Retinoblastoma: Socio-Demographic, Clinical and Therapeutic Aspects in the Hemato-Oncology Unit of the Department of Pediatrics of Donka National Hospital, Guinea ()
1. Introduction
Retinoblastoma is a malignant tumor that develops at the expense of embryonic retinal cells or retinoblasts [1]. It affects infants and young children in general, before the age of 5 years [2] [3] [4]. Globally, the overall incidence of retinoblastoma is estimated at 1/16,000 live births, or about 8000 new cases each year, including at least 2000 new cases in Africa [5]. The incidence of retinoblastoma is unevenly distributed. It is higher in low-income countries than in high-income countries [6].
There are two forms of retinoblastoma: the sporadic form and the hereditary form. Sporadic cases are always unilateral and account for 60% of patients, with a median age at diagnosis of about two years, while the hereditary forms are mostly bilateral and account for 40% of patients, with a median age at diagnosis of about one year [2].
The diagnosis of retinoblastoma is essentially clinical and is most often revealed by two warning signs: Leukocoria and strabismus. These signs allow an early diagnosis by a simple examination of the fundus. Imaging plays an important role in the diagnosis of atypical or advanced forms of retinoblastoma with an inaccessible fundus [7].
In industrialized countries, the cure rate is about 95%, the vast majority of cases are diagnosed at an early stage of the disease, whereas in poor countries life-threatening retinoblastoma is a major challenge and is due to late diagnosis [5].
The objective of this study was to highlight the socio-demographic, clinical and therapeutic aspects of retinoblastoma at the Pediatric Hematology and Oncology Unit in Donka of Guinea.
2. Methods
The pediatric hematology and oncology unit of Donka national hospital in Guinea was the setting for this study. This unit is located on the grounds of Donka National Hospital republic of Guinea. It has a capacity of 8 inpatient beds and a day hospital. The staff includes 3 onco-pediatricians, 5 state nurses and 1 technical health worker. The hematology and oncology unit is supported by the Franco-African pediatric oncology group (GFAOP), which provides medicines and staff training. This unit was opened in 2012. It became functional in 2016 with the training of oncologists. It is the only pediatric cancer care unit in Guinea. It was a retrospective and descriptive study over 3 years from January 1, 2017 to December 31, 2019.
The study population was all retinoblastoma patients followed in the unit, and whose records were usable (records of patients who have completed a full retinoblastoma extension workup). Patients who were lost to follow-up (Patients who have not been heard from and who have not undergone an extension workup) were not included in the study.
The variables studied were:
· Socio-demographic data (sex, age, place of residence of patients);
· Clinical data (mode of discovery, reason and time of consultation, itinerary, stage of the disease, laterality, fundus results);
· Paraclinical data (biology, ultrasound and brain orbital CT data).
The data were collected on a pre-established and validated survey form and entered into Word and Excel and then analyzed on Epi info 7.2.
Ethical Considerations
The agreement of the service managers was obtained before the surveys began. A working protocol was drawn up and validated by the hospital authorities and the pediatric chair. The confidentiality of the data collected was respected and the personal information collected remained confidential.
3. Results
3.1. Socio-Demographic Aspects
Out of 210 patients followed for cancer we registered 46 cases of retinoblastoma (21.9%) (Table 1). The patients were distributed as follows: 13 in 2017 (28.2%), 16 in 2018 (34.8%) 17 in 2019 (37%). The average age of our patients was 35.17 months with extremes of 3 months and 132 months. There were 52.2% girls and 47.8% boys with a B/G sex ratio of 0.9. The age range of 25 to 59 months was the most representative with 26 cases (56.52%). For 31 patients there was no notion of consanguinity between the 2 parents (67.3%). Eleven patients had relatives with a 2nd degree consanguinity (24%). Four patients had a 1st degree consanguinity (8.7%).
3.2. Clinical Aspects
The median time to visit was 165 days with extremes of 7 days and 4 years. The median time to diagnosis was 168 days with extremes of 8 days and 4 years. Median time to treatment was 197 days with extremes of 15 days and 4 years. At admission: 28 patients (60.87%) had Exophthalmos, 16 patients (34.78%) had Leukocoria, 4 patients (8.7%) had Buphtalmos and 4 patients (8.7%) had Strabismus. Sixteen of our patients had metastases (35%). Of these 14 (30.5%) had brain metastases and 2 patients (4.5%) had lymph node metastases. Sixty-five patients (65%) had no metastases. We registered 14 patients (30.43%) with intra-orbital forms, 32 patients (69.57%) with extra orbital forms. Forty patients (87%) had a unilateral shape and 6 patients (13%) had a bilateral shape.
Table 1. Incidence of retinoblastoma compared to other childhood cancers.
3.3. Therapeutic Aspects
Thirty-eight patients (82.6%), had preoperative chemotherapy 20 patients (43.48%) were enucleated 19 patients (41.3%) had postoperative chemotherapy. There were 9 patients (19.5%) were in remission, 14 patients (30.43%) died, 15 patients (36.39%) discontinued treatment (Table 2) and 8 patients (17.39%) are currently being treated.
Of the patients who died 12/14 had extra-orbital forms (85.7%), 6/14 (42.8%) had brain metastases, 2/14 (14.2%) had lymph node metastases. 2/14 (14.2%) had bilateral forms and 1/14 (7.14%) had intraorbital forms. Of the patients who died, 9/14 (64.2%) died during preoperative chemotherapy, 2/14 (14.22%) died during postoperative chemotherapy, 1/14 (7.14%) died on admission prior to the start of treatment and 3/14 (21.42%) died during palliative treatment.
Only one of our patients had health insurance (2.17%). For the other patients, the parents were responsible for their children’s health care.
4. Discussion
During this study period, 210 cases of all cancers were recorded. Retinoblastoma ranked second with a frequency of 21.90% (Table 1). Our frequency is higher than that of Ngatchoukpo et al. in Central Africa [8] and Constant et al. in 2018 [9] who found 5.4% and 12.07% respectively. The pediatric hematology and
Table 2. Distribution of patients by time to discontinue treatment.
oncology unit in Donka Guinea is a young unit. Before the creation of the unit, several cases of retinoblastoma were treated in Bamako (Mali) at the Institute of Tropical Ophthalmology of Africa (IOTA). The population and the health personnel are informed of the opening of the unit in Conakry, which increases the number of consultations.
The mean age of diagnosis was 35.17 months with extremes of 3 months and 132 months. This result is similar to that of Berete et al. in 2018 in Treichville who found a mean age of 35.5 months [10].
The age range of 25 to 59 months was the most representative with 26 cases, a frequency of 56.52%. This result is different from that found by Fernandes et al. in the United States in 2018 [11] who reported that the 0 - 1 year age group was the most affected. This difference could be explained by the early diagnosis in developed countries. Most patients consulted as soon as the first signs appeared. Lack of awareness of retinoblastoma in peripheral center delays the diagnosis of retinoblastoma.
The median time to visit was 165 days and the median time to diagnosis was 168.5 days. These results are higher than those found by Njuguma et al. in 2016 in Kenya [12] in their study who reported a median time to diagnosis of 30 days and a median time to diagnosis of 109 days. This may be explained by the fact that the signs and symptoms of retinoblastoma are not easily recognized by parents and health care staff.
The median processing time was 158 days. This result is higher than that found by Lukamba et al. [13] in 2018 in a study conducted in Côte d’Ivoire and the Democratic Republic of Congo, who reported a median time of 31 days. This could be related to the delay in consultation and diagnosis encountered in our study.
We found the notion of consanguinity between the parents in 15 cases, i.e. 32.61%. This result is identical to the one reported by Frikha et al. in Tunisia [14] who noted 15 cases or 37.5%. On the other hand, it is lower than that found by Kaka et al. in Niger in 2016 [15] who reported 45 cases or 78.6%. 10.52% of patients had a family history of retinoblastoma, i.e. 4.35% in siblings and 6.52% in ancestors. This result is higher than that found by Zomor et al. in Egypt in 2015 [16] who reported in their study that 5.7% of patients had a family history of retinoblastoma. In the literature 40% of retinoblastoma cases are hereditary. They are caused by a germline mutation in the RB1 gene [17] [18]. The presence or absence of a family history is an important factor in determining the likelihood of retinoblastoma occurrence. The probability of retinoblastoma occurring in patients with a family history of bilateral retinoblastoma is 90%. This probability is 15% for cases of unilateral retinoblastoma [17] [19]. Follow-up of children with a family history of retinoblastoma is necessary for early detection.
The unilateral form predominated in our study with 87% of the cases against 13.0% for the bilateral form. Unilateral retinoblastoma is the most common form as reported in the studies by Singh et al. in 2018 [20].
Clinical signs were dominated by exophthalmos 28 cases (37.78%). The presence of extra orbital forms 32 (69.57%), the presence of metastases 16 cases indicates a delay in the diagnosis of retinoblastoma at the Pediatric Hematology and Oncology Unit in Donka. Kim and Park in Korea in 2015 found leukocoria as the most frequent sign with 56% of cases [21]. On the other hand, exophthalmos was the most frequent reason for consultation 61% in a study conducted by Berete et al. in Ivory Coast in 2018 [10]. This result could be explained by the fact that children in Africa consult late in the course of the disease due to parents' ignorance of the first clinical signs of retinoblastoma, but also to the habit of consulting the traditional therapist first. It is after the failure of a long course of traditional treatment that patients are referred to a health facility. They are seen in a specialized structure at a late stage of the disease.
The extra-ocular form predominated in our study, 32 cases or 69.57% Among the 46 patients, there were 16 (34.79%) metastases. This result is different from that found by Chebbi et al. in Tunisia in 2014 [22] who reported 87% intraocular form. Lu et al. in the United States in 2018 [23] reported 9 patients with metastases (3.9%). The high number of extra-orbital forms at the time of diagnosis and the presence of metastases indicate a delay in diagnosis. Early diagnosis of cancers in general and retinoblastoma in particular is one of the major challenges in the management of childhood cancer in Guinea. The delay in diagnosis can be explained by the population’s lack of knowledge of RB and health workers’ lack of awareness of early signs. In fact, all our patients consulted a health structure as soon as the first symptom noticed by the parents appeared. The recourse to self-medication in case of failure of the 1st consultation in a health structure favours the delay of diagnosis and treatment.
The management of retinoblastoma is multidisciplinary. It involves the pediatric oncologist, the ophthalmologist, the radiotherapist, the ocularist, the anatomopathologist, the psychologist, the radiologist.
In our study, 82.6% of patients received preoperative chemotherapy, enucleation was performed in 20 patients (43.48%), and 41.30% of patients received postoperative chemotherapy. The high proportion of preoperative chemotherapy and enucleation performed would be explained by the fact that most of our patients diagnosed with an exophthalmos that did not allow for conservative treatment. Conservative treatment and radiotherapy are not done in Guinea. All cases with bilateral form requiring conservative treatment and cases of retinoblastoma requiring radiotherapy were referred outside Guinea.
The prognosis is still bleak in developing countries. We recorded 14 deaths (30.43%). This finding is found in most African studies, notably that of Kazadi Lukusa et al. [24] in Congo in 2012, who found a mortality rate of 90%. This high number of deaths can be explained by the delay in diagnosis (high extraocular forms, presence of metastases) and the absence of certain therapies such as radiotherapy in Guinea. Parents do not have the means to evacuate their children due to the cost of radiotherapy.
Fifteen patients dropped out of treatment by 32.61% (Table 2). The absence of a home for parents who do not live in Conakry and the high cost of check-ups such as CT scans are factors that encourage the abandonment of treatment. The pediatric hematology and oncology unit in Conakry receives half-yearly drug donations from the Franco-African pediatric oncology group, which reduces the cost of chemotherapy. In the event of a drug break, chemotherapy is paid for by the family.
Our study has some limitations: we did not have enough recurrences to assess the survival of our patients. As the study period was from January 2017 to December 2019, some of our patients were still being treated at the time of inclusion. For these patients, we were unable to assess the evolution of their pathology.
We had 36.96% remission. Berete et al. [10] in Ivory Coast in 2018 reported a remission rate of 25%. This result could be explained not only by a delay in diagnosis and treatment but also by frequent drug stockouts.
5. Conclusion
In this region of Guinea, retinoblastoma is the most common ocular tumor in children. Its diagnosis is easy: strabismus and leukocoria are the early signs of reti-noblastoma. The prognosis depends on how early the diagnosis is made. Physicians, care-givers, and family members should be aware of the nature of this malignancy and social education/message as such is necessary.
Acknowledgements
We would like to thank the Franco-African Pediatric Oncology Group for all its support in the research and care of children with cancer.