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. 2024 Jul 12;22:62. doi: 10.1186/s12959-024-00627-2

Outcomes of deep venous thrombosis management and associated factors among patients in tertiary hospitals in Addis Ababa, Ethiopia: a multicenter retrospective cohort study

Seble Birhane 1, Melak Gedamu Beyene 1, Fishatsion Tadesse 2, Assefa Mulu Baye 1,
PMCID: PMC11241949  PMID: 38997721

Abstract

Background

Pulmonary embolism (PE) and deep venous thrombosis (DVT) are the two most important manifestations of venous thromboembolism (VTE). DVT remains a significant condition since associated morbidity is significant and has elevated healthcare-related costs.

Methods

A retrospective cohort study was conducted among DVT patients admitted to Tikur Anbessa Specialized Hospital, Zewditu Memorial Hospital and St. Paul’s Hospital Millennium Medical College on follow-up from July 1, 2017, to July 01, 2020. Data on sociodemographic characteristics, types of DVT, laboratory findings, medications, risk factors of DVT, complications and outcomes of DVT were collected. The data were analyzed using SPSS version 25. Multivariate logistic regression analysis was conducted to determine predictors of DVT recurrence and major bleeding. A P value < 0.05 was considered to identify significant predictors.

Results

The mean age of the participants was 45.2 years, with SD of 15.36. The major causes of DVT included immobilization (29.9%), previous surgery (27.5%) and cancer (21.1%). The DVT recurrence rate was 22.5%. Nine (2.2%) of the participants died, and 19.9% developed complications. Bilateral DVT (Adjusted odds ratio (AOR) = 2.8, 95% Confidence interval (CI) = 1.14, 6.66), obesity (AOR = 3.3, 95% CI = 1.15, 9.59), hypertension (AOR = 6.5, 95% CI = 2.90, 14.70) and retroviral infection (AOR = 6.3, 95% CI = 2.34, 16.94) were predictors of recurrent DVT. Nineteen (4.7%) patients had major bleeding, and patients with bilateral DVT, active cancer and terminal age had an increased risk of major bleeding.

Conclusions

The overall DVT recurrence rate was alarmingly high and further complicated by PE, post thrombotic syndrome and chronic vein insufficiency, resulting in a 2.2% death rate. Major bleeding after DVT and PE remained high. Close monitoring should be performed for patients with advanced age, active cancer, bilateral DVT, retroviral infection, obesity and hypertension to prevent the recurrence of DVT and major bleeding.

Keywords: Deep venous thrombosis, Recurrence, Bleeding, Addis Ababa

Introduction

Venous thromboembolism (VTE), including deep venous thrombosis (DVT) and/or pulmonary embolism (PE), is a common, severe, potentially fatal but manageable acute condition. Approximately 0.1% of the global population each year develop DVT [1]. DVT is a complex multifactorial disease and an important cause of preventable mortality and morbidity [2]. The incidence of DVT increases sharply after approximately 45 years of age and is slightly greater in men than in women of advanced age. Major risk factors for thrombosis, other than age, include exogenous factors such as surgery, hospitalization, immobility, trauma, pregnancy, and puerperium and hormone use and endogenous factors such as cancer, obesity, and inherited and acquired disorders of hypercoagulation [3].

Globally, DVT remains a significant condition since associated morbidity is significant and has elevated healthcare-related costs [4]. DVT and associated complications are common in hospital settings, but they are also becoming more common among outpatients. The incidence of VTE was 5.5% among hospitalized patients in a study conducted in Addis Ababa [5]. A study from Addis Ababa and Jimma reported that the recurrence rate of DVT was 26.4%, which is higher than most previously published data [6]. A study conducted in Canada revealed that the rates of recurrent VTE after DVT and PE remain unacceptably high, where one-fifth of cases experienced recurrent VTE [7]. According to a study in the US, DVT contributes to the deaths of 33% of those affected [8]. VTE is a major health problem in Europe, with more than one million VTE events or deaths per year in the six countries examined. Almost three-quarters of all VTE-related deaths were reported from hospital-acquired VTE [9].

According to the Centers for Disease Control and Prevention (CDC), one-third of patients diagnosed with DVT/PE experience recurrence within 10 years, and up to 50% develop post thrombotic syndrome (PTS) [10]. The frequency of recurrent DVT is increasing, making early identification and treatment of risk factors that predispose patients to recurrence critical.

The aim of treatment for DVT is to reduce morbidity and mortality. This is achieved by optimal therapy with anticoagulants to prevent thrombus extension and embolization, thus preventing recurrence and death, which exposes patients to an inherent increased risk of bleeding [11]. In a study from Canadan, among patients with DVT, 12.8% developed major bleeding during the follow-up period [7].

There is a dearth of information available in Ethiopia on the outcomes of DVT treatment and the risk factors for its recurrence. Most prior studies that examined the recurrence rate of DVT in Ethiopia had limited sample sizes and relied on nonmulticenter data, and most disregarded secondary outcomes such as major bleeding. Therefore, this study was conducted to evaluate treatment outcomes and associated factors among DVT patients receiving anticoagulation therapy at three tertiary care hospitals, namely, Tikur Anbessa Specialized Hospital (TASH), St. Paulos Hospital Millennium Medical College (SPHMMC) and Zewuditu Memorial Hospital (ZMH), in Addis Ababa.

Methods and materials

Study design, area and period

A retrospective cohort study was conducted among DVT patients at SPHMMC, ZMH and TASH. We chose these hospitals because they are referral hospitals which allows us to find diverse participants. During the data collection period, there were approximately 720 patients under regular follow-up at the clinics of the hospitals, with an average of 30 patients seen at each clinic daily. The data were collected from October 1, 2020 to March 31, 2021.

Population

DVT patients at TASH, SPHMMC and ZMH who were on follow-up between July 1, 2017, and July 1, 2020, who were aged 18 years and older, and who were on anticoagulants for at least 3 months or more were included. DVT patients who had incomplete data or medical records were excluded from the study.

Sample size determination

A total of 408 study participants were included using a single proportion population formula and were proportionally allocated to TASH, SPHMMC or ZMH. Systematic random sampling techniques were employed to select participants.

Data collection tools and procedures

The data collection tool was developed by using different studies [1214]. The data collected included sociodemographic characteristics, types of DVT, laboratory findings, a list of all medications, risk factors and clinical data, complications and outcomes of DVT. Information about the category of bleeding that occurred during the treatment period was evaluated based on the International Society on Thrombosis and Hemostasias [14]. All the data were collected from patient medical records.

The data were collected by two trained data collectors, one nurse and one pharmacist trained on the objective of the study and the contents of the questionnaire.

The validity of the study was checked by a pretest performed on 5% of the study population at St. Peter Specialized Hospital with similar characteristics to ensure the agreement of the data abstraction format with the needs of the study. Modifications were mainly made to the variables used to measure DVT treatment outcomes and were corrected and modified into the final version of the data collection tool. Continuous supervision was provided by the principal investigator to ensure the completeness and consistency of the collected data. All collected data were examined for completeness and consistency during data management, storage and analysis.

Data Analysis

The data were collected and entered into Epi info 4.6.0.6 and analyzed using Statistical Package for the Social Sciences (SPSS) version 25. Descriptive statistics such as frequency, percentage, mean, and standard deviation (SD) were used to describe demographic and clinical features, as well as the outcomes. Logistic regression models were used to determine whether the sociodemographic data, laboratory findings and comorbid conditions were related to outcomes such as recurrent DVT and major bleeding. Candidate variables possibly associated with the outcome variables (P value < 0.25) after bivariate analysis were included in the multivariable logistic regression model. A P value < 0.05 was considered a significant predictor of the outcome.

Outcome measures

The primary outcomes for the study were recurrence, major bleeding and death, whereas the secondary outcomes were factors for recurrent DVT and major bleeding.

Definition of terms

DVT recurrence

was defined as an objectively verified hospital discharge diagnosis of DVT, a fatal complication of DVT confirmed by ultrasonography, or a site of thrombosis that was either previously uninvolved or had interval documentation of incident DVT [14].

Major bleeding

included fatal bleeding; retroperitoneal, intracranial, or intraocular bleeding; bleeding that causes hemodynamic compromise requiring specific treatment; bleeding that requires intervention (surgical or endoscopic) or decompression of a closed space to stop or control the event; clinically overt bleeding, requiring any transfusion of one unit or more of packed red blood cells or whole blood; and clinically overt bleeding, causing a decrease in hemoglobin of 3 g/dL or more (or, if the hemoglobin level is not available, a decrease in hematocrit of 10% or greater) [15].

Complication

Complications from deep vein thrombosis can be very serious. It includes pulmonary embolism (PE), chronic venous insufficiency, and post thrombotic syndrome [16].

Results

Sociodemographic and clinical characteristics

The study sample consisted of 408 men and women from the three hospitals during the three-year study period and included patients who had taken anticoagulant medication for at least 3 months. The mean age and SD of the study participants were 45.2 and 15.36 years, respectively. As shown in Table 1, approximately one-third (36.5%) of the participants were in the ≥ 51 years age group. More than half (58.8%) of the participants were female.

Table 1.

Sociodemographic characteristics and clinical profiles of study participants with DVT at selected hospitals in Addis Ababa, July 1, 2017 to July 1, 2020

Characteristics Frequency Percent
Age (years) 18–35 116 28.4
36–50 143 35.1
≥ 51 149 36.5
Sex Male 168 41.2
Female 240 58.8
Sites of DVT Lower limb 389 95.3
Upper limb 6 1.5
Both lower and upper limbs 13 3.2
DVT types Proximal 165 40.4
Distal 11 2.7
Both 232 56.9
DVT involved limb Unilateral 321 78.7
Bilateral 87 21.3
Sign and symptoms at presentation Pain 408 100.0
Swelling 408 100.0
Pitting edema 318 77.9
Skin discoloration 233 57.1
Local tenderness 219 53.7
Risk factors for DVT Recent immobilization 122 29.9
Previous surgery 112 27.5
Active cancer 86 21.1
Previous VTE 84 20.6
Presence of infection 80 19.6
Pregnancy 64 15.7
Obesity 54 13.2
Age > 75 33 8.1
Heart failure 23 5.6
Stroke 18 4.4
Prior history of trauma 17 4.2
Genetics 9 2.2
Unprovoked 94 23.0
Comorbidity 204 50.0
Hypertension 124 30.4
Prior history of surgery 74 18.1
Types of surgery Abdominal 41 55.4
Orthopedic 17 23.1
Brain 6 8.1
ENT 5 6.8
Cardiac 3 4.1
Breast 2 2.7
Cancer 62 15
Types of cancers Breast 18 29.0
Ovarian 17 27.4
Cervical 12 19.4
Rectal 10 16.1
Other * 5 8.0
RVI 59 14.4
Diabetes mellitus 48 11.8
HF 21 5.1
Dyslipidemia 13 3.2
Stroke 12 2.9
CLD 11 2.6
AF 3 0.7
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*Lung, colorectal and liver cancer; AF, atrial fibrillation; CLD, chronic liver disease; DVT, deep vein thrombosis; ENT, eye, nose and throat; HF, heart failure; RVI, retroviral infection

The majority of DVT patients reported had lower limb thrombosis (95.3%), followed by unilateral (78.7%) and proximal DVT (40.4%). Regarding the presence of signs and symptoms, more than three-fourths of the studied patients had pitting edema, and all the studied patients experienced pain and swelling. Among the risk factors for DVT, immobilization was associated with 29.9% of the patients, surgery was associated with 27.5% of the patients, and the other risk factors were summarized. The most commonly reported comorbid diseases were hypertension (30.4%), diabetes mellitus (11.8%), retroviral infection (11.4%), and malignant diseases (62, 15%). Breast cancer was the most common cancer, accounting for 29% of the malignant cases, followed by ovarian, cervical, rectal and liver cancers. 18% of the participants had a prior history of surgery (Table 1).

The majority of the study participants were taking warfarin (79.4%), along with either unfractionated heparin (80.8%) or enoxaparin (19.1%), and the rest were taking rivaroxaban (20.6%). All of the study participants were on anticoagulants. Among a total of 408 DVT patients, 204 had comorbid conditions and were taking concurrent medications. The majority of these patients were taking antibiotics, followed by cardiovascular, vitamin K, and antidiabetic drugs, as shown in Table 2.

Table 2.

Anticoagulants and other medications used for the management of DVT and comorbidities at selected hospitals in Addis Ababa, July 01, 2017 - July 01, 2020

Anticoagulants medications Frequency Percent
Warfarin 324 79.4
Heparin 262 80.8
Enoxaparin 62 19.1
Rivaroxaban 84 20.6
Antibiotics 55 13.5
Calcium channel blockers 43 10.5
ACE inhibitors 33 8.1
Vitamin K 30 7.4
Statins 29 7.1
Beta blockers 24 5.9
Anti-diabetics 23 5.6
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ACEI: Angiotensin Converting Enzyme Inhibitor

The following table presents the bleeding status of the DVT patients. The results showed that 42 (10.0%) patients had a history of bleeding, and 19 (4.7%) had major bleeding (Table 3).

Table 3.

Bleeding status of the study participants according to the International Society on Thrombosis and Hemostasias guidelines at selected hospitals in Addis Ababa, July 01, 2017 - July 01, 2020

Variables Frequency Percent
Bleeding during follow up 42 10.0
Patients with major bleeding 19 4.7
Subjective finding of bleeding (n = 28) Nose bleeding 11 39.3
Active vaginal bleed 6 21.4
GI bleeding 4 14.3
Gum bleeding 3 10.7
Hematuria 3 10.7
Urethral bleeding 1 3.6
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GI: Gastrointestinal tract

According to our study findings, the incidence of recurrent DVT was 22.5%, and the majority of patients experienced two recurrences of DVT (20.1%). After treatment with anticoagulants, 17.9% of patients were completely resolved, 10% worsened, and 2.2% died. Approximately one-fifth (19.9%) of the study participants developed complications, and PE accounted for 44.4%, followed by PTS and chronic vein insufficiency (Table 4).

Table 4.

DVT treatment outcomes at selected hospitals in Addis Ababa, July 01, 2017 - July 01, 2020

Variables Frequency Percent
Patient develops recurrent DVT 92 22.5
Number of recurrent DVT Two 82 20.1
Three 8 2.0
Five 2 0.5
Time of recurrence (year) < 1 21 22.8
1–3 35 38
3–5 20 21.7
> 5 16 17.4
Current status of DVT Improved 210 51.5
No change 75 18.4
Complete resolution 73 17.9
Prophylaxis after complete resolution (n = 73) 20 27.4
Worsened 41 10.0
Death 9 2.2
Cause of death RF secondary to massive PE 4 44.4
RF secondary to acute PE 2 22.2
Others* 3 33.3
Developed complication 81 19.9
Types of complication PE 36 44.4
PTS 31 38.3
Chronic venous insufficiency 14 17.3
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*Bleeding secondary to supra-INR, RF secondary to PE + septic shock and UGIB & hypoxia secondary to CLD; PE: pulmonary embolism, PTS: post thrombotic syndrome, RF: respiratory failure, UGIB: upper gastrointestinal bleeding, DVT: deep venous thrombosis

Predictors of recurrent DVT

The results of the multivariate logistic regression analysis showed that bilateral DVT, obesity, hypertension and the RVI were significantly associated with DVT recurrence. Accordingly, participants with bilateral DVT had a 2.8-fold greater likelihood of recurrence than did participants with unilateral DVT (AOR = 2.8, 95% CI = 1.14, 6.66), and obese participants had a 3.3-fold greater likelihood of recurrence than did participants with a normal body mass index (AOR = 3.3, 95% CI = 1.15, 9.59). Participants with hypertension had a 6.5-fold greater recurrence of DVT than did nonhypertensive patients (AOR = 6.5, 95% CI = 2.90, 14.70), while RVI patients had a 6.3-fold greater recurrence of DVT than did their counterparts (AOR = 6.3, 95% CI = 2.34, 16.94) (Table 5).

Table 5.

Multivariate binary logistic regression analysis of predictor factors for DVT recurrence among study participants at selected hospitals in Addis Ababa, July 01, 2017 - July 01, 2020

Variables Recurrence DVT COR (95%CI) AOR (95% CI) P value
Yes (%) No (%)
Age category 18–35 15(8.6) 101(91.4) Reference
36–50 41(28.7) 102(71.3) 2.7(1.41, 5.19) 1.5(0.59, 3.84) 0.383
>=51 36(24.2) 113(75.8) 2.1(1.11, 4.15) 0.79(0.29,2.17) 0.652
Gender Male 25(14.9) 143(85.1) Reference
Female 67(28.0) 173(72.0) 2.2(1.33, 3.69) 0.59(0.28, 1.25) 0.171
Types of DVT Unilateral 43(13.6) 278(86.6) Reference
Bilateral 49(56.3) 38(43.7) 8.3(4.89, 14.19) 2.8(1.14, 6.66) 0.024*
Local tenderness Yes 56(25.6) 163(74.4) 1.5(0.91, 2.34) 0.64(0.32, 1.29) 0.218
No 36(19.1) 153(80.9) Reference
Presence of infection Yes 48(60.0) 32(40.0) 9.7(5.59, 16.76) 1.2(0.37, 2.92) 0.944
No 44(13.4) 284(86.6) Reference
Obesity Yes 37(68.5) 17(31.5) 11.8(6.22, 22.49) 3.3(1.15, 9.59) 0.027*
No 55(15.6) 299(84.4) Reference
Previous surgery Yes 46(41.1) 66(58.9) 3.8(2.32, 6.19) 0.68(0.27, 1.68) 0.410
No 46(15.6) 250(84.4) Reference
Recent immobilization Yes 48(30.4) 74(60.6) 3.6(2.19, 5.79) 0.94(0.42, 2.15) 0.893
No 44(16.4) 242(84.6) Reference
Hypertension Yes 65(52.4) 59(47.6) 10.5(6.17, 17.82) 6.5(2.90, 14.70) 0.000*
No 27(9.5) 257(90.5) Reference
Retroviral infection Yes 46(79.3) 12(20.7) 23.3(11.69,46.44) 6.3(2.34, 16.94) 0.000*
No 46(13.2) 303(86.8) Reference
Heparin use Yes 55(20.0) 220(80.0) Reference
No 37(28.4) 96(71.6) 1.5(0.95, 2.49) 0.70(0.34, 1.46) 0.345
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*p value < 0.05; DVT: deep venous thrombosis, INR: international normalized ratio, COR: crude odds ratio, AOR: adjusted odds ratio, CI: confidence interval

Predictors of major bleeding

In addition, the strength of the association between the independent variable and major bleeding was alsomeasured using a 95% confidence interval and odds ratio. Accordingly, DVT type, the presence of active cancer and age older than 75 years were associated with major bleeding according to multivariable logistic regression analysis.

Patients with bilateral DVT had a 3.9-fold increase in major bleeding compared with patients with unilateral DVT (AOR = 3.9, 95% CI = 1.6, 9.7), and participants with active cancer disease had a 6.5-fold increase in major bleeding compared with those with no active cancer (AOR = 6.5, 95% = 2.9, 14.75). Participants aged >75 years had a 6.8-fold greater incidence of major bleeding than did those aged younger than 75 years (AOR = 6.8, 95% CI = 2.03, 22.33) (Table 6).

Table 6.

Multivariate binary logistic regression analysis of predictors associated with major bleeding at selected hospitals in Addis Ababa, July 01, 2017 - July 01, 2020

Variables Major bleeding COR (95%CI) AOR (95% CI) P value
Yes (%) No (%)
Gender Male 14(8.3%) 154(91.7) Reference
Female 28(11.7%) 212(88.3) 1.5(0.74, 2.85) 0.821(0.35, 1.94) 0.653
Types of DVT Unilateral 16(4.4%) 305(95.6) Reference
Bilateral 26(29.9%) 61(70.1) 8.1(4.11, 16.05) 3.94(1.6, 9.701) 0.003*
Pitting edema Yes 35(11%) 283(89.0) 1.5(0.63, 3.42) 0.74(0.26, 2.13) 0.573
No 7(7.8%) 83(92.2) Reference
Active cancer Yes 28(32.6%) 58(67.4) 10.6(5.27, 21.39) 6.54(2.90, 14.75) 0.000*
No 14(4.3%) 308(95.7) Reference
Diabetes mellitus Yes 18(47.5%) 30(62.5) 8.4(4.10, 17.19) 1.4(0.42, 4.70) 0.577
No 24(6.7%) 336(93.3) Reference
Age > 75 years Yes 19(57.6%) 14(42.4) 20.7(9.25, 46.64) 6.8(2.03, 22.93) 0.002*
No 23(6.1%) 352(93.9) Reference
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*p value < 0.05, DVT: deep venous thrombosis, COR: crude odds ratio, AOR: adjusted odds ratio, CI: confidence interval

Discussion

The current study investigated the incidence and predictors of recurrent DVT in three selected tertiary hospitals in Addis Ababa, Ethiopia. A higher rate of recurrent DVT was reported, accounting for 22.5%. Nine participants (2.2%) died, and 19.9% of patients developed complications. PE accounted for 44.4% of these complications, followed by PTS and chronic vein insufficiency. Forty-two participants (10%) experienced bleeding episodes, and 4.7% of the participants experienced major bleeding.

Among the signs and symptoms, pain and general swelling manifested in all patients. Similar findings were reported in Ethiopia and Hong Kong [6, 17]. Unilateral limb involvement was observed in 78.7% of the patients. A higher percentage of unilateral involvement was also previously reported in Addis Ababa [18]. Our study also showed that the majority of the patients (95.3%) had DVT in their lower limbs, which is in line with a study performed in Zambia [19] and Hong Kong [17].

Our findings showed that the most common causes of DVT were a longer hospital stay (immobilization) (29.9%), previous surgery (27.5%), active cancer (21.1%), previous VTE (20.6%), acute infection (19.6%), pregnancy (15.7%), heart failure (5.6%), prior history of trauma (4.2%), presumed genetic disorders (2.2%) and age ≥ 75 years (8.1%), while the remaining 23% had unprovoked DVT. According to a previous study performed in Addis Ababa [18], the most commonly noted causes of DVT were malignancy of any kind (30.9%) and prolonged immobilization (19.8%). The difference may be that the current study was a multicenter study. Likewise, a study from America [1] reported that cancer was also a common comorbid condition, affecting 36.4% of all patients, while recent immobility and/or injury were found in 41.9% of the cohort and 22.8% of patients with the event classified as unprovoked. The finding of unprovoked risks was similar to our findings. In contrast, a study in Nigeria [20] showed that only 2% were unprovoked. This variation might be due to the smaller sample size used in the Nigerian study.

The incidence of recurrent DVT was 22.5%, and the majority of patients experienced two recurrences of DVT (20.1%). This finding was comparable to those of previous studies performed in Ethiopia [6] and the USA [21], which reported DVT recurrence rates of 26.4% and 26.1%, respectively. However, a lower incidence of recurrent DVT has been reported elsewhere [22]. The variation might be attributed to methodological differences and patient care disparities in various settings.

The results of the multivariate logistic regression analysis showed that bilateral DVT, obesity, hypertension and RVI were significantly associated with DVT recurrence. In our study, the odds of recurrent DVT were 6.5 times greater among patients with hypertension than among patients without hypertension. Similarly, hypertension was a predictor of recurrent DVT in a meta-analysis [23]. This could be explained by elevated blood pressure causing damage to venous valves, resulting in obstruction of blood vessels [24], and hypertension can also be associated with hypercoagulability [25].

In addition, the odds of developing recurrent DVT among people living with HIV (PLWH) were 6.3 times greater than those among their counterparts. A similar finding was also reported in the Netherlands, where the risk of recurrent VTE was elevated in PLWH compared to controls [26]. HIV-associated immunosuppression, opportunistic infections, malignancies and coagulopathy abnormalities contribute to an increased risk of recurrent DVT [27].

Our findings revealed that bilateral DVT was associated with a 2.8-fold increase in recurrent DVT. Similarly, a report from Qatar revealed that bilateral DVT predisposes patients to recurrent DVT [28].

The risk of recurrent DVT among obese patients was 3.3 times greater than that among nonobese patients. Similar findings were reported elsewhere [23, 29]. Although the pathophysiologic mechanisms underlying the contribution of obesity to recurrent DVT have not been fully explained, several speculated factors might play a role. Obesity may be associated with a prothrombotic state characterized by increased levels of procoagulant factors and decreased levels of anticoagulant factors [30].

Our study revealed that 9 (2.2%) of the participants died during the study period. The most common complication causing death was PE. This was comparable to that observed in the Worcester Venous Thromboembolism Study [7], where patients who presented with PE had a significantly greater overall death rate than those who presented with isolated DVT. In addition, Labropoulos et al. reported an association between PE and death [21].

Our data showed that 19.9% of patients developed complications, 44.4% of whom developed PE, 38.3% of whom developed PTS, and 17.3% of whom experienced chronic vein insufficiency. The CDC reported that 33–50% of people who have experienced DVT will experience long-term complications (post thrombotic syndrome), which include swelling, pain, discoloration, and scaling in the affected limb [31]. A study from Sweden showed that 26% of the study population developed PTS, 12% recurrent DVT, and 9% PE [32].

Our findings revealed that 4.7% of patients experienced major bleeding. Similar results were reported for Sweden (4.0%) [33] and Denmark (6.6%) [34]. The type of DVT (bilateral DVT), presence of active cancer and age above 75 years were associated with major bleeding. The likelihood of developing major bleeding among patients with bilateral DVT was 3.9 times greater than that among patients with unilateral DVT. This finding could be partly explained by the fact that bilateral DVT can cause major bleeding due to the extensive clot burden and the disruption of blood vessels [35], and intensive anticoagulation therapy further increases the risk of bleeding [36]. Participants with active cancer had a 6.5-fold increase in major bleeding. This finding is in line with a study from Japan [37]. This is explained by the complex nature of the pathophysiology of cancer and associated chemotherapy-induced bleeding [38]. Participants aged more than 75 years had a 6.8-fold increased risk of major bleeding. This was supported by another study performed in Italy [39].

Some investigations, including ours, have indicated that an age greater than 75 years is related to an increased risk of bleeding; hence, this parameter has been incorporated in the calculation of bleeding risk scores [39, 40]. Similar findings were reported elsewhere [41, 42], indicating that old age is a contributing factor to the risk of bleeding. This might be due to risk factors such as cancer, stroke, heart failure, immobilization, and a history of VTE, which are more common in the elderly population and contribute to a greater incidence of bleeding events [33].

In resource limited settings, the management and follow-up of DVT present unique challenges. Initial management typically involves intensive anticoagulant therapy, such as low molecular weight heparin or direct-acting oral anticoagulants, although access to these medications is limited. Follow-up care often relies on outpatient clinics, where patients may face barriers to regular attendance due to distance, transportation costs, or competing socioeconomic interests. These challenges contribute to suboptimal adherence to treatment and monitoring protocols, increasing the risk of recurrence and complications. Moreover, lack of specialty care facilities and trained health professionals may hinder the diagnosis and management of DVT complications, such as bleeding events. The implications of these systemic challenges are significant, potentially exacerbating the burden of recurrent and complications of DVT. Efforts to address these issues should prioritize improving access to essential medications, enhancing healthcare infrastructure, and support patient adherence and follow-up care.

This research employed a larger sample size in multiple study settings than did previous studies in Ethiopia. We aimed to incorporate key outcomes of DVT, including recurrence, mortality, complications, major bleeding, and predictive factors for recurrence and major bleeding, which have not been thoroughly examined in prior studies. However, our study is not without limitations. Since it is a retrospective study, it is predisposed to recall bias. We encountered instances of incomplete recording by providers or insufficient information regarding relevant findings, such as subjective bleeding assessments being unavailable in many cases. Additionally, most of the data associated with the INR were not recorded. Despite these limitations, our study provides valuable insights and offers important recommendations for future research and clinical practice.

Conclusions

In the current study, the overall DVT recurrence rate was 22.5%, which was complicated by PE, PTS and chronic vein insufficiency, resulting in 2.2% death. Major bleeding rates after DVT and PE remain high. Efforts are needed to identify patients who are most at risk for VTE complications, and developing better anticoagulation strategies that are suitable for long-term use is crucial for better patient treatment outcomes. Close monitoring should be performed for patients with advanced age, active cancer, bilateral DVT, RVI, obesity and hypertension to prevent the recurrence of DVT and major bleeding.

Acknowledgements

We would like to thank Tikur Anbessa Specialized Hospital, St. Peter Specialized Hospital, St. Paul’s Hospital Millennium Medical College and Zewditu Memorial Hospital and staff members for their cooperation and permission to conduct this study. We would also like to express our appreciation to the data collectors.

Abbreviations

DOAC

Direct oral anticoagulant

DVT

Deep vein thrombosis

INR

International normalized ratio

LMWH

Low-molecular-weight heparin

NOAC

Nonvitamin K antagonist oral anticoagulants

PE

Pulmonary embolism

PT

Prothrombin time

PTS

Post thrombotic syndrome

RVI

Retroviral infection

VTE

Venous thromboembolism

VKA

Vitamin K-Antagonist

Author contributions

SB and AMB were involved in the inception and methodology of the study and data curation.SB, MGB, FT, and AMB validated, analyzed, wrote and edited the draft manuscript.All authors reviewed the manuscript.All authors have read and agreed to the published version of the manuscript.

Funding

This research received no external funding.

Data availability

No datasets were generated or analysed during the current study.

Declarations

Ethics approval and consent to participate

Ethical approval was obtained from the Ethical Review Committee (ERC) of School of Pharmacy, Addis Ababa University (Ref; ERB/SOP/266/13/2021) and the Institutional Review Board (IRB) of St Paul Hospital Millennium Medical College (Ref; P423/389). The study was conducted according to the Declaration of Helsinki. This study utilized secondary data collected from medical records of study participants for the purpose of evaluating the outcomes DVT management and its predictors. The data utilized in this study are anonymized, and thus do not contain any personally identifiable information that could compromise the privacy or confidentiality of participants.

Consent for publication

Not applicable.

Competing interests

The authors declare no competing interests.

Footnotes

The original version of this article was revised: “Author comment during proofing has been delete from the article”.

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Change history

7/31/2024

A Correction to this paper has been published: 10.1186/s12959-024-00639-y

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