We conducted a single-center, retrospective study at the 614-bed, tertiary care Gifu University Hospital. We enrolled hospitalized patients with thoracic cancer who received cancer chemotherapy in the respiratory medicine ward between April 2013 and May 2014. One of two clinical pharmacists in charge, including one oncology pharmacy specialist, was based in the respiratory medicine ward and implemented pharmaceutical care for the patients. Adverse events were monitored in cooperation with physicians, nurses and clinical pharmacists and were recorded in each patient's electronic medical chart. Appropriate drug management for adverse events was performed by the physician based on his/her own judgement or on the pharmacist's recommendation, and judgment of whether or not the intervention improved an adverse event was continued until the end of the treatment.

The present study was conducted according to the guidelines for human studies of the ethics committee of Gifu University Graduate School of Medicine and the Government of Japan, and was approved by the university's institutional review board (approval no. 28-348). In view of the retrospective nature of the study, informed consent from the subjects was not mandated.

In our hospital, all thoracic cancer chemotherapy is administered based on a treatment protocol agreed upon by physicians and clinical pharmacists in advance. This protocol sets the criteria for starting treatment, dose reduction or drug withdrawal accompanying incidence of adverse events and dose adjustments for renal and hepatic function based mainly on evidence from original reports, and prophylactic supportive care, including antiemetic medication; hydration management for cisplatin; folic acid supplements and vitamin B₁₂ injections for pemetrexed; glucocorticoid and histamine H₁ for paclitaxel hypersensitivity; and hydration while on having renal dysfunction. Standard antiemetic medication was administered based on the Japanese Society of Clinical Oncology guidelines (17). Additionally, patients who developed chemotherapy-induced nausea and vomiting were prophylactically administered aprepitant, olanzapine, lorazepam or prochlorperazine in addition to standard prophylactic antiemetic therapy at the next scheduled treatment.

Standardized chemotherapy order forms containing the dosage of anticancer drug and dose calculation (mg/m²), start date and time, day of therapy, solution diluent and volume, infusion rate (drips), route (intravenous push or infusion), duration of infusion, frequency of anticancer drug administration, total number of scheduled doses, and prophylactic supportive care restricted to injections were entered into the electronic medical chart for each regimen.

Clinical pharmacists performed the following duties: Interviewed all patients on admission and documented medications brought to the hospital and patients' medication history, daily review of laboratory data, verified prescriptions, monitored and managed adverse events, provided drug information to medical staff, and patient education.

Clinical pharmacists provided physicians with timely information and advice on adverse events; drug interactions; and appropriate dosages, dose intervals, and routes of administration. All interventions performed by pharmacists were recorded, including whether or not their recommendations were accepted by the physicians.

In the present study, adverse events were defined as harm due to medications (adverse drug event), radiation therapy, or events that occurred during the course of the disease, excluding those due to medical errors, system errors and equipment failure. The severity of adverse events was graded according to the Common Terminology Criteria for Adverse Events (National Cancer Institute, MD, USA) version 4.0. Pharmacotherapy for adverse events was based on the National Comprehensive Cancer Network guidelines for supportive care and other clinical practice guidelines for each adverse event.

Interventions for adverse events were carried out in patients showing grade ≥2 non-hematological or grade ≥3 hematological adverse events, and the effect of intervention was evaluated before and after intervention. The judgment whether or not the intervention improved the adverse events was conducted until the end of the treatment.

The following patient data were recorded in specially prepared Microsoft Excel 2010 (Microsoft Corp.) spreadsheets: Patient age and sex; date of admission and discharge; diagnosis; purpose of hospitalization; list of private medications; clinical pharmacists' prescription proposals; and adverse events, their grade, and outcome of intervention. The duration of hospital stay was documented in Kaplan-Meier plots and the mean hospital stay was statistically compared using the Mantel-Cox log rank test. Data were analyzed using SPSS version 11 (SPSS Inc.) and GraphPad Prism version 6.0 (GraphPad Software). Comparison of the incidence of adverse events before and after intervention was statistically analyzed using McNemar's test for paired non-parametric variables. P-values of <0.05 was considered statistically significant.

A total of 484 (337 men and 147 women) patients who were hospitalized for the purpose of cancer chemotherapy were enrolled in the present study. Patient demographics are shown in Table I. The median age of patients was 66.0 years (5-95th, 56.0-76.0 years), and the mean duration of hospital stay was 12.3 days (5-95th, 4.0-24.0 days). The most common cancer type was non-small cell lung cancer (n=355, 73.3%), followed by small cell lung cancer (n=110, 22.7%), malignant mesothelioma (n=10, 2.1%) and thymoma/thymic carcinoma (n=9, 1.9%). The most common cancer chemotherapy regimen was carboplatin (AUC 5) + pemetrexed (500 mg/m²) ± bevacizumab (15 mg/m²) (n=88, 18.2%), followed by carboplatin (AUC 5) + paclitaxel (200 mg/m²) ± bevacizumab (15 mg/m²) (n=85, 17.5%), docetaxel (60 mg/m²) (n=67, 13.8%), amurubicin (40 mg/m²) (n=41, 8.5%), carboplatin (AUC 5) + etoposide (100 mg/m²) (n=33, 6.8%), and pemetrexed (500 mg/m²) + bevacizumab (15 mg/m²) (n=30, 6.2%).

Before administration of chemotherapy, the clinical pharmacist implemented a total of 152 interventions in 101 of the 484 (20.8%) patients. The types of interventions implemented by the clinical pharmacist before administration of chemotherapy are shown in Table II. The most frequent type of intervention was drug addition (n=82, 53.9%), among which 76 interventions (50.0%) were related to addition of supportive care, followed by dose adjustment (n=27, 17.8%), selection (n=15, 9.9%), discontinuation (n=12, 7.9%), examination addition (n=6, 3.9%) and other (n=10, 6.6%).

As shown in Table III, there were a total of 365 adverse events, among which 29 (7.9%), 227 (62.2%), 89 (24.4%), and 20 (5.5%) were grade 1, 2, 3 and 4, respectively. A total of 203 (41.9%) patients had adverse events, including 12 (2.5%) with grade 1, 106 (21.9%) with grade 2, 69 (14.3%) with grade 3, 16 (3.3%) with grade 4, and 191 (39.4%) with grade ≥2 events.

In contrast, the most common adverse event was nausea/vomiting (23.4%), followed by neutropenia (17.8%), constipation (7.4%), anorexia (6.2%), hepatic dysfunction/renal dysfunction (4.7%), anemia (4.7%), hyperglycemia (3.8%), peripheral neuropathy (3.8%), oral mucositis/esophagitis (3.3%), myalgia/arthralgia/other pain (3.0%), hiccups (3.0%), diarrhea (2.4%), dysgeusia (2.1%), malaise (1.8%) and thrombocytopenia (1.8%) (Fig. 1A). The most common cause of adverse events was anticancer drugs (71.7%), followed by other drugs (23.5%), radiotherapy (3.3%) and disease (1.5%) (Fig. 1B).

As shown in Fig. 1C, the mean duration of hospitalization was significantly longer among patients with grade ≥2 events than those with grade 0 and 1 events [7.8 days, range 2.5-18.7 days vs. 18.1 days, range 4.0-48.6 days; hazards ratio (HR) 0.457, 95% confidence interval (CI) 0.377-0.555; P<0.001].

There were 224 medical interventions and 73 follow ups for grade ≥2 non-hematological or grade ≥3 hematological adverse events. Seventy-seven of 170 (45.3%) medical interventions for grade ≥2 non-hematological adverse events were implemented based on the pharmacist's recommendations (Fig. 2A). In contrast, 4 of 54 (7.5%) medical interventions for grade ≥3 hematological adverse events were based on the pharmacist's recommendations (Fig. 2B).

The rates of pharmacist's recommendations in medical intervention for each of non-hematological adverse events of grade ≥2 or hematological adverse events of grade ≥3 observed was as follows: Peripheral neuropathy (92.3%), followed by malaise (75.0%), nausea/vomiting (59.1%), oral mucositis/esophagitis (54.5%), diarrhea (50.0%), myalgia/arthralgia/other pain (28.6%), constipation (26.1%), hiccups (20.0%), anorexia (14.3%), hepatic/renal dysfunction (11.1%), neutropenia (8.2%) and hyperglycemia (7.1%) (Fig. 2C).

As shown in Fig. 3A, the incidence of grade ≥2 non-hematological or grade ≥3 hematological adverse events was significantly reduced after intervention (39.4 vs. 17.8%, P<0.01). Moreover, as shown in Fig. 3B, the incidence rates of following non-hematological adverse events of grade ≥2 or hematological adverse events of grade ≥3 observed were significantly reduced after implementation of medical interventions listed in Table IV: Nausea/vomiting (16.3 vs. 4.5%, P<0.01), constipation (5.4 vs. 0.8%, P<0.01), anorexia (4.3 vs. 1.2%, P<0.01), hyperglycemia (3.3 vs. 1.7%, P<0.01), oral mucositis/esophagitis (3.1 vs. 1.7%, P<0.05), hepatic or renal dysfunction (2.5 vs. 0.8%, P<0.01), myalgia/arthralgia/other pain (2.1 vs. 0.2%, P<0.01), hiccups (2.1 vs. 0.4%, P<0.01), diarrhea (1.2 vs. 0%, P<0.05), malaise (1.2 vs. 0%, P<0.05) and neutropenia (10.5 vs. 0.6%, P<0.01).