate by naturally gravitating toward a high-sodium diet and by dramatically increasing their water intake. Advanced symptoms include muscle cramps, lightheadedness, dizziness or vertigo, feelings of anxiety or panic (not mentally induced), increased heart rate or slowed heart rate, low blood pressure and orthostatic hypotension sometimes resulting in fainting. Other symptoms frequently associated with dysautonomia include: headaches, pallor, malaise, facial flushing, constipation or diarrhea, nausea, acid reflux, visual disturbances, numbness, nerve pain, trouble breathing, chest pains, loss of consciousness and seizures.

Also known as chronic nonparoxysmal sinus tachycardia, patients have elevated resting heart rate and/or exaggerated heart rate in response to exercise. These patients have no apparent heart disease or other causes of sinus tachycardia. IST is thought to be due to abnormal autonomic control.

CSWS is usually caused by brain injury/trauma or cerebral lesion, tumor, or hematoma. CSWS is a diagnosis of exclusion and may be difficult to distinguish from the syndrome of inappropriate antidiuretic hormone (SIADH), which develops under similar circumstances and also presents with hyponatremia. The main clinical difference is that of total fluid status of the patient: CSWS leads to a relative or overt low blood volume whereas SIADH is consistent with a normal or high blood volume. If blood-sodium levels increase when fluids are restricted, SIADH is more likely.

Symptoms reported by patients vary in frequency and severity.

Symptoms associated with IST include:

- Frequent or sustained palpitations

- Dyspnea (shortness of breath) and palpitations on exertion

- Pre-syncope (feeling as if about to faint)

- Fatigue (physical)

- Dizziness

- Exercise intolerance

- Occasional paresthesia and cramping

- Symptoms associated with autonomic nervous system disturbance, including GI disturbance

Dopamine beta (β)-hydroxylase deficiency is a condition that affects the autonomic nervous system (ANS). The ANS works via two opposing branches, the sympathetic and parasympathetic, both of which antagonistically control involuntary processes that regulate bodily homeostasis. Problems related to DβH deficiency often first appear as complications shortly after birth. Postnatal episodes may include vomiting, dehydration, hypotension, muscle hypotonia, hypothermia, and hypoglycemia.

Due to the deficiency of norepinephrine and epinephrine those affected by dopamine β-hydroxylase deficiency may present with droopy eyelids (ptosis), nasal congestion, and hypotension. The most common complaint of individuals with dopamine β-hydroxylase deficiency is orthostatic hypotension. The symptoms associated with orthostatic hypotension are dizziness, blurred vision, or fainting upon standing. Therefore, DβH deficiency patients may have an inability to stand for a prolonged period of time. This phenomenon is especially pronounced when going from supine to upright positions, such as getting out of bed in the morning. It is also worsened by extreme climates due to loss of fluid through excessive sweating. The inability to maintain normal blood pressure makes it difficult for people with DβH deficiency to exercise (exercise intolerance). Males with DβH deficiency may experience retrograde ejaculation, a discharge of semen backward into the bladder due to dysmotility of their smooth muscle, which as innervated by the ANS. A subset of DβH deficiency patients present with hypermobility. Postural orthostatic tachycardia syndrome, another form of dysautonomia, also sees this comorbidity with hypermobility in the form of a rare connective tissue disorder called Ehlers Danlos syndrome.

Another commonly experienced symptom is hypoglycemia, which is thought to be caused by adrenomedullary failure. In looking at the cardiovascular system, a loss of noradrenergic control is seen as T-wave abnormalities on electrocardiogram. Prolactin is frequently suppressed by excessive dopamine found in the patient's central nervous system. Excess dopamine can also affect digestion, producing vomiting and inhibiting motor signaling to the GI tract.

A degenerative disease of the autonomic nervous system, symptoms include dizziness and fainting (caused by orthostatic hypotension), visual disturbances and neck pain. Chest pain, fatigue and sexual dysfunction are less common symptoms that may also occur. Symptoms are worse when standing; sometimes one may relieve symptoms by lying down.