Efficacy and Safety of Indwelling Catheter for Malignant Pleural Effusions Related to Timing of Cancer Therapy: A Systematic Review

Introduction: To compare the efficacy and safety of indwelling pleural catheters (IPC) in relation with the timing of systemic cancer therapy (SCT) (i.e., before, during, or after SCT) in patients with malignant pleural effusion (MPE). Methods: Systematic review of randomized controlled trials (RCT), quasi-controlled trials, prospective and retrospective cohorts, and case series of over 20 patients, in which the timing of IPC insertion in relation to that of SCT was provided. Medline (via PubMed), Embase, and Cochrane Library were systematically searched from inception to January 2023. The risk of bias was assessed using the Cochrane Risk of Bias (ROB) tool for RCTs and the ROB in non-randomized studies of interventions (ROBINS-I) for non-randomized designs. Results: Ten studies (n=2907 patients; 3066 IPCs) were included. Using SCT while the IPC was in situ decreased overall mortality, increased survival time, and improved quality-adjusted survival. Timing of SCT had no effect on the risk of IPC-related infections (2.85% overall), even in immunocompromised patients with moderate or severe neutropenia (relative risk 0.98 [95%CI: 0.93–1.03] for patients treated with the combination of IPC and SCT). The inconsistency of the results or the lack of analysis of all outcome measures in relation to the SCT/IPC timing precluded drawing solid conclusions about time to IPC removal or need of re-interventions. Conclusions: Based on observational evidence, the efficacy and safety of IPC for MPE does not seem to vary depending on the IPC insertion timing (before, during, or after SCT). The data most likely support early IPC insertion. (AU)

Pulmonary Emphysema Regional Distribution and Extent Assessed by Chest Computed Tomography Is Associated With Pulmonary Function Impairment in Patients With COPD.

Objective: This study aimed to evaluate how emphysema extent and its regional distribution quantified by chest CT are associated with clinical and functional severity in patients with chronic obstructive pulmonary disease (COPD). Methods/Design: Patients with a post-bronchodilator forced expiratory volume in one second (FEV1)/forced vital capacity (FVC) < 0.70, without any other obstructive airway disease, who presented radiological evidence of emphysema on visual CT inspection were retrospectively enrolled. A Quantitative Lung Imaging (QUALI) system automatically quantified the volume of pulmonary emphysema and adjusted this volume to the measured (EmphCTLV) or predicted total lung volume (TLV) (EmphPLV) and assessed its regional distribution based on an artificial neural network (ANN) trained for this purpose. Additionally, the percentage of lung volume occupied by low-attenuation areas (LAA) was computed by dividing the total volume of regions with attenuation lower or equal to -950 Hounsfield units (HU) by the predicted [LAA (%PLV)] or measured CT lung volume [LAA (%CTLV)]. The LAA was then compared with the QUALI emphysema estimations. The association between emphysema extension and its regional distribution with pulmonary function impairment was then assessed. Results: In this study, 86 patients fulfilled the inclusion criteria. Both EmphCTLV and EmphPLV were significantly lower than the LAA indices independently of emphysema severity. CT-derived TLV significantly increased with emphysema severity (from 6,143 ± 1,295 up to 7,659 ± 1,264 ml from mild to very severe emphysema, p < 0.005) and thus, both EmphCTLV and LAA significantly underestimated emphysema extent when compared with those values adjusted to the predicted lung volume. All CT-derived emphysema indices presented moderate to strong correlations with residual volume (RV) (with correlations ranging from 0.61 to 0.66), total lung capacity (TLC) (from 0.51 to 0.59), and FEV1 (~0.6) and diffusing capacity for carbon monoxide DLCO (~0.6). The values of FEV1 and DLCO were significantly lower, and RV (p < 0.001) and TLC (p < 0.001) were significantly higher with the increasing emphysema extent and when emphysematous areas homogeneously affected the lungs. Conclusions: Emphysema volume must be referred to the predicted and not to the measured lung volume when assessing the CT-derived emphysema extension. Pulmonary function impairment was greater in patients with higher emphysema volumes and with a more homogeneous emphysema distribution. Further studies are still necessary to assess the significance of CTpLV in the clinical and research fields.

Influence of emphysema distribution on pulmonary function parameters in COPD patients / Influência da distribuição do enfisema nos parâmetros de função pulmonar em pacientes com DPOC

ABSTRACT OBJECTIVE: To evaluate the impact that the distribution of emphysema has on clinical and functional severity in patients with COPD. METHODS: The distribution of the emphysema was analyzed in COPD patients, who were classified according to a 5-point visual classification system of lung CT findings. We assessed the influence of emphysema distribution type on the clinical and functional presentation of COPD. We also evaluated hypoxemia after the six-minute walk test (6MWT) and determined the six-minute walk distance (6MWD). RESULTS: Eighty-six patients were included. The mean age was 65.2 ± 12.2 years, 91.9% were male, and all but one were smokers (mean smoking history, 62.7 ± 38.4 pack-years). The emphysema distribution was categorized as obviously upper lung-predominant (type 1), in 36.0% of the patients; slightly upper lung-predominant (type 2), in 25.6%; homogeneous between the upper and lower lung (type 3), in 16.3%; and slightly lower lung-predominant (type 4), in 22.1%. Type 2 emphysema distribution was associated with lower FEV1, FVC, FEV1/FVC ratio, and DLCO. In comparison with the type 1 patients, the type 4 patients were more likely to have an FEV1 < 65% of the predicted value (OR = 6.91, 95% CI: 1.43-33.45; p = 0.016), a 6MWD < 350 m (OR = 6.36, 95% CI: 1.26-32.18; p = 0.025), and post-6MWT hypoxemia (OR = 32.66, 95% CI: 3.26-326.84; p = 0.003). The type 3 patients had a higher RV/TLC ratio, although the difference was not significant. CONCLUSIONS: The severity of COPD appears to be greater in type 4 patients, and type 3 patients tend to have greater hyperinflation. The distribution of emphysema could have a major impact on functional parameters and should be considered in the evaluation of COPD patients.

RESUMO OBJETIVO: Avaliar o impacto que a distribuição do enfisema tem na gravidade clínica e funcional em pacientes com DPOC. MÉTODOS: A distribuição do enfisema foi analisada em pacientes com DPOC, que foram classificados de acordo com um sistema de classificação visual de cinco pontos a partir de achados de TC de tórax. Avaliou-se a influência do tipo de distribuição do enfisema na apresentação funcional e clínica da DPOC. Hipoxemia após o teste da caminhada de seis minutos (TC6) foi também avaliada e a distância percorrida (DTC6) foi determinada. RESULTADOS: Foram incluídos 86 pacientes. A média de idade foi de 65,2 ± 12,2 anos, 91,9% eram homens, e todos menos um eram fumantes (média de carga tabágica, 62,7 ± 38,4 anos-maço). A distribuição do enfisema foi categorizada como obviamente predominante no pulmão superior (tipo 1), em 36,0% dos pacientes; levemente predominante no pulmão superior (tipo 2), em 25,6%; homogêneo entre o pulmão superior e inferior (tipo 3), em 16,3%; e levemente predominante no pulmão inferior (tipo 4), em 22,1%. A distribuição do enfisema do tipo 2 foi associada a menores valores de VEF1, CVF, relação VEF1/CVF e DLCO. Em comparação com os pacientes do tipo 1, os do tipo 4 apresentaram maior probabilidade de ter VEF1 < 65% do previsto (OR = 6,91, IC95%: 1,43-33,45; p = 0,016), DTC6 < 350 m (OR = 6,36, IC95%: 1,26-32,18; p = 0,025),e hipoxemia após o TC6 (OR = 32,66, IC95%: 3,26-326,84; p = 0,003). Os pacientes do tipo 3 tiveram uma relação VR/CPT maior, embora sem diferença significativa. CONCLUSÕES: A gravidade da DPOC parece ser maior nos pacientes do tipo 4, e os do tipo 3 tendem a apresentar maior hiperinsuflação. A distribuição do enfisema pode ter um impacto importante nos parâmetros funcionais e deve ser considerada na avaliação de pacientes com DPOC.

Influence of emphysema distribution on pulmonary function parameters in COPD patients.

OBJECTIVE: To evaluate the impact that the distribution of emphysema has on clinical and functional severity in patients with COPD. METHODS: The distribution of the emphysema was analyzed in COPD patients, who were classified according to a 5-point visual classification system of lung CT findings. We assessed the influence of emphysema distribution type on the clinical and functional presentation of COPD. We also evaluated hypoxemia after the six-minute walk test (6MWT) and determined the six-minute walk distance (6MWD). RESULTS: Eighty-six patients were included. The mean age was 65.2 ± 12.2 years, 91.9% were male, and all but one were smokers (mean smoking history, 62.7 ± 38.4 pack-years). The emphysema distribution was categorized as obviously upper lung-predominant (type 1), in 36.0% of the patients; slightly upper lung-predominant (type 2), in 25.6%; homogeneous between the upper and lower lung (type 3), in 16.3%; and slightly lower lung-predominant (type 4), in 22.1%. Type 2 emphysema distribution was associated with lower FEV1, FVC, FEV1/FVC ratio, and DLCO. In comparison with the type 1 patients, the type 4 patients were more likely to have an FEV1 < 65% of the predicted value (OR = 6.91, 95% CI: 1.43-33.45; p = 0.016), a 6MWD < 350 m (OR = 6.36, 95% CI: 1.26-32.18; p = 0.025), and post-6MWT hypoxemia (OR = 32.66, 95% CI: 3.26-326.84; p = 0.003). The type 3 patients had a higher RV/TLC ratio, although the difference was not significant. CONCLUSIONS: The severity of COPD appears to be greater in type 4 patients, and type 3 patients tend to have greater hyperinflation. The distribution of emphysema could have a major impact on functional parameters and should be considered in the evaluation of COPD patients.