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Bioscience Journal  Original Article 

Biosci. J., Uberlândia, v. 36, n. 6, p. 2281-2287, Nov./Dec. 2020 
http://dx.doi.org/10.14393/BJ-v36n6a2020-48129 

SEVERE CARDIAC INSUFFICIENCY SECONDARY TO CARDIOTOXICITY 
WITH CLINICAL AND MORPHO-FUNCTIONAL IMPROVEMENT AFTER 

OPTIMISED CLINICAL TREATMENT: CASE REPORT 
 

INSUFICIÊNCIA CARDÍACA GRAVE SECUNDÁRIA A CARDIOTOXICIDADE COM 
MELHORA CLÍNICA E MORFO-FUNCIONAL APÓS TRATAMENTO CLÍNICO 

OTIMIZADO: RELATO DE CASO 
 
Pedro Ribeiro ROSA1; Igor Mychael Melo FERREIRA1; Guilherme Silva de MENDONÇA2*; 

Fábio Vieira FERNANDES1; Rodrigo Penha de ALMEIDA3; Elmiro Santos RESENDE4;  
João Lucas O'CONNELL5 

1. Federal University of Uberlândia, Faculty of Medicine, Uberlândia, MG, Brasil; 2. Federal University of Uberlândia, Faculty of 
Medicine, Uberlândia, MG, Brasil; 3. Federal University of Uberlândia, Faculty of Bioengineering, Uberlândia, MG, Brasil; 4. Federal 

University of Uberlândia, Faculty of Medicine, Uberlândia, MG, Brasil; 5. Federal University of Uberlândia, Faculty of Medicine, 
Uberlândia, MG, Brasil. guilherme.silva@ufu.br 

 
ABSTRACT: Many therapies used for cancer (pathology whose cases are progressively increasing in 

the world) such as chemotherapy and radiotherapy have numerous adverse effects, with cardiotoxicity being 
one of the most important. This can be defined from the detection, by an imaging method, of a reduction of at 
least 10% in the left ventricular ejection fraction (LVEF), bringing it to a value below 53%. Anthracyclines 
(such as Doxorubicin), Trastuzumab, and Taxanes (Docetaxel) are among the most associated 
chemotherapeutics. To emphasize the importance of optimized treatment for heart failure and to review the 
main updates on the theme of cardiotoxicity. Case report and bibliographic review on the latest updates to the 
management of cardiotoxicity and associated heart failure. When correctly identifying the main risk factors 
associated with chemotherapy and the individual to develop myocardial injury, it is possible to perform the 
monitoring by means of two main predictors: the myocardial tension strength and the biomarkers. In this sense, 
changes associated with these predictors may allow early intervention through appropriate treatment and, with 
the advancement of research, even prevention, mainly using the association of Carvedilol with Enalapril. 
Continuous monitoring and early initiation of drug therapy for heart failure are clearly associated with a lower 
degree of myocardial injury and a lower rate of complications. In addition, there is still an increasingly 
promising possibility in relation to preventive drug therapy, however, there is still a lack of studies on this 
topic.  

  
KEYWORDS: Cardiac Insufficiency. Early detection. Chemotherapy. Biomarkers.   
 

INTRODUCTION 
 
Over recent years, there has been a noted 

progressive increase in the number of neoplasia 
cases around the world (SIEGEL; MILLER; 
JEMAL, 2016). Many therapies used to treat cancer 
have adverse side effects, with cardiotoxicity being 
one of their worst side effects. According to the 
American Society of Echocardiography and the 
European Association of Cardiovascular Imaging, 
cardiotoxicity due to chemotherapeutic drugs is 
defined by the detection, using an imaging method, 
of a reduction of 10% (or more) in the left 
ventricular ejection fraction (LVEF) and reaching 
below 53% as a result (PLANA et al., 2014). 
Chemotherapeutic drugs, such as Anthracyclines (i.e 
Doxorubicin), Trastuzumab, and Taxanes 
(Docetaxel), for example, are among those most 

associated with toxic actions that affect the cardiac 
muscle (PLANA et al., 2014).  

This article aims to briefly describe the 
reported case of a patient that exhibited an 
exuberant clinical condition of CI, where the 
appearance of an important ventricular dysfunction 
was documented following breast cancer treatment, 
but presenting good clinical and ventricular function 
recovery years after classic CI treatment. In 
addition, it aims to review the main updates on the 
topic. 

 
MATERIAL AND METHODS 

 
In this sense, a review of medical records 

was carried out, as well as the monitoring of the 
patient's clinical history, to highlight the outcomes 
of therapy. In addition, a brief review was made, 
associating the theme to the case described, on 

Received: 01/04/2019 
Accepted: 30/01/2020 



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conduct related to the monitoring, prevention and 
treatment of cardiotoxicity. 

This article was submitted and approved by 
the Research Ethics Committee, CAAE nr 
29825819.1.0000.5152 - Opinion Number: 
4.037.581, with the patient in this case authorizing 
its publication after signing an informed consent 
form (ICF).  

 
CASE STUDY 

 
Female patient, currently 61 years old, was 

diagnosed with malign breast neoplasia (T3N0M0) 
in 2008 (10 years ago) (AJCC, 2017). She 
underwent four cycles of chemotherapy with the use 
of Doxorubicin (in a total accumulated dose of 200 
mg/m2), followed by 35 cycles of conventional 
radiography (in a total accumulated dose of 55 Gy) 
until December 2009 (9 years ago).  

Before treatment, the patient was 
asymptomatic in regard to cardiovascular signs and 
symptoms, denying the existence of previous 
cardiovascular events or symptoms. She had 
performed an electrocardiogram and a thorax 
radiography, both of which were normal. The 
Doppler echocardiography assessment, performed 
before starting treatment, indicated a Left 
Ventricular End Systolic Volume (LVESV) = 60 ml 
(normal) and a Left Ventricular Ejection Fraction 
(LVEF) = 60%. The patient did not perform cardiac 
follow-up consultation; neither repeated the 
abovementioned exams during her treatment 
process.  

Three months after finishing the 
chemotherapeutical and radiological treatments (8 
years ago), the patient developed classic signs and 
symptoms of CI (dyspnoea, orthopnoea, nocturnal 
paroxysmal dyspnoea, lower limbs swelling, jugular 
swelling) up to functional class IV in accordance 
with the classification of the New York Heart 
Association (NYHA). The patient underwent four 
sequential hospitalisations aimed at clinical state 
compensation during a period of 6 months after 
diagnosis, with hospitalisations at Intensive Therapy 

Units being necessary during some of these 
decompensations. Another echocardiogram was 
performed (during the first hospitalisation), 
indicating diffuse and important VE hypokinesis, 
LVESV = 92ml, and LVEF = 21%, confirming left 
ventricular dysfunction. Throughout the four 
hospitalisations (during a 6 month period), there was 
some initial difficulty in optimising drug therapy for 
CI. Given the lack of initial clinical response, a 
referral to the cardiac transplant program was 
suggested. However, the patient sought a different 
medical team, which opted for trying once more a 
progressive optimisation of the drug therapy 
treatment with the use of classic drugs that act by 
promoting reverse cardiac remodelling.  

For the months and years following, the 
patient progressed with significant clinical 
improvement, currently (2018) being at a functional 
class I (NYHA). During this 8 year period there was 
also significant improvements in the morph 
functional parameters, according to an 
echocardiographic exam performed in 2018: 
LVESV = 48ml and LVEF = 71%. In addition, a 
progressive optimisation of the classic drugs used 
for CI treatment was achieved. Until recently, the 
patient was being treated with Carvedilol 25mg 
12/12h, Losartan 50mg 1212/h, Spironolactone 
25mg/day and Ivabradina 5mg 12/12h. As there had 
been significant clinical and echocardiographic 
improvements, high blood pressure episodes and 
questioning by the patient on the actual necessity of 
using all those drugs, the prescription was then 
modified, and as of today, the patient is being 
treated with Carvedilol 12,5mg 12/12h and Losartan 
25mg 12/12h. Baseline heart rate usually sits 
between 60 and 70 bpm and arterial pressure is kept 
at adequate levels.   

 
DISCUSSION 

 
There are two main types of cardiotoxicity 

described thus far: type I and type II. The following 
Frame deals with some of their respective 
characteristics. 

 
Tabela 1. Types of cardiac dysfunction related to chemotherapy (CDRC) and their respective characteristics 

 Type I Type II 
Distinctive agents Doxorubicin  Trastuzumab 

Clinical measures and 
typical response to anti 
remodelling therapy (beta-
blockers, ACE Inhibitor) 

In most cases, seems to be 
permanent or irreversible; The 
recurrence after some months or 
years can be related to sequential 
cardiac stress. 

High probability of recovery 
(for or near basal cardiac status) 
between 2 to 4 months after 
interruption. 

   
Dosage effects Accumulative Not related to dosage 



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Re-exposure  

High probability of 
dysfunction being progressive; can 
result in cardiac insufficiency or 
untreatable death. 

Growing evidence for the 
relative safety of re-exposure 
(additional data is necessary).  

   

Vacuoles; myofibrillar 
disorder; necrosis.   

Vacuoles; myofibrillar 
disorder; necrosis (the alterations are 
generally resolved with time).  

No apparent abnormality 
(although not having been entirely 
studied). 

Adapted from Ewer and Lippman (2005) 
 

Even though it describes the natural 
evolution of most patients subjected to the use of 
mainstream chemotherapeutic drugs, it is known 
that this classification system also has its 
exceptions. For example, in some cases in which the 
drug used is normally associated with Type I 
cardiotoxicity, even if a dysfunction is detected 
early on, with chemotherapy being rapidly 
suspended and ventricular dysfunction treatment 
started prematurely, a total regression of the 
dysfunction can still occur within a few months 
(CARDINALE et al., 2015).  

Every time the presence of risk factors 
associated with the development of cardiotoxicity 

are detected (more than 65 years of age, positive 
family history regarding cardiovascular related 
death, tobacco use, hypertension, diabetes, previous 
case of coronary or renal disease) aside from the 
risk factors associated with chemotherapy itself used 
in treatment (type and dosage of chemotherapeutic 
drug used) (ARMENIAN et al., 2016), the execution 
of adequate ventricular function monitoring should 
also be suggested. Besides these risk factors, the 
dosage and type of treatment used are also important 
concerning the possibility of occurring cardiac 
lesion, as evidenced on the frame below:  

 
Tabela 2. Higher risk of developing cardiotoxicity with a treatment that includes any of the following: 

High doses of anthracyclines (e.g., doxorubicin > 250mg/m2, epirubicin > 600mg/m2)  
High dose of radiotherapy (> 30Gy), when the heart is part of the radiotherapy treatment plan.  
- Low dosage of anthracyclines (e.g., doxorubicin 250mg/m2, epirubicin 600mg/m2) combined with a 

low dose of radiography (30Gy) when the heart is part of the radiotherapy treatment plan.  
 
- Treatment with a low dosage of anthracycline (e.g, doxorubicin, 250mg/m2, epirubicin, 600mg/m2) 

or trastuzumab on their own, and the presence of any of the following risk factors: two or more cardiovascular 
risk factors, including tobacco use, hypertension, diabetes, dyslipidaemia and obesity, during or after 
completing therapy.   

- Treatment with low doses of anthracycline (e.g., doxorubicin, 250mg/m2; epirubicin, 600mg/m2) 
followed by trastuzumab treatment.  
Adapted from Armenian et al. (2016) 

 
Due to its wide availability, safety, low cost 

and good applicability, trans-thoracic Doppler 
echocardiogram (ECHO) is the chosen method for 
cardiac monitoring and assessment (PLANA et al., 
2014).  

Even though considered the best monitoring 
parameter, ECHO – 2D presents an incapacity in 
detecting small LVEF variations (PLANA et al., 
2014). As such, two methods have recently come to 
attention for reaching this goal: the analysis of 
myocardial tension (calculated by measuring the 
“myocardial deformations”, analysing the Speckle-
Tracking echocardiography) (CURIGLIANO et al., 
2016) and the analysis of myocardial lesion 
biomarkers. Myocardial tension can be calculated 
by means of the normal echocardiographic 

technique, by comparing the global longitudinal 
strain (GLS) parameter to the echocardiogram. 
Notwithstanding having a good amount of recent 
and promising studies on the subject, some 
controversy persists, being based principally on the 
presence of variations depending on the quality of 
the detected image, on the machine used and on the 
machine operator (CURIGLIANO et al., 2016). 

Troponins are among the most used 
biomarkers. Its predictive value for cardiotoxicity 
was hinted at studies conducted, which evaluated 
patients with breast cancer treated with 
anthracyclines, taxanes and trastuzumab. Patients 
that had a high concentration of Troponins (> 
30pg/ml) were found to have a higher predisposition 
to develop breast cancer (p=0.04), with a specificity 



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of 73%. However, these are not yet used for 
defining conduct (SAWAYA et al., 2012). 

Drug treatment of cardiotoxicity by use of 
anthracyclines is based on the usual standard 
treatment for cardiac insufficiency. Thus, the drug 
choices at the time our patient started treatment 
were: inhibitors of angiotensin-converting enzyme 
II (IACE) or angiotensin II receptors blockers 
(ARB) in association with beta adrenergic blocking 
agents (BB). In other words, the treatment for this 
clinical state must prioritise drugs that work on 
cardiac remodelling (CARDINALE et al., 2010). 
Regarding the different drugs in the afore mentioned 
group, any IACE and ARB can be used. However, 
among the habitual BB, only carvedilol and 
nebivolol were tested and approved for this specific 
clinical state (CARDINALE et al., 2010). In a study 
conducted by Cardinale e et al (2010), a combined 
therapy of IACE (Enalapril) and BB (Carvedilol) 
administered between one month and two after 
chemotherapy with anthracyclines was administered 
in patients that exhibited cardiotoxicity with left 
ventricular dysfunction. In many of the cases (42%), 
there was a full recovery of LVEF. In 13% of the 
cases, there was partial recovery with an increase of 
10% in LVEF, but still maintained below 50%. 
Nonetheless, it should be highlighted that for those 
patients that started treatment late, partial recovery 
did not take place (CARDINALE et al., 2010).  

There has been frequent discussion in recent 
literature on the possibility of cardiovascular 
damage prevention in patients subjected to 
chemotherapeutic treatment. Among the therapeutic 
options, the drugs used most often for that end are: 
Dexrazoxane, therapy combined with IACE and BB, 
aldosterone antagonists, isolated BB, ARB and 
Statins. Many of these agents have even been 
associated to benefits such as LVEF preservation 
and reduced risks of cardiovascular events during 
therapy (PAYNE; NOHRIA, 2017). The two 
following studies sought to assess the effects of both 
combined and independent therapy in the 
prognostics of patients. In one study conducted by 
Bosch et al, carvedilol and enalapril were used in an 
effort to try and prevent myocardial aggression in 
patients with leukaemia and other haematopoietic 
malignancies in comparison with a placebo. In total, 
90 patients were studied, with 45 receiving 
combined therapy and another 45 patients 
constituting the control group. Before treatment, the 
selected patients did not exhibit left ventricular 
dysfunction. By the end, those patients that received 

combined therapy presented a lower death or 
cardiac insufficiency rate (6.7% vs 22%).  

Furthermore, lower rates of mortality, 
cardiac insufficiency or LVEF below 45% (6.7% vs 
24.4%) were also seen. After six months of 
monitoring, no major changes in the LVEF of the 
combined therapy group were detected, while in the 
control group a LVEF reduction was observed (-
3.8% on average, over the absolute value), with a 
difference of 3.4% (p < 0.04) between both groups 
(PAYNE; NOHRIA, 2017). On the other hand, in 
another study conducted by Gulati et al, the only 
drugs used were metropolol (BB) on its own, only 
candesartan (ARB) or metropol combined with 
candesartan and compared with placebo for 
preventing cardiac lesion in breast cancer patients 
being treated with anthracyclines, trastuzumab, 
taxanes, cyclophosphamides, radiotherapy and/or 5-
fluorouracil. A total of 120 patients were included in 
the analysis. The average LVEF of the groups 
before starting the chemotherapeutic treatment was 
over 60%. By the end of the monitoring process, a 
significant correlation between the use of ARB and 
a reduction in the fall of LVEF was observed. LVEF 
average reduction was of 2.6% in the placebo 
population, while in the ARB-treated population, 
this reduction was of around 0.8% (p=0.026). There 
was no correlation between the use of metoprolol 
and LVEF reduction10. Furthermore, asides from the 
hitherto exposed, there is currently a noticeable 
increase in research that associate practice with 
cardiotoxicity prevention (PAYNE; NOHRIA, 
2017).   

 
CONCLUSION  

 
The identification of patients at higher risk 

of developing cardiotoxicity, the periodic and 
routine monitoring of ventricular function after each 
chemotherapeutical treatment cycle, the use of 
medicaments that are able to promote the reduction 
of myocardial damage, the interruption (temporary 
or definitive) of anti-neoplastic treatment when 
recommended, and the prompt start to treatment 
with drugs that can prevent the worsening of cardiac 
remodelling are fundamental actions for reducing 
the occurrence of cardiotoxicity related to 
chemotherapeutical drugs. In addition, promising 
data is evident, especially in relation to the use of 
drug therapy as a prevention of cardiotoxicity. 
However, there is still a need for further studies to 
corroborate this prerogative. 

 



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Figure 1. Electrocardiogram (performed in 2013) showing Sinus Rhythm, Left Bundle Branch Block and 

unspecific Alterations of Ventricular Repolarisation.  
 

 
Figure 2. Chest x ray (performed in 2010) showing cardiomegaly and signs of pulmonary edema.  

 

 
Figure 3. Magnetic resonance during clinical treatment for Cardiac Insufficiency (after partial improvement of 

clinical condition).  
 



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Figure 4. Magnetic resonance during clinical treatment of ventricular dysfunction (after partial recovery of 

clinical condition). 
 

 
 
RESUMO: Muitas terapias utilizadas para o câncer (patologia cujos casos estão aumentando 

progressivamente no mundo) como a quimioterapia e a radioterapia possuem inúmeros efeitos adversos, sendo 
a cardiotoxicidade um dos mais importantes. Esta pode ser definida a partir da detecção, por um método de 
imagem, de uma redução de, pelo menos, 10% na fração de ejeção do ventrículo esquerdo (FEVE), levando a 
mesma para um valor inferior a 53%. As Antraciclinas (como a Doxorrubicina), o Trastuzumab, e os Taxanos 
(Docetaxel) estão entre os quimioterápicos mais associados. Enfatizar a importância do tratamento otimizado 
para insuficiência cardíaca e revisar sobre as principais atualizações do tema cardiotoxicidade. Relato de caso e 
revisão bibliográfica sobre últimas atualizações de condutas referentes ao manejo da cardiotoxicidade e 
insuficiência cardíaca associada. Ao se identificar corretamente os principais fatores de risco associados à 
quimioterapia e ao indivíduo para desenvolver a injúria miocárdica, é possível realizar o monitoramento por 
meio de dois preditores principais: a força de tensão miocárdica e os biomarcadores. Nesse sentido, alterações 
associadas a esses preditores podem permitir a intervenção precoce por meio do tratamento adequado e, com o 
avanço das pesquisas, até mesmo a realização da prevenção, principalmente utilizando-se a associação de 
Carvedilol com Enalapril. Monitorização contínua e início precoce da terapia medicamentosa para insuficiência 
cardíaca estão claramente associadas com um menor grau de injúria miocárdica e um menor índice de 
complicações. Além disso, ainda há a possibilidade cada vez mais promissora em relação à terapia 
medicamentosa preventiva, porém, ainda há carência de estudos em relação a este tema.  

 
PALAVRAS CHAVE: Biomarcadores. Detecção precoce. Insuficiência Cardíaca. Quimioterápicos.  
 
 

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