Pediatric malignancies: Is the prechemotherapy left ventricular function normal?

Management and Experiences in Diagnosing and Treating Acute Heart Failure in Children with Solid Tumors

Acute heart failure is a critical and life-threatening complication that occurs during the treatment of solid tumors in children. It has a high mortality rate, poses treatment challenges, and also affects the overall prognosis of tumor treatment. Currently, there are limited clinical diagnostic and treatment data in this area. To understand the characteristics and outcomes of acute heart failure in children with solid tumors during the treatment process, share treatment experiences, and provide management strategies for monitoring, treatment, and prevention. Five representative cases of children with solid tumors were selected to summarize the clinical features, auxiliary examination data, individualized treatment plans, and treatment effects during the occurrence of acute heart failure. The possible triggers and time points for the onset of acute heart failure in children with solid tumors were analyzed, along with treatment responses and influencing factors. All five cases of children with solid tumors exhibited symptoms of acute heart failure after chemotherapy, with heart functions staging from class II to class IV. Most cases occurred during the bone marrow suppression period after chemotherapy, with a noticeable increase in heart rate during the early stages of heart failure. Those using anthracycline drugs did not reach the internationally recommended maximum cumulative dose. Two children with heart function class IV altered their tumor treatment plans to completion, and one child with heart function class IV and concurrent renal dysfunction had chemotherapy interrupted. All children received oral anti-heart failure treatment and nutritional myocardial therapy. Two children with heart function class II returned to normal after oral medication; three children with heart function class IV received intravenous vasoactive agents during the acute phase of heart failure, followed by regular reinforcement in the later stage. The heart function improved in all three cases (heart function class IV), with one case returning to normal, one case with slow recovery in non-compaction cardiomyopathy gradually approaching normalcy, and one case with only mild improvement in heart function despite concurrent renal dysfunction. Children with solid tumors are susceptible to acute heart failure during the bone marrow suppression period and an increased heart rate serves as an early warning signal. Active anti-heart failure treatment is effective. For severe cases, regular intravenous administration of vasoactive agents during the maintenance period can promote the recovery of heart function, with renal dysfunction emerging as a significant factor influencing poor recovery of heart function.

Cancer-Induced Resting Sinus Tachycardia: An Overlooked Clinical Diagnosis

Elevated resting heart rate is frequently observed in cancer patients, and is associated with increased mortality. Although specific chemotherapeutic agents can induce cardiotoxicity, the presence of sinus tachycardia in chemotherapy-naive patients suggests other factors likely contribute to this clinical presentation. Despite its prevalence, cancer-associated resting sinus tachycardia has not been fully recognized and comprehensively described as a separate clinical entity. Secondary effects of cancer, especially structural cardiac changes, secretory factors (inflammatory cytokines), and thromboembolic disease can cause resting tachycardia. Alternatively, rapid heart rate may reflect compensatory mechanisms responding to increased metabolic demands, raised cardiac output states, and even pain. Hence, cancer-associated tachycardia presents a clinical dilemma; acute life-threatening conditions (such as sepsis, pulmonary embolism, etc.) must be ruled out, but cancer itself can explain resting sinus tachycardia and more conservative management can avoid unnecessary testing, cost and patient stress. Furthermore, identification and management of cardiac conditions associated with cancer may improve survival and the quality of life of cancer patients.

Assessment of left heart dysfunction to predict doxorubicin cardiotoxicity in children with lymphoma

Objectives

The objectives of this study were to assess the changes in the left myocardial function after chemotherapy for childhood lymphoma and observe the predictive or monitor value for cancer treatment-related cardiac dysfunction (CTRCD) by speckle-tracking echocardiography.

Methods

A total of 23 children with histopathological diagnoses of lymphoma were included, with age-matched normal controls. Comparative analysis of clinical serological tests and left heart strain parameters in children with lymphoma, including left ventricular global longitudinal strain (LVGLS); global myocardial work (GMW) indices, which include global work index (GWI), global constructive work (GCW), global wasted work, and global work efficiency; and the LS of subendocardial, middle, and subepicardial layer myocardium during left ventricular systole were measured: left atrial strain of reservoir phase (LASr), left atrial strain of conduit phase (LAScd), and left atrial strain of contraction phase (LASct).

Results

One-way ANOVA showed that GLS, GWI, GCW, LASr, and LAScd were closely associated with CTRCD and multivariate logistic regression analysis showed that GLS was the most sensitive predictor for detecting patients at lofty risk of anthracycline-related cardiotoxicity. Both before and after chemotherapy, GLS in the left ventricle showed a pattern of basal segment < middle segment < apical segment and subepicardial < middle < subendocardial layer (p < 0.05), and the degree of decrease also showed a regular pattern of epicardial layer < middle layer < subendocardial layer while the difference was not significant (p > 0.05). After chemotherapy, maximum flow rate in early mitral relaxation/left atrial systolic maximum flow rate (E/A) and left atrial volume index of each group were in the normal range, and the values of LASr, LAScd, and LASct slightly increased in the second cycle and decreased significantly in the fourth cycle after chemotherapy, reaching the lowest level; LASr and LAScd were positively correlated with GLS.

Conclusion

LVGLS is a more sensitive and earlier indicator to predict CTRCD compared with conventional echocardiography-related parameters and serological markers, and GLS of each myocardial layer showed a certain regularity. Left atrial strain can be used for early monitoring of cardiotoxicity in children with lymphoma after chemotherapy.

Effect of Active Cancer on the Cardiac Phenotype: A Cardiac Magnetic Resonance Imaging-Based Study of Myocardial Tissue Health and Deformation in Patients With Chemotherapy-Naïve Cancer

Background

The overlap between cancer and cardiovascular care continues to expand, with intersections emerging before, during, and following cancer therapies. To date, emphasis has been placed on how cancer therapeutics influence downstream cardiac health. However, whether active malignancy itself influences chamber volumes, function, or overall myocardial tissue health remains uncertain. We sought to perform a comprehensive cardiovascular magnetic resonance‐based evaluation of cardiac health in patients with chemotherapy‐naïve cancer with comparison with a healthy volunteer population.

Methods and Results

Three‐hundred and eighty‐one patients with active breast cancer or lymphoma before cardiotoxic chemotherapy exposure were recruited in addition to 102 healthy volunteers. Both cohorts underwent standardized cardiovascular magnetic resonance imaging with quantification of chamber volumes, ejection fraction, and native myocardial T1. Left ventricular mechanics were incrementally assessed using three‐dimensional myocardial deformation analysis, providing global longitudinal, circumferential, radial, and principal peak‐systolic strain amplitude and systolic strain rate. The mean age of patients with cancer was 53.8±13.4 years; 79% being women. Despite similar left ventricular ejection fraction, patients with cancer showed smaller chambers, increased strain amplitude, and systolic strain rate in both conventional and principal directions, and elevated native T1 versus sex‐matched healthy volunteers. Adjusting for age, sex, hypertension, and diabetes mellitus, the presence of cancer remained associated with these cardiovascular magnetic resonance parameters.

Conclusions

The presence of cancer is independently associated with alterations in cardiac chamber size, function, and objective markers of tissue health. Dedicated research is warranted to elucidate pathophysiologic mechanisms underlying these findings and to explore their relevance to the management of patients with cancer referred for cardiotoxic therapies.

Left ventricular mechanics in patients with hematological malignancies before initiation of chemo- and radiotherapy

Objective We sought to investigate left ventricular (LV) structure, function and mechanics in the patients with leukemia and lymphoma before initiation of chemotherapy, as well as the relationship between hematological malignancies and reduced LV longitudinal strain. Methods This retrospective investigation included 71 patients with leukemia and lymphoma before chemotherapy and 36 healthy controls. All participants underwent echocardiographic examination before initiation of chemotherapy and radiotherapy. Results LV global longitudinal strain (- 20.2 ± 1.7% vs. - 17.9 ± 3.0%, p < 0.001) was significantly lower in the patients with hematological malignancies than in controls. There was no difference in LV circumferential and radial strains between two observed groups. Subendocardial and subepicardial longitudinal strains were significantly lower in the patients with hematological malignancies (- 20.5 ± 3.6% vs. - 22.5 ± 3.8%, p = 0.001 for subendocardial strain; - 18.0 ± 1.5% vs. - 15.8 ± 2.6%, p < 0.001 for subepicardial strain). Hematological malignancies were associated with reduced global LV longitudinal strain (OR 21.0; 95%CI 2.04-215.0, p = 0.010) independently of age, gender, heart rate, body mass index, left ventricular ejection fraction, left ventricular mass index, and glucose level. Conclusions LV longitudinal strain was impaired in the patients with leukemia and lymphoma even before initiation of chemotherapy. Endocardial and epicardial LV layers are equally affected in the patients with hematological malignancies. Newly diagnosed hematological malignancies were related with reduced LV global longitudinal strain independently of common clinical and echocardiographic parameters.