Treatment-related fertility impairment in long-term female childhood, adolescent and young adult cancer survivors: investigating dose-effect relationships in a European case-control study (PanCareLIFE).

STUDY QUESTION: Which chemotherapeutic agents and body site-specific radiation fields are dose-dependently associated with an increased risk of fertility impairment in long-term female childhood, adolescent and young adulthood (CAYA) cancer survivors? SUMMARY ANSWER: Busulfan, lower abdominal radiotherapy (RT) and total body irradiation (TBI) seem to be associated with fertility impairment at any dose, whereas gonadotoxicity of melphalan and procarbazine is suggested at medium/high (>140 mg/m2) or high dose (>5600 mg/m2) therapy, respectively. WHAT IS KNOWN ALREADY: Several treatment-related fertility deficits, as assessed by both self-reported outcomes and hormonal markers are known to occur following treatment of CAYA cancer. However, knowledge regarding precise dose-related estimates of these treatment-related risks are scarce. STUDY DESIGN, SIZE, DURATION: The current case-control study was nested within the PanCareLIFE cohort study. In total, 1332 CAYA survivors from 8 countries, 9 institutions and 11 cohorts, participated in and contributed data to the study. PARTICIPANTS/MATERIALS, SETTING, METHODS: All participants were female 5-year CAYA cancer survivors. In total, 450 cases (fertility impaired survivors) and 882 matched controls (not fertility impaired survivors) were included. Fertility impairment was defined using both questionnaire data (primary or secondary amenorrhea; use of artificial reproductive techniques; unfulfilled wish to conceive) and hormonal data (FSH and anti-Müllerian hormone (AMH)). Multivariable logistic regression models were used to investigate the effect of (i) alkylating agent exposure, and (ii) dose categories for individual chemotherapeutic agents and for RT-exposed body sites. MAIN RESULTS AND THE ROLE OF CHANCE: A positive dose-effect relationship between cyclophosphamide equivalent dose (CED) score and fertility impairment was found, with survivors with a CED score > 7121 mg/m2 being at a significantly increased risk of fertility impairment (odds ratio (95% CI) = 2.6 (1.9-3.6) P < 0.001). Moreover, cumulative dose variables of the following treatments were significantly associated with fertility impairment: busulfan, carmustine, cyclophosphamide, melphalan, procarbazine, lower abdominal RT and TBI. Busulfan, lower abdominal RT and TBI seem to be associated with fertility impairment at any dose, whereas gonadotoxicity of melphalan and procarbazine is suggested at medium/high (>140 mg/m2) or high dose (>5600 mg/m2) therapy, respectively. LIMITATIONS, REASONS FOR CAUTION: Our study may have been subject to selection bias since data from about half of the original base cohorts were available for the current study. This could impact the generalizability of our study results. WIDER IMPLICATIONS OF THE FINDINGS: We identified survivors at high risk for fertility impairment and, consequently, for a reduced or even absent reproductive life span. Both girls and young women who are about to start anti-cancer treatment, as well as adult female survivors, should be counselled about future parenthood and referred to a reproductive specialist for fertility preservation, if desired. STUDY FUNDING/COMPETING INTEREST(S): This study has received funding from the European Union's Seventh Framework Programme for research, technological development and demonstration under grant agreement no. 602030. There are no competing interests. TRIAL REGISTRATION NUMBER: n/a.

Incidence and severity of crucial late effects after allogeneic HSCT for malignancy under the age of 3 years: TBI is what really matters.

Younger children are considered to be more vulnerable to late effects (LE), which prompted us to study LE in patients after haematopoietic stem cell transplantation (HSCT) for a haematological malignancy before the age of 3. In this multicentre EBMT study, cumulative incidence (CI) and severity of endocrine LE, central nervous system complications and secondary malignancies at 5, 10, 15 and 20 years of follow-up were assessed. Risk factors (RF) like gender, diagnosis, age at and year of HSCT, TBI- or chemo-conditioning and GVHD were analysed. CI of any LE was 0.30, 0.52, 0.66 and 0.72 at 5, 10, 15 and 20 years after HSCT, respectively. In 25% of the patients, LE were severe at a median follow-up of 10.4 years. In multivariate analysis, only TBI was a RF for having any LE and for thyroid dysfunction and growth disturbance. Female gender was a RF for delayed pubertal development. Some more insight could be gained by descriptive analysis regarding the role of TBI and GVHD on the severity of LE. Although only five selected LE have been studied and median follow-up is relatively short, the incidence and severity of these LE are considerable but not different from what has been found in older children and TBI is the main RF.

Outcome following late marrow relapse in childhood acute lymphoblastic leukemia.

Thirty-four children with acute lymphoblastic leukemia, who developed bone marrow relapse after treatment was electively stopped, received reinduction, consolidation, continuing therapy, and intrathecal (IT) methotrexate (MTX). Sixteen children who relapsed within six months of stopping treatment had a median second-remission duration of 26 weeks; all next relapses occurred in the bone marrow. In 18 children who relapsed later, the median duration of second remission was in excess of two years, but after a minimum of four years' follow-up, 16 patients have so far relapsed again (six in the CNS). CNS relapse occurred as a next event in four of 17 children who received five IT MTX injections only and in two of 14 children who received additional regular IT MTX. Although children with late marrow relapses may achieve long second remissions, their long-term out-look is poor, and regular IT MTX does not afford adequate CNS prophylaxis. It remains to be seen whether more intensive chemotherapy, including high-dose chemoradiotherapy and bone marrow transplantation, will improve the prognosis in this group of patients.

Late effects of intensive treatment for acute myeloid leukemia and myelodysplasia in childhood.

PURPOSE: To perform a comprehensive assessment of the late effects of short-term intensive chemotherapy for childhood acute myeloid leukemia (AML) and myelodysplasia, and compare the sequelae of intensive chemotherapy alone with those of total-body irradiation (TBI). PATIENTS AND METHODS: Of 33 survivors studied, 26 (group A) received intensive chemotherapy including anthracyclines, one also received busulfan, cyclophosphamide (Bu/Cy), and bone marrow transplantation (BMT). Seven patients (group B) received chemotherapy, TBI, and BMT. Hearing, sight, growth, and endocrine, renal, and cardiac function were assessed. RESULTS: The mean height standard deviation score of 25 nontransplanted group A patients was +0.67 at diagnosis, -0.11 following treatment (P = .016), and +0.34 7 years later (P > .05), indicating no long-term growth impairment. The patients had normal gonadal function and the girls had normal uterine size and ovarian volume. The Bu/Cy patient had primary ovarian failure. Four group B children required growth hormone and four sex steroids for growth or gonadal failure. The girls had reduced uterine size and ovarian volume. Three had thyroid dysfunction and six had cataracts. Abnormalities of renal function were found in both groups and hearing loss in group A only. The mean cardiac shortening fraction was significantly reduced at 29.2% in group A and 28.6% in group B compared with 36% in normal subjects. Two group A patients have developed cardiac failure. CONCLUSION: Chemotherapy and TBI before BMT for AML has resulted in growth failure, gonadal and thyroid damage, and cataracts in most children, whereas chemotherapy alone caused cardiac, renal, and hearing abnormalities only.

Secondary amenorrhoea after total body irradiation in pre-puberty.

Bone marrow transplant (BMT) has been used as part of the overall treatment of refractory malignant diseases. High dose cyclophosphamide and total body irradiation (TBI) are frequently used as conditioning for BMT. Initial regimens included a single fraction of TBI, with doses varying from 7.5-10 Gy, but this was associated with a high incidence of late sequelae including multiple endocrinopathies. A fractionated irradiation course over 3-4 days of a higher total dose, 12-15 Gy, of TBI is now used. Successfully treated patients with childhood cancer have an increased risk, of developing second tumours. We describe a patient successfully treated for AML who developed multiple endocrine dysfunction and a second benign ovarian tumour.

Bone mineralization after treatment of growth hormone deficiency in survivors of childhood malignancy.

Having noted symptomatic osteoporotic vertebral collapse in young adult survivors of childhood malignancy, bone mineral density (BMD) was examined at three sites by dual-energy X-ray absorptiometry in 64 patients treated in childhood for intracranial malignancy (group 1; n = 21) or acute leukaemia (group 2; n = 43). Patients in group 1 were selected for growth hormone deficiency (GHD) by auxological and biochemical criteria before the end of puberty (Tanner stage V). Seven patients (six men; mean (+/- SEM) age at study, 28.0 +/- 2.9 years; mean age at diagnosis, 8.7 +/- 1.5 years) in this group had been treated with human pituitary growth hormone (GH) for 1-12 years; and 14 patients (nine men; mean age at study, 26.8 +/- 1.0 years; mean age at diagnosis, 10.7 +/- 1.4 years) had not received GH. Bone densities in group 1 were normal in the GH-treated patients at the femoral neck (98.4 +/- 3.8% of control), lumbar spine (100.4 +/- 6.1% of control) and Ward's triangle (101.0 +/- 6.1% of control) but markedly reduced in the untreated group (femoral neck, 81.2 +/- 2.6% of control (p = 0.002); lumbar spine, 79.1 +/- 4.1% of control (p = 0.04); Ward's triangle, 80.1 +/- 3.6% of control (p = 0.01)). The majority of patients in group 2 had been treated for acute lymphoblastic leukaemia (ALL) and were in three subgroups.(ABSTRACT TRUNCATED AT 250 WORDS)

Management of growth failure in the treatment of malignant disease.

Growth failure due to endocrine dysfunction as a result of treatment for malignant disease is becoming increasingly common. It may occur after cranial or craniospinal irradiation given in the treatment of acute lymphoblastic leukemia and brain tumors, and is often coupled with early or precocious puberty. It also occurs after neck and gonadal radiation and is particularly severe after total body irradiation where multiple endocrine deficiencies frequently occur. Failure to appreciate its occurrence or failure to institute therapy early enough may lead to short stature in adult life. Accurate and regular monitoring of standing and sitting height, bone age, and endocrine data should be undertaken by the oncologist in close collaboration with an endocrinologist, to ensure appropriate management of the patient.

Acute lymphoblastic leukaemia under 2 years.

Presenting features and natural history were assessed in 48 children with acute lymphoblastic leukaemia less than 2 years of age at diagnosis. Of these, 16 were less than 1 year (group 1) and 32 were between 1 and 2 years (group 2). Results were compared with a group of 348 children between the ages of 2 and 14 years (group 3) diagnosed over the same period. The children in group 1 presented with a higher prevalence of null cell acute lymphoblastic leukaemia, leucocyte counts greater than 100 X 10(9)/l, and hepatosplenomegaly and had a higher central nervous system (CNS) relapse rate and shorter duration of remission than those in the other two groups. Disease free survival and overall survival in group 2 paralleled that of group 3, although children in group 2 had a significantly higher CNS relapse rate. Neurological toxicity resulting from treatment with methotrexate and radiation was common in those under 2 years as a whole. In conclusion, children under 1 year have a particularly poor prognosis, while those between 1 and 2 years have a prognosis similar to that in the older age group. Alternative approaches to CNS prophylaxis are needed to reduce the high prevalence of CNS disease and toxicity.

Gonadotropin releasing hormone analogue and growth hormone therapy in precocious and premature puberty following cranial irradiation for acute lymphoblastic leukaemia.

Ten girls with early puberty secondary to cranial irradiation as a part of the treatment for acute lymphoblastic leukaemia (ALL) were treated with either gonadotropin-releasing hormone analogue (GnRHa) and human growth hormone (GH) (8 girls) or with GnRHa alone (2 girls). After 4 years of treatment, height SDS for bone age was improved in the group who received combined treatment (from -0.97 to +0.07, p < 0.001), in contrast to the 2 patients who received GnRHa alone in whom height standard deviation scores for bone age decreased (from -1.10 to -1.33). Sitting height in all patients was relatively shorter than leg length, and there was no significant alteration during the 4 years of treatment.

A second course of treatment for childhood acute lymphoblastic leukaemia: long-term follow-up is needed to assess results.

We report the results of long-term follow-up of 94 children who completed treatment for acute lymphoblastic leukaemia (ALL) between 1974 and 1986 and subsequently experienced a bone marrow relapse before 1992. 91 children received further induction, intensification and CNS directed therapy; 19 proceeded to BMT or ABMT and the remainder were treated on one of three protocols which increased in intensity. The duration of second remission improved significantly with increasing intensity of treatment and bone marrow transplantation was followed by fewer relapses than chemotherapy. Analysis of factors influencing the duration of second remission showed that only length of first remission was of additional significance; the median duration of second remission being only 19 months in children with a first remission of less than 4 years and 62 months in those with longer first remissions. 29 children electively stopped chemotherapy a second time but only 11 of these remain still in second remission with recurrences occurring for up to 7 years from the the time first relapse. Only three of the 24 long-term survivors had no significant late effects of treatment; these were most marked in children who had received a second course of radiotherapy. We conclude that very long follow-up is necessary to determine whether patients may be successfully re-treated following late bone marrow relapse and that all such treatment is associated with a high incidence of late effects.

Gonadal function after testicular radiation for acute lymphoblastic leukaemia.

Pubertal maturation, growth, and gonadal function were assessed in 13 boys with acute lymphoblastic leukaemia who had received direct testicular irradiation three to nine years earlier as treatment for testicular relapse or prophylaxis against this complication. Six boys had reached Tanner stage III-V puberty, five of whom had normal growth velocities and bone ages equivalent to chronological age. One boy exhibited maturational arrest on entering stage IV. The remaining seven children (54%) showed evidence of complete pubertal delay or arrested development in stage II, with absence of the pubertal growth spurt and often with delayed bone age. Basal gonadotrophins were abnormally high in all 13 boys, and those with delayed puberty had prepubertal concentrations of testosterone. Testicular irradiation given before puberty causes permanent Leydig cell damage in a high proportion of subjects, necessitating testosterone supplementation. The extent of damage may be related to the age at which radiation is delivered.

Total body irradiation-induced osteochondromata.

Nine patients developed osteochondromata, a mean of 6 years after total body irradiation (TBI) given before bone marrow transplantation for childhood leukaemia. This represents 23% of patients receiving TBI during the period from 1981 to 1989 surviving > or =5 years after bone marrow transplantation. The patients were followed up for a mean of 12.5 years from diagnosis of leukaemia and a mean of 2.5 years from diagnosis of osteochondromata. No osteochondroma, including three lesions removed surgically, showed evidence of malignant change. Six patients received growth hormone for irradiation-induced growth hormone deficiency, but this did not appear to influence the natural history of the osteochondromata. Radiation-induced osteochondromata (RIO) are often multiple and are indistinguishable from the more common idiopathic type. The incidence of RIO after TBI was higher than that reported after local irradiation.

The effect of testicular irradiation on Leydig cell function in prepubertal boys with acute lymphoblastic leukaemia.

Testicular function was investigated by the luteinising hormone releasing hormone (LHRH) test and a three day human chorionic gonadotrophin (HCG) test in 11 prepubertal boys with acute lymphoblastic leukaemia (ALL) who had received 2400 rads of fractionated radiation to their testes after relapse at this site. The results were compared with an unirradiated control group. Basal and peak testosterone values after 1000 units of HCG were significantly lower in the irradiated patients than in the control group. Peak follicle stimulating hormone (FSH) values after 100 micrograms LHRH were significantly higher in irradiated boys, but there was no difference in either basal FSH or basal and peak luteinising hormone values. The findings suggest that the ability of the Leydig cell to produce testosterone--as detected by the HCG test--is appreciably reduced after irradiation and that tubular dysfunction in prepubertal boys may sometimes be predicted by a raised FSH response.

Growth following single fraction and fractionated total body irradiation for bone marrow transplantation.

Total body irradiation (TBI) is used as preparative regimen prior to bone marrow transplantation (BMT). Since there are more long-term survivors, follow up studies are important. We have performed a retrospective analysis of growth for 49 children, who had undergone treatment with cyclophosphamide and TBI before BMT. Of these patients 26 received single fraction (SF) TBI as a dose of 900-1000 cGy, whereas 23 received fractionated (FF) TBI as a total dose of either 1200 cGy divided in six fractions or 1440 cGy divided in eight fractions over 3 days. Half of the patients in the SF-TBI group, and 9 in the FF-TBI group had received low-dose cranial irradiation prior to TBI. In all groups a decrease in height SDS was observed. By evaluating the major factors leading to growth impairment the influence of cranial irradiation, which was demonstrable in the 1st year after TBI, could not be shown after 3 years. At this time growth was significantly more impaired in the SF group with a mean height SDS of -0.9 (+/- SD 0.9) compared to a mean height SDS -0.22 (1.02) in the FF group (P < 0.05). Measurement of segmental proportions showed a significant difference in SDS for sitting height in comparison to SDS for subischial leg length, irrespective of the TBI regimen. This was already evident 1 year after TBI and decreased during the following years. Twenty four of the patients (17 in the single fraction and 7 in the fractionated TBI group) were treated with growth hormone, but demonstrated an inappropriate response with absent catch-up growth in their legs.(ABSTRACT TRUNCATED AT 250 WORDS)

Endocrine function following single fraction and fractionated total body irradiation for bone marrow transplantation in childhood.

Forty-nine children who had undergone treatment with cyclophosphamide and total body irradiation before bone marrow transplantation were investigated for impaired endocrine function. Twenty-six patients received single fraction total body irradiation as a dose of 9-10 Gy, whereas 23 patients received fractionated total body irradiation as a total dose of either 12 Gy divided into six fractions or 14.4 Gy divided into eight fractions, administered over 3 or 4 days. Half of the patients in the single fraction group and nine in the fractionated group had received cranial irradiation prior to total body irradiation. Pathological changes in thyroid function were observed in 19 patients (73%) of the single fraction group (elevated thyrotrophin (58%) and decreased thyroxine levels (15%)), whereas in the fractionated group only six patients (25%) developed transient raised thyrotrophin levels: the mean observation period was 3.2 years in the single fraction group and 2.7 years in the fractionated group. The stimulated growth hormone peak concentration was influenced significantly by previous cranial irradiation and was independent of the type of total body irradiation administered. In the patients who had received cranial irradiation, the mean growth hormone peak levels were 8.4 mU/l (single fraction group) and 13.9 mU/l (fractionated group), whereas in those who received only total body irradiation they were 24.9 mU/l(single fraction group) and 28.1 mU/l (fractionated group). The basal gonadotrophin concentration in children older than 9 years showed elevated levels in nine patients (50%) of the single fraction group and in only three patients (30%) of the fractionated group.(ABSTRACT TRUNCATED AT 250 WORDS)

Management of growth hormone deficiency through puberty.

As a model of the growth hormone (GH) dependence of growth in prepuberty and puberty, the growth of 182 children (93 boys, 89 girls) who survived in first remission for treatment of acute lymphoblastic leukaemia was examined. Chemotherapy regimens, including intrathecal methotrexate, were similar in all patients, but CNS treatment differed, in that one group received 2400 cGy cranial irradiation, while the other received 1800 cGy. There was a significant decrease in height SDS during prepuberty, which was equivalent in both sexes, whereas there was a much greater decrease in pubertal growth in girls than in boys. Girls treated with the lower dose regimen of cranial irradiation had their onset of pubertal maturation significantly advanced, to a mean of 9.9 years (p less than 0.001). Previous studies have indicated that the duration of puberty is shortened by GH treatment in patients with idiopathic multiple pituitary hormone deficiency or isolated GH deficiency (GHD). To determine whether an increase in the dose of GH administered during the adolescent growth spurt would improve final height, a prospective randomized trial was performed in 32 children (25 boys, 7 girls) with isolated GHD treated with a GH dose regimen of 15 IU/m2/week as daily s.c. injections. At the onset of the pubertal growth spurt, the patients were randomized either to an unchanged dose or to 30 IU/m2/week. There was no significant change in height velocity with the doubled dose of GH, but there was a trend in the advancement of pubertal maturation which was considered to be dose related. It is suggested that these findings are of relevance to the treatment of GHD in puberty, especially in girls with early or precocious puberty occurring as a consequence of low-dose cranial irradiation.(ABSTRACT TRUNCATED AT 250 WORDS)

Growth hormone treatment of growth failure secondary to total body irradiation and bone marrow transplantation.

Growth hormone was given to 13 children (nine boys, four girls) with acute leukaemia who had undergone treatment with cyclophosphamide and total body irradiation before bone marrow transplantation. Mean age at total body irradiation and bone marrow transplantation was 9.0 years (range 3.7-15.8). Endocrinological investigation was carried out at a mean of 2.0 years (range 0.4-4.0) after bone marrow transplantation. Peak serum growth hormone responses to hypoglycaemia were less than 10.0 micrograms/l (less than 20.0 mU/l) in 10, 10.5 micrograms/l (21.0 mU/l) in one, greater than 16.0 micrograms/l (greater than 32.0 mU/l) in two patients. Mean age of the patients at the start of growth hormone treatment was 12.2 years (range 5.8-18.2). The mean time between total body irradiation and bone marrow transplantation and the start of growth hormone treatment was 3.2 years (range, 1.1-5.0). Height velocity SD score (SD) increased from a mean pretreatment value of -1.27 (0.65) to + 0.22 (0.81) in the first year, +0.16 (1.11) in the second year, and +0.42 (0.71) in the third year of treatment. Height SD score (SD) changed only slightly from -1.52 (0.42) to -1.50 (0.47) in the first year, to -1.50 (0.46) in the second year, and -1.74 (0.92) in the third year. Measurement of segmental proportions showed no significant increase in subischial leg length from -0.87 (0.67) to -0.63 (0.65) in the first year, to -0.58 (0.70) in the second year, and -0.80 (1.14) in the third year of treatment. Our data indicate that children who have undergone total body irradiation and bone marrow transplantation respond to treatment with growth hormone in either of two dose regimens, with an increase in height velocity that is adequate to restore a normal growth rate but not to 'catch up', and that total body irradiation impairs not only spinal but also leg growth, possibly by a direct effect of irradiation on the epiphyses and soft tissues.

Survival and endocrine outcome after testicular relapse in acute lymphoblastic leukaemia.

Survival and endocrine status in a cohort of boys with acute lymphoblastic leukaemia (ALL) who started treatment between 1972 and 1987 and subsequently developed a testicular relapse were analysed. During this period there was a significant improvement in the overall event free survival for boys, but no significant decrease in the testicular relapse rate. Thirty three boys had an apparently isolated testicular relapse, whereas 21 boys had a combined relapse. The event free survival for boys with an isolated testicular relapse was 59% at six years (95% confidence interval (CI) 42 to 74%). The event free survival for the 16 patients with a combined relapse who received a second course of treatment was 32% (95% CI 17 to 60%). Those patients receiving adequate second line treatment for an isolated testicular relapse whose first remission was longer than or equal to two years had an event free survival of 82% (95% CI 63 to 93%) at six years. No boy relapsing within two years from diagnosis has survived. Endocrine late effects are significant, with 82% of the boys requiring hormonal treatment at some stage for induction of puberty or continuing pubertal maturation, or both. It is concluded that, despite the increasing intensity of initial treatment for ALL, isolated testicular relapse is treatable by conventional means in most patients. Careful endocrine follow up of these patients is essential as most will require hormone replacement treatment.