Venous thrombosis

Venous thrombosis is thrombosis in a vein, caused by a thrombus (blood clot). The most common form of venous thrombosis is a deep vein thrombosis (DVT), when a blood clot forms in the deep veins of the leg. If the thrombus breaks off (it embolizes) and flows towards the lungs, it can become a pulmonary embolism (PE), a blood clot in the lungs. This combination is called venous thromboembolism. Various other forms of venous thrombosis also exist; some of these can also lead to pulmonary embolism.

Venous thrombosis
A deep vein thrombosis in the right leg. There is striking redness and swelling.
SpecialtyHematology, pulmonology, cardiology
Frequency1-2 per 1,000 per year[1]

The initial treatment for venous thromboembolism is typically with either low molecular weight heparin (LMWH) or unfractionated heparin, or increasingly with directly acting oral anticoagulants (DOAC). Those initially treated with heparins can be switched to other anticoagulants (warfarin, DOACs), although pregnant women and some people with cancer receive ongoing heparin treatment. Superficial venous thrombosis only requires anticoagulation in specific situations, and may be treated with anti-inflammatory pain relief only.

Classification

Common forms

Superficial venous thromboses cause discomfort but generally not serious consequences, as do the deep vein thromboses (DVTs) that form in the deep veins of the legs or in the pelvic veins. Nevertheless, they can progress to the deep veins through the perforator veins or, they can be responsible for a lung embolism mainly if the head of the clot is poorly attached to the vein wall and is situated near the sapheno-femoral junction.

When a blood clot breaks loose and travels in the blood, this is called a venous thromboembolism (VTE). The abbreviation DVT/PE refers to a VTE where a deep vein thrombosis (DVT) has moved to the lungs (PE or pulmonary embolism).[2]

Since the veins return blood to the heart, if a piece of a blood clot formed in a vein breaks off it can be transported to the right side of the heart, and from there into the lungs. A piece of thrombus that is transported in this way is an embolus: the process of forming a thrombus that becomes embolic is called a thromboembolism. An embolism that lodges in the lungs is a pulmonary embolism (PE). A pulmonary embolism is a very serious condition that can be fatal depending on the dimensions of the embolus.

Rare forms

While venous thrombosis of the legs is the most common form, venous thrombosis may occur in other veins. These may have particular specific risk factors:[3]

Parodoxical embolism

Systemic embolism of venous origin can occur in patients with an atrial or ventricular septal defect, or an arteriovenous connection in the lung, through which an embolus may pass into the arterial system. Such an event is termed a paradoxical embolism. When this affects the blood vessels of the brain it can cause stroke.[4]

Causes

Venous thrombi are caused mainly by a combination of venous stasis and hypercoagulability—but to a lesser extent endothelial damage and activation.[5] The three factors of stasis, hypercoaguability, and alterations in the blood vessel wall represent Virchow's triad, and changes to the vessel wall are the least understood.[6] Various risk factors increase the likelihood of any one individual developing a thrombosis.

Acquired

Inherited

Mixed

The overall absolute risk of venous thrombosis per 100,000 woman years in current use of combined oral contraceptives is approximately 60, compared to 30 in non-users.[21] The risk of thromboembolism varies with different types of birth control pills; Compared with combined oral contraceptives containing levonorgestrel (LNG), and with the same dose of estrogen and duration of use, the rate ratio of deep vein thrombosis for combined oral contraceptives with norethisterone is 0.98, with norgestimate 1.19, with desogestrel (DSG) 1.82, with gestodene 1.86, with drospirenone (DRSP) 1.64, and with cyproterone acetate 1.88.[21] Venous thromboembolism occurs in 100–200 per 100,000 pregnant women every year.[21]

Regarding family history, age has substantial effect modification. For individuals with two or more affected siblings, the highest incidence rates is found among those ≥70 years of age (390 per 100,000 in male and 370 per 100,000 in female individuals), whereas the highest incidence ratios compared to those without affected siblings occurred at much younger ages (ratio of 4.3 among male individuals 20 to 29 years of age and 5.5 among female individuals 10 to 19 years of age).[22]

Risk of venous thromboembolism (VTE) with hormone therapy and birth control (QResearch/CPRD)
TypeRouteMedicationsOdds ratio (95% CI)
Menopausal hormone therapyOralEstradiol alone
    ≤1 mg/day
    >1 mg/day
1.27 (1.16–1.39)*
1.22 (1.09–1.37)*
1.35 (1.18–1.55)*
Conjugated estrogens alone
    ≤0.625 mg/day
    >0.625 mg/day
1.49 (1.39–1.60)*
1.40 (1.28–1.53)*
1.71 (1.51–1.93)*
Estradiol/medroxyprogesterone acetate1.44 (1.09–1.89)*
Estradiol/dydrogesterone
    ≤1 mg/day E2
    >1 mg/day E2
1.18 (0.98–1.42)
1.12 (0.90–1.40)
1.34 (0.94–1.90)
Estradiol/norethisterone
    ≤1 mg/day E2
    >1 mg/day E2
1.68 (1.57–1.80)*
1.38 (1.23–1.56)*
1.84 (1.69–2.00)*
Estradiol/norgestrel or estradiol/drospirenone1.42 (1.00–2.03)
Conjugated estrogens/medroxyprogesterone acetate2.10 (1.92–2.31)*
Conjugated estrogens/norgestrel
    ≤0.625 mg/day CEEs
    >0.625 mg/day CEEs
1.73 (1.57–1.91)*
1.53 (1.36–1.72)*
2.38 (1.99–2.85)*
Tibolone alone1.02 (0.90–1.15)
Raloxifene alone1.49 (1.24–1.79)*
TransdermalEstradiol alone
   ≤50 μg/day
   >50 μg/day
0.96 (0.88–1.04)
0.94 (0.85–1.03)
1.05 (0.88–1.24)
Estradiol/progestogen0.88 (0.73–1.01)
VaginalEstradiol alone0.84 (0.73–0.97)
Conjugated estrogens alone1.04 (0.76–1.43)
Combined birth controlOralEthinylestradiol/norethisterone2.56 (2.15–3.06)*
Ethinylestradiol/levonorgestrel2.38 (2.18–2.59)*
Ethinylestradiol/norgestimate2.53 (2.17–2.96)*
Ethinylestradiol/desogestrel4.28 (3.66–5.01)*
Ethinylestradiol/gestodene3.64 (3.00–4.43)*
Ethinylestradiol/drospirenone4.12 (3.43–4.96)*
Ethinylestradiol/cyproterone acetate4.27 (3.57–5.11)*
Notes: (1) Nested case–control studies (2015, 2019) based on data from the QResearch and Clinical Practice Research Datalink (CPRD) databases. (2) Bioidentical progesterone was not included, but is known to be associated with no additional risk relative to estrogen alone. Footnotes: * = Statistically significant (p < 0.01). Sources: See template.
Absolute and relative incidence of venous thromboembolism (VTE) during pregnancy and the postpartum period
Absolute incidence of first VTE per 10,000 person–years during pregnancy and the postpartum period
Swedish data A Swedish data B English data Danish data
Time period N Rate (95% CI) N Rate (95% CI) N Rate (95% CI) N Rate (95% CI)
Outside pregnancy 1105 4.2 (4.0–4.4) 1015 3.8 (?) 1480 3.2 (3.0–3.3) 2895 3.6 (3.4–3.7)
Antepartum 995 20.5 (19.2–21.8) 690 14.2 (13.2–15.3) 156 9.9 (8.5–11.6) 491 10.7 (9.7–11.6)
  Trimester 1 207 13.6 (11.8–15.5) 172 11.3 (9.7–13.1) 23 4.6 (3.1–7.0) 61 4.1 (3.2–5.2)
  Trimester 2 275 17.4 (15.4–19.6) 178 11.2 (9.7–13.0) 30 5.8 (4.1–8.3) 75 5.7 (4.6–7.2)
  Trimester 3 513 29.2 (26.8–31.9) 340 19.4 (17.4–21.6) 103 18.2 (15.0–22.1) 355 19.7 (17.7–21.9)
Around delivery 115 154.6 (128.8–185.6) 79 106.1 (85.1–132.3) 34 142.8 (102.0–199.8)
Postpartum 649 42.3 (39.2–45.7) 509 33.1 (30.4–36.1) 135 27.4 (23.1–32.4) 218 17.5 (15.3–20.0)
  Early postpartum 584 75.4 (69.6–81.8) 460 59.3 (54.1–65.0) 177 46.8 (39.1–56.1) 199 30.4 (26.4–35.0)
  Late postpartum 65 8.5 (7.0–10.9) 49 6.4 (4.9–8.5) 18 7.3 (4.6–11.6) 319 3.2 (1.9–5.0)
Incidence rate ratios (IRRs) of first VTE during pregnancy and the postpartum period
Swedish data A Swedish data B English data Danish data
Time period IRR* (95% CI) IRR* (95% CI) IRR (95% CI)† IRR (95% CI)†
Outside pregnancy
Reference (i.e., 1.00)
Antepartum 5.08 (4.66–5.54) 3.80 (3.44–4.19) 3.10 (2.63–3.66) 2.95 (2.68–3.25)
  Trimester 1 3.42 (2.95–3.98) 3.04 (2.58–3.56) 1.46 (0.96–2.20) 1.12 (0.86–1.45)
  Trimester 2 4.31 (3.78–4.93) 3.01 (2.56–3.53) 1.82 (1.27–2.62) 1.58 (1.24–1.99)
  Trimester 3 7.14 (6.43–7.94) 5.12 (4.53–5.80) 5.69 (4.66–6.95) 5.48 (4.89–6.12)
Around delivery 37.5 (30.9–44.45) 27.97 (22.24–35.17) 44.5 (31.68–62.54)
Postpartum 10.21 (9.27–11.25) 8.72 (7.83–9.70) 8.54 (7.16–10.19) 4.85 (4.21–5.57)
  Early postpartum 19.27 (16.53–20.21) 15.62 (14.00–17.45) 14.61 (12.10–17.67) 8.44 (7.27–9.75)
  Late postpartum 2.06 (1.60–2.64) 1.69 (1.26–2.25) 2.29 (1.44–3.65) 0.89 (0.53–1.39)
Notes: Swedish data A = Using any code for VTE regardless of confirmation. Swedish data B = Using only algorithm-confirmed VTE. Early postpartum = First 6 weeks after delivery. Late postpartum = More than 6 weeks after delivery. * = Adjusted for age and calendar year. † = Unadjusted ratio calculated based on the data provided. Source: [23]

Pathophysiology

In contrast to the understanding for how arterial thromboses occur, as with heart attacks, venous thrombosis formation is not well understood.[24] With arterial thrombosis, blood vessel wall damage is required for thrombosis formation, as it initiates coagulation,[24] but the majority of venous thrombi form without any injured epithelium.[5]

Red blood cells and fibrin are the main components of venous thrombi,[5] and the thrombi appear to attach to the blood vessel wall endothelium, normally a non-thrombogenic surface, with fibrin.[24] Platelets in venous thrombi attach to downstream fibrin, while in arterial thrombi, they compose the core.[24] As a whole, platelets constitute less of venous thrombi when compared to arterial ones.[5] The process is thought to be initiated by tissue factor-affected thrombin production, which leads to fibrin deposition.[6]

The valves of veins are a recognized site of VT initiation. Due to the blood flow pattern, the base of the valve sinus is particularly deprived of oxygen (hypoxic). Stasis excacerbates hypoxia, and this state is linked to the activation of white blood cells (leukocytes) and the endothelium. Specifically, the two pathways of hypoxia-inducible factor-1 (HIF-1) and early growth response 1 (EGR-1) are activated by hypoxia, and they contribute to monocyte and endothelial activation. Hypoxia also causes reactive oxygen species (ROS) production that can activate HIF-1, EGR-1, and nuclear factor-κB (NF-κB), which regulates HIF-1 transcription.[6]

HIF-1 and EGR-1 pathways lead to monocyte association with endothelial proteins, such as P-selectin, prompting monocytes to release tissue factor-filled microvesicles, which presumably initiate fibrin deposition (via thrombin) after binding the endothelial surface.[6]

Prevention

Evidence supports the use of heparin in people following surgery who have a high risk of thrombosis to reduce the risk of DVTs; however, the effect on PEs or overall mortality is not known.[25] In hospitalized non-surgical patients, mortality does not appear to change.[26][27][28] It does not appear, however, to decrease the rate of symptomatic DVTs.[26] Using both heparin and compression stockings appears better than either one alone in reducing the rate of DVT.[29]

In hospitalized people who have had a stroke and not had surgery, mechanical measures (compression stockings) resulted in skin damage and no clinical improvement.[26] Data on the effectiveness of compression stockings among hospitalized non-surgical patients without stroke is scarce.[26]

The American College of Physicians (ACP) gave three strong recommendations with moderate quality evidence on VTE prevention in non-surgical patients: that hospitalized patients be assessed for their risk of thromboembolism and bleeding before prophylaxis (prevention); that heparin or a related drug is used if potential benefits are thought to outweigh potential harms; and that graduated compression stockings not be used.[30] As an ACP policy implication, the guideline stated a lack of support for any performance measures that incentivize physicians to apply universal prophylaxis without regard to the risks.[30] Goldhaber recommends that people should be assessed at their hospital discharge for persistent high-risk of venous thrombosis and that people who adopt a heart-healthy lifestyle might lower their risk of venous thrombosis.[31]

People who have cancer have a higher risk of VTE and may respond differently to anticoagulant preventative treatments and prevention measures.[32] For people undergoing chemotherapy for cancer who are able to walk (ambulatory), low molecular weight heparins treatment (LMWH) decreases the risk of VTE.[33] Due to potential concerns of bleeding its routine use is not recommended.[33] For people who are having surgery for cancer, it is recommended that they receive anticoagulation therapy (preferably LMWH) in order to prevent a VTE.[34] LMWH is recommended for at least 7–10 days following cancer surgery, and for one month following surgery for people who have a high risk of VTEs.[35][34]

In adults who have had their lower leg casted, braced, or otherwise immobilized for more than a week, LMWH may decrease the risk and severity of deep vein thrombosis, but does not have any effect on the incidence of pulmonary embolism .[36] LMWH is recommended for adults not in hospital with an above-knee cast and a below-knee cast, and is safe for this indication.[37]

Following the completion of warfarin in those with prior VTE, the use of long-term aspirin has been show to be beneficial.[38]

Treatment

American evidence-based clinical guidelines were published in 2016 for the treatment of VTE.[39] In the UK, guidelines by the National Institute for Health and Care Excellence (NICE) were published in 2012, updated in 2020.[40] These guidelines do not cover rare forms of thrombosis, for which an individualized approach is often needed.[3] Central and branch retinal vein occlusion does not benefit from anticoagulation in the way that other venous thromboses do.[3]

Anticoagulation

If diagnostic testing cannot be performed swiftly, many are commenced on empirical treatment.[40] Traditionally this was heparin, but several of the DOACs are licensed for treatment without initial heparin use.[39]

If heparin is used for initial treatment of VTE, fixed doses with low molecular weight heparin may be more effective than adjusted doses of unfractionated heparin (UFH) in reducing blood clots.[41] No differences in mortality, prevention of major bleeding, or preventing VTEs from recurring were observed between LMWH and UFH.[42] No differences have been detected in the route of administration of UFH (subcutaneous or intravenous).[41] LMWH is usually administered by a subcutaneous injection, and a person's blood clotting factors do not have to be monitored as closely as with UFH.[41]

Once the diagnosis is confirmed, a decision needs to be made about the nature of the ongoing treatment and its duration. USA recommendations for those without cancer include anticoagulation (medication that prevents further blood clots from forming) with the DOACs dabigatran, rivaroxaban, apixaban, or edoxaban rather than warfarin or low molecular weight heparin (LMWH).[39]

For those with cancer, LMWH is recommended,[39] although DOACs appear safe in the majority of situations.[40] For long-term treatment in people with cancer, LMWH is probably more effective at reducing VTEs when compared to vitamin K antagonists.[32] People with cancer have a higher risk of experiencing reoccurring VTE episodes ("recurrent VTE"), even while taking preventative anticoagulation medication. These people should be given therapeutic doses of LMWH medication, either by switching from another anticoagulant or by taking a higher dose of LMWH.[43]

In pregnancy, warfarin and DOACs are not considered suitable and LMWH is recommended.[39]

For those with a small pulmonary embolism and few risk factors, no anticoagulation is needed.[39] Anticoagulation is, however, recommended in those who do have risk factors.[39]

Thrombolysis

Thrombolysis is the administration of medication (a recombinant enzyme) that activates plasmin, the body's main enzyme that breaks down blood clots. This carries a risk of bleeding and is therefore reserved for those who have a form of thrombosis that may cause major complications. In pulmonary embolism, this applies in situations where heart function is compromised due to lack of blood flow through the lungs ("massive" or "high risk" pulmonary embolism), leading to low blood pressure.[39] Deep vein thrombosis may require thrombolysis if there is a significant risk of post-thrombotic syndrome.[39] Thrombolysis may be administered by intravenous catheter directly into the clot ("catheter-directed thrombolysis"); this requires a lower dose of the medication and may carry a lower bleeding risk but evidence for its benefit is limited.[39]

Inferior vena cava filters

Inferior vena cava filters (IVCFs) are not recommended in those who are on anticoagulants.[39] IVCFs may be used in clinical situations where a person has a high risk of experiencing a pulmonary embolism, but cannot be on anticoagulants due to a high risk of bleeding, or they have active bleeding.[43][44] Retrievable IVCFs are recommended if IVCFs must be used, and a plan should be created to remove the filter when it is no longer needed.[43]

Superficial venous thrombosis

While topical treatments for superficial venous thrombosis are widely used, the evidence is strongest for the heparin-like drug fondaparinux (a factor Xa inhibitor), which reduces extension and recurrence of superficial venous thrombosis as well as progression to symptomatic embolism.[45]

Prognosis

After an episode of unprovoked VTE, the risk of further episodes after completing treatment remains elevated, although this risk diminishes over time. Over ten years, 41% of men and 29% of women can expect to experience a further episode. For each episode, the risk of death is 4%.[46]

See also

References

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