PREPUBERTAL GROWTH AND GROWTH HORMONE SECRETION IN CHILDREN AFTER TREATMENT FOR HEMATOLOGICAL MALIGNANCIES,INCLUDING AUTOLOGOUS BONE MARROW TRANSPLANTATION

Prepubertal growth standards were used to assess growth in 20 children who had undergone autologous bone marrow transplantation (ABMT) as part of their treatment for hematological malignancy. Most of the patients (16 of 20) were transplanted after a relapse of their disease. A negative change in height standard deviation score (H-SDS) was seen only in the group of patients (n=7) who had received both cranial irradiation therapy (CRT) and 7.5-Gy single-fraction total body irradiation (TBI). Height changes in this group were observed from the time of diagnosis. In contrast, the groups of patients conditioned with chemotherapy only (n=3) or both chemotherapy and TBI, without preceding CRT (n=10), did not demonstrate a significant loss in H-SDS. Weight related to height demonstrated large individual differences over time. Spontaneous growth hormone (GH) secretion, as measured by a four-point sleep curve, was followed longitudinally and an increasing proportion of patients with low peak levels was seen in all patient groups. In summary, prepubertal growth was suppressed only in patients who received cranial irradiation before ABMT. Despite low GH peak levels, normal prepubertal growth was found in patients with no CRT before ABMT.     

Adult height after cranial irradiation with 24 Gy: factors and markers of height loss

The decrease in adult height of children who have been given cranial irradiation (24 Gy) for acute lymphoblastic leukaemia is attributed to chemotherapy, growth hormone (GH) deficiency and early puberty. This study evaluates the factors involved in the height loss between irradiation and adult height and its markers in 43 patients irradiated at 5.8 ± 0.4 (SEM) years. The mean height loss was 0.9 ± 0.2 SD in the children with a normal GH peak ( n = 11), 1.7 ± 0.2 SD in those with a low GH peak and untreated ( n = 15) and 0.6 ± 0.2 SD in those treated with GH ( n = 17). The adult height was significantly lower than target height in all three groups. The height loss correlated negatively with the GH peak ( p < 0.02) and with the age at onset of puberty ( p < 0.05) in the first two groups with spontaneous growth, but not with the chemotherapy regimen or its duration, or the plasma insulin-like growth factor I (IGFI) and its GH-dependent binding protein (BP-3). Early puberty (onset at 8-10 years) occurred in 6 girls from the first two groups. At the first evaluation, 5.6 ± 0.4 years after irradiation, the GH peak values after arginine-insulin stimulation correlated with the age at irradiation ( p < 0.03), taking into account the time since irradiation. The plasma 1GF1 and BP-3 values were correlated with each other, but not with the GH peak. In conclusion, this study demonstrates the impact of GH deficiency and GH replacement therapy on adult height in children given cranial irradiation for leukaemia. They therefore should be evaluated for their GH secretion 1 2 years after the end of chemotherapy. GH therapy is indicated for those with low GH peak and decreased growth rate or no increase in growth rate despite puberty.     

Growth impairment and growth hormone therapy in children treated for malignant brain tumours

Eighty-two children with malignant brain tumours were treated according to the “8 in 1” chemotherapy protocol in Finland during 1986 to 1993. Thirty-seven with brain tumours not involving the hypothalamic-pituitary region are still alive and tumour-free. The growth and response to growth hormone (GH) therapy in these children was analysed. Children who received craniospinal irradiation had the most severe loss of height SDS, being −1.07 within 3 years of the diagnosis. Even children with no irradiation to the hypothalamic-pituitary axis had a mean change in height SDS of −0.5 after 3 years. Fifteen of 23 children who received craniospinal irradiation and two out of eight children who received cranial irradiation have received GH therapy. A catch-up growth response to the daily GH therapy with the mean dose of 0.7 IU/kg per week was complete in 3 years (+1.87 SDS), irrespective of craniospinal irradiation, in children who were treated at prepubertal age but was seen in none of the children who had reached pubertal age. Conclusion Growth impairment and GH deficiency are common in children treated for malignant brain tumours. The response to GH therapy is good in prepubertal children in terms of increased growth velocity, although the final height is not yet known. Received: 10 September 1996 and in revised form: 28 January 1997 / Accepted: 11 February 1997     

The role of growth hormone in stunted head growth after cranial irradiation

The head sizes of 38 patients, growth hormone (GH) deficient following craniospinal (n = 26) or cranial irradiation (n = 12), have been assessed before (n = 38) and on completion of GH therapy (n = 15) or at the end of a similar period of observation without GH (n = 7). These results were compared to the change in head size seen in idiopathic GH deficiency following GH therapy (n = 14). Before GH therapy, the latter had small heads [mean occipitofrontal circumference SD score (SDS) -1], which were relatively large compared to the height deficit [height SDS (CA) -4.7], and they exhibited catch-up growth with GH (delta occipitofrontal circumference SDS + 0.7, final occipitofrontal circumference SDS -0.2). In contrast, over a similar period all patients, who previously had received cranial irradiation in the dosage range 2700-4750 centi-Geigy, irrespective of the radiation schedule or GH treatment, showed a decrease in occipitofrontal circumference SDS (mean delta -0.9), a significant difference to the expected head growth of normal children over a similar period (p less than 0.01). We have noted that restricted head growth occurs in the years following cranial irradiation and is unaffected by GH therapy. Earlier work has shown that cranial irradiation may impair intelligence. The exact relationship between intellectual impairment and stunted head growth remains to be determined.     

Long-term complications following bone marrow transplantation in children

Abstract Seventeen children who underwent bone marrow transplantation (BMT) between 1975 and 1985 and survived for more than 2 years were evaluated for growth and development. The patients had a follow up of 2.1-13.1 years. Prior to transplant, children with malignancy had received multi-agent chemotherapy and nine had also received central nervous system irradiation. Transplant preparation for malignancy (group 1; n = 13) included high-dose cyclophosphamide (CPA) 120–200 mg/kg and total body irradiation (TBI) 10–13.2 Gy, whereas conditioning for non-malignant disorders (group 2; n = 4) included high-dose CPA 200 mg/kg with or without busulphan. Patients in group 1 showed a steady decline in height velocity following initial chemotherapy and cranial irradiation and the decline was even greater following BMT. Growth hormone (GH) deficiency developed in eight of nine children tested, hypergonadotrophic hypogonadism developed in 11 who reached puberty, thyroid hormone abnormalities were encountered in four out of 10 tested and 11 of 13 developed cataracts. Patients in group 2 did not show decline in linear growth rate, thyroid hormone abnormalities or cataracts after BMT. The only child tested had normal GH levels and the two patients who reached puberty showed delayed but complete gonadal recovery. Our data demonstrate that TBI leads to significant late effects on growth and gonadal function. Contrary to previous reports, a high incidence of cataract formation is observed after fractionated TBI. Conditioning regimens without TBI should be considered in children undergoing BMT.     

Final height of patients who underwent bone marrow transplantation during childhood.

OBJECTIVE: To determine the impact on final adult height of bone marrow transplantation. METHODS: The final height of 28 long term survivors (18 males; 10 females), allografted before or at the onset of puberty, at a median age of 10.8 years (range 6.3 to 14.6) and who did not receive growth hormone (GH) treatment or other growth promoting agents, was evaluated. Median follow up period after bone marrow transplantation was 7.9 years (range 3.2 to 11.4), and age at the most recent evaluation 18.1 years (range 15.6 to 24.5). Height values were expressed in standard deviation score (SDS) from the mean of the normal population. Height at bone marrow transplantation was compared with final height as well as with parental genetic height. Patients were divided into three groups: severe aplastic anaemia (SAA): three patients given no radiotherapy; leukaemia-total body irradiation (TBI): 14 patients with acute or chronic leukaemia conditioned with chemotherapy and TBI; leukaemia-TBI with previous cranial radiation therapy (CRT): 11 patients. None of the patients had solid tumour. RESULTS: There was a decrease in final height SDS compared to pre-transplantation height SDS (paired t test, p < 0.0001). All patients except one reached an adult height above -2.0 SDS. A significant decrease in height SDS was found in the TBI and the CRT groups (paired t test, p = 0.02 and p = 0.0002, respectively). Whereas height SDS value at the time of transplant was higher than the genetic height SDS, final height SDS values were lower. CONCLUSIONS: Despite the decrease in height SDS found after bone marrow transplantation, 27 of the 28 patients spontaneously achieved what is considered to be a normal height SDS (above -2.0 SDS). This should be taken into account when considering GH treatment in children who underwent bone marrow transplantation for malignant haematological diseases.     

Final height of patients who underwent bone marrow transplantation during childhood

OBJECTIVE: To determine the impact on final adult height of bone marrow transplantation. METHODS: The final height of 28 long term survivors (18 males; 10 females), allografted before or at the onset of puberty, at a median age of 10.8 years (range 6.3 to 14.6) and who did not receive growth hormone (GH) treatment or other growth promoting agents, was evaluated. Median follow up period after bone marrow transplantation was 7.9 years (range 3.2 to 11.4), and age at the most recent evaluation 18.1 years (range 15.6 to 24.5). Height values were expressed in standard deviation score (SDS) from the mean of the normal population. Height at bone marrow transplantation was compared with final height as well as with parental genetic height. Patients were divided into three groups: severe aplastic anaemia (SAA): three patients given no radiotherapy; leukaemia-total body irradiation (TBI): 14 patients with acute or chronic leukaemia conditioned with chemotherapy and TBI; leukaemia-TBI with previous cranial radiation therapy (CRT): 11 patients. None of the patients had solid tumour. RESULTS: There was a decrease in final height SDS compared to pre-transplantation height SDS (paired t test, p < 0.0001). All patients except one reached an adult height above -2.0 SDS. A significant decrease in height SDS was found in the TBI and the CRT groups (paired t test, p = 0.02 and p = 0.0002, respectively). Whereas height SDS value at the time of transplant was higher than the genetic height SDS, final height SDS values were lower. CONCLUSIONS: Despite the decrease in height SDS found after bone marrow transplantation, 27 of the 28 patients spontaneously achieved what is considered to be a normal height SDS (above -2.0 SDS). This should be taken into account when considering GH treatment in children who underwent bone marrow transplantation for malignant haematological diseases.     

Normal growth despite abnormalities of growth hormone secretion in children treated for acute leukemia.

We have studied the relationship between abnormalities of the growth hormone-somatomedin axis and growth in 26 children previously treated for acute lymphatic leukemia. Each child had previously received cranial irradiation, was in complete clinical and hematologic remission, and off all drugs.The mean standing height SDS of the 26 children was significantly less than normal. There was no significant difference between the mean standing height SDS, height velocity SDS, somatomedin activities, and degree of bone age retardation between the 17 children who received the higher dose of cranial irradiation (Group 1) and the nine who had the lower dose of cranial irradiation (Group II). Furthermore, there was no significant reduction in mean height velocity SDS, somatomedin activity, or bone age in either group when compared to normal age-matched controls. The peak GH responses to both insulin hypoglycemia and an arginine test were significantly lowered in Groups I and II when compared to a control group of children. We conclude that only a minority of children, who previously received cranial irradiation for ALL were clinically GH deficient and, therefore, likely to benefit from GH therapy despite the finding that the majority of these children had reduced GH responses to pharmacologic stimuli.     

Growth and endocrine disorders in optic glioma

Hypothalamo-pituitary function in children with optic glioma may be impaired by the tumour itself and by the high cranial radiation doses used in treatment. This study evaluates the effect of optic glioma and its treatment on patient growth and pubertal development. Twenty-one patients (13 boys, 8 girls), treated for optic glioma by cranial irradiation (45–55 Grays) at a mean age of 5.4 years, were evaluated before (n=10) and/or after (n=21) irradiation. Growth hormone (GH) deficiency was present in only 1 patient tested before irradiation and in all patients after irradiation. Precocious puberty occurred in 7/21 cases, before irradiation in 5 patients and after irradiation in 2 patients. The cumulative height loss during the 2 years after irradiation was 0.2±0.2 SD (m±SEM) in 7 patients with precocious puberty and 1.1±0.2 SD in 14 prepubertal patients (P<0.01). The corresponding bone age advance over chronological age, evaluated 1–3 years after irradiation, was 1.1±0.5 and –0.7±0.3 year in the two groups (P<0.01). The mean height loss between time of irradiation and the final height was 2.3±0.6 SD (n=6). Primary amenorrhoea, associated with low oestradiol levels, occurred in two of the three girls of pubertal age. These data indicate that the high dose of cranial radiation used to treat optic glioma invariably results in GH deficiency within 2 years and that hGH therapy is required when GH deficiency is documented. Precocious puberty, resulting in apparently normal growth velocity in spite of GH deficiency, should be treated with luteinizing hormone-releasing hormone analogues because of the risk of accelerated bone maturation and reduced final height.     

Is insulin-like growth factor-1 monitoring useful in assessing the response to growth hormone of growth hormone-deficient children?

OBJECTIVE: To assess the relationship between insulin-like growth factor-1 (IGF-1), the growth hormone (GH) dose utilized to treat GH-deficient children and the changes noticed in height-standard deviation score (H-SDS) and height velocity (HV). STUDY DESIGN: We studied 24 prepubertal GH-deficient patients with a mean age of 10.5 +/- 1.8 years and a mean bone age (BA) of 8.4 +/- 2.1 years. H-SDS for chronologic age (CA) and BA before therapy were -2.6 +/- 0.8 and -1.2 +/- 0.8, whereas height velocity (HV)-SDS was -1.1 +/- 1.5. Serum IGF-1 and insulin-like growth factor binding protein-3 (IGFBP-3) levels were measured before, after 6 and 12 months of GH, and correlated with the GH dose used. Based on the increment of IGF-1 used during treatment, patients were divided into 2 groups: G1 (>1 SDS) and G2 (<1 SDS). HV-SDS and interval height increases were analyzed. RESULTS: HV-SDS, as well as H-SDS for CA and BA during the first year of treatment, were significantly greater than before therapy. IGF-1 SDS increased significantly during the first 6 months of therapy (P <.0003), but increased no further at 12 months despite the use of a higher GH dose (0.1 vs 0.14 IU/kg/day), whereas IGFBP-3 SDS increased at both 6 and 12 months. There was no correlation between the GH dose used and IGF-1 and IGFBP-3 levels. When patients were divided according to their IGF-1 increment during therapy, a significant increase in H-SDS for BA and in HV-SDS was noted only in group 2. CONCLUSIONS: The increment in IGF-1 SDS during therapy did not correlate with the interval height increase. IGF-1 measurement may be helpful in monitoring compliance and safety, but seems to be less useful in adjusting the GH dose needed to treat prepubertal GH-deficient children.     

Growth hormone state after completion of treatment with growth hormone.

After completion of treatment with growth hormone (GH) 19 patients with isolated ''idiopathic'' GH deficiency and 15 with post-irradiation GH deficiency underwent retesting of GH secretion with an insulin tolerance test or an arginine stimulation test, or both. Patients with post-irradiation GH deficiency comprised 13 patients with central nervous system tumours distant from the hypothalamo-pituitary axis and two with acute lymphoblastic leukaemia, who had received cranial or craniospinal irradiation. All 15 patients with post-irradiation GH deficiency remained GH deficient (peak GH response less than 7 mU/l (n = 10) and 7-15 mU/l (n = 5)). Of the 19 retested patients with idiopathic GH deficiency, however, five (26%) had peak GH responses of greater than 15 mU/l (regarded now as transient or false idiopathic GH deficiency) and were indistinguishable from the remainder (permanent or true idiopathic GH deficiency, peak GH responses less than 7 mU/l (n = 12) and 7-15 mU/l (n = 2)), by pretreatment anthropometry and post-treatment height standard deviation score, but had a lower first year height velocity (mean (SD) velocity 5.6 (0.5) cm/year for false idiopathic deficiency v 8.7 (1.75) cm/year for true idiopathic deficiency, p less than 0.01) and height increment on treatment (mean (SD) increment 2.2 (1.5) cm/year for false idiopathic deficiency v 5.2 (2.3) cm/year for true idiopathic deficiency, p less than 0.05). By current practices two patients with false idiopathic deficiency may have been distinguished by sex steroid priming. Thus post-irradiation GH deficiency seems to be permanent, but errors in diagnosis in idiopathic GH deficiency are common.     

Effectiveness of growth hormone (GH) therapy in GH-deficient children and non-GH-deficient short children

The growth response during short-term growth hormone (GH) treatment was evaluated in eight prepubertal non-GH-deficient (non-GHD) children and compared with six prepubertal GH-deficient (GHD) patients. Standard doses of GH can improve growth rate in GHD and in some non-GHD patients. In neither group the growth response can be predicted by the acute increase in Thymidine Activity or Somatomedin-C levels. A diagnostic trial of GH treatment may be the only certain method of selecting the short non-GHD patients who may benefit from long-term GH therapy.Abbreviations GH growth hormone - GHD growth hormone deficient - Sm-C somatomedin C - TA thymidine activity     

Effects of low-dose cranial radiation on growth hormone secretory dynamics and hypothalamic-pituitary function

Spontaneous growth hormone (GH) secretory dynamics and hypothalamic-pituitary function were studied in 16 long-term survivors of acute lymphoblastic leukemia who were aged 9 to 15 1/2 years and had been treated with prophylactic central nervous system radiation and combined chemotherapy. At the time of study, the mean height was -1.5 SD score below the mean, less than genetic potential, and significantly less than the mean pretreatment height of -0.25 SD score. Height velocity was subnormal for age and sexual stage in all patients. Two patients had compensated hypothyroidism, and four had evidence of gonadal failure. In 11 patients, the peak GH level after two provocative tests was below 10 micrograms/L, which was consistent with GH deficiency. In ten of 13 patients tested, spontaneous GH secretion determined by a 24-hour GH concentration (GHC), GH pulse amplitude, frequency of GH pulses greater than or equal to 5 micrograms/L, and GH peak during wake and sleep hours was significantly less than in normal height controls. Although in three pubertal patients the 24-hour GHC was within normal limits, the GHC during sleep hours, GH pulse amplitude during 24 hours and sleep hours, and peak GH during wake hours were significantly less than in normal height controls. In all pubertal and in two of the prepubertal patients, the somatomedin C (SmC) level was significantly less than in controls. The 24-hour GHC correlated well with the GHC during sleep, peak-stimulated GH level, gonadal steroid level, and the SmC level, but not with height velocity, dose of radiation, or age at radiation. A significant increase in height velocity and the SmC level was noted in all patients treated with GH. These results indicate that GH deficiency occurs after 18 to 24 Gy of cranial radiation and that the puberty-associated growth spurt may mask the decline in height velocity owing to GH deficiency. In some patients treated with cranial radiation, a subtle dysregulation in spontaneous GH secretion may exist despite a normal GH response to provocative testing.     

Reduction of adult height in childhood acute lymphoblastic leukemia survivors after prophylactic cranial irradiation

BACKGROUND: Impaired linear growth is a well-recognized complication in long-term childhood ALL survivors who received cranial irradiation. However, as many patients achieve a final height between the 5th and the 95th centile, the true incidence of linear growth impairment might be underestimated. METHODS: Reduction of adult height (RAH) was estimated in adult childhood ALL survivors with and without cranial irradiation. RAH was calculated as the difference between target height (TH) and final height (FH). TH was calculated according to the formula TH = {[(height father + height mother +/- 12)/2] + 3}. RAH was assessed in 79 adult childhood ALL survivors in first complete remission who had received cranial irradiation 25 Gy (Group I, n = 53), 18 Gy (Group II, n = 10) or chemotherapy alone (controls, n = 16). RESULTS: RAH was 8.6 +/- 8.2 cm in Group I (P = 0.001 vs. controls), 6.2 +/- 3.2 cm in Group II (P = 0.01 vs. controls), and 1.7 +/- 4.6 in controls (chemotherapy only). There was no significant difference between Group I and Group II. In Group I females had more RAH than males (P = 0.02). RAH was related to younger age at diagnosis (P = 0.001). CONCLUSIONS: The deficit between target height and final height highlights the reduction of adult height in the majority of male and female childhood ALL survivors who had received prophylactic cranial irradiation, in particular in those who were diagnosed at a younger age. This reduction would have been masked if patients FH was only compared with standard methods. RAH might be a sensitive predictor for growth hormone deficiency as these results suggest that radiation-induced growth hormone deficiency in these patients is the rule rather than the exception.     

Response to growth hormone treatment and final height after cranial or craniospinal irradiation

Growth hormone (GH) deficiency (GHD) induced by cranial irradiation has become a frequent indication of hGH substitutive therapy. This study analyses the growth response to hGH therapy and the factors involved in the decrease in growth velocity observed after cranial irradiation. One hundred children (61 boys and 39 girls) given cranial radiation for pathology distant from the hypothalamo-pituitary area were studied. Fifty-six of them received hGH therapy for GHD resulting in decreased growth velocity. The initial annual height gain in the cranial-irradiated group was comparable to that of patients treated for idiopathic GHD; additional spinal irradiation significantly reduced the growth response. Twenty-eight hGH-treated patients reached final heights which were compared to those of 2 untreated irradiated groups, one with GHD (n = 27) and the other with normal GH secretion (n = 17). The height SD score changes observed in hGH therapy were +0.3 in the cranial (n = 10) and -1.2 SD in the craniospinal (n = 18) groups. GH deficiency had contributed to a mean height loss of 1 SD and spinal irradiation to a loss of 1.4 SD. The small effect of hGH therapy on final height is probably linked to the small bone age retardation at onset of hGH therapy and to the fact that irradiated children entered puberty at a younger age in terms of chronological age (10.6 +/- 0.3 yr in girls and 11.0 +/- 0.3 yr in boys) and bone age (9.6 +/- 0.4 yr in girls and 12.6 +/- 0.3 in boys) than the idiopathic GHD patients. These data suggest that the results of hGH therapy in irradiated children might be improved with higher and more fractionated hGH doses and, in some patients, by delaying puberty using luteinizing hormone releasing hormone analogs.     

Influence of Treatment Modalities on Prepubertal Growth in Children with Acute Lymphoblastic Leukemia

The statural growth of 85 prepubertal children treated for acute lymphoblastic leukemia was evaluated in a longitudinal study over 4.5 years. Patients were divided into three groups according to central nervous system prophylaxis: 37 patients received cranial irradiation with a dose of 24 Gy, 15 received a dose of 18 Gy, and 33 were not irradiated. According to the risk of leukemia, patients were divided into normal-risk (n = 74) and high-risk (n = 11) groups. The duration of treatment was 2 years, during which all patients showed growth retardation. The relative standard deviation score for height declined from 0 to -0.7 for the irradiated patients and from 0 to -0.2 for the non-irradiated group (P = 0.0001). There was no difference in growth pattern between cranial irradiation with 18 versus 24 Gy and chemotherapeutic treatment according to high-risk versus normal-risk protocols. However, a negative synergistic effect of more intensive chemotherapy and cranial irradiation on growth was demonstrated.     

Cataracts after autologous bone marrow transplantation in children

We recorded the incidence and degree of posterior subcapsular cataract (PSC) in 29 children who had undergone autologous (n = 28) or syngeneic (n = 1) bone marrow transplantation (BMT) due to haematologic or lymphoid malignancy. Conditioning prior to transplantation consisted either of a combination of chemotherapy and total body irradiation (TBI) (n = 21) or of chemotherapy only (n = 8). TBI was given in one fraction of 7.5 Gy. Nine patients had received previous cranial irradiation. The patients were followed for 4-10y (median 8 y) after transplantation. Of 29 patients, 22 developed PSC, all within 4 y after BMT. With the exception of one patient who developed unilateral PSC, all had received TBI. Conversely, 100% of those who received TBI developed PSC. In this group (+TBI), eight patients (38%) developed significant PSC, defined as best corrected visual acuity <0.8 in either eye. Six patients (10 eyes) have since needed surgical repair consisting of extracapsular cataract extraction and intraocular lens implantation. There was no clear relationship between previous cranial irradiation and cataract development, nor any other obvious baseline differences between those in the +TBI group who developed significant PSC and those who did not. Although effects of previous therapy cannot be ruled out, TBI appears to be the main cause of PSC in this group of patients. Twelve patients in the +TBI group had well-preserved visual acuity throughout the study, reflecting a slow progression of PSC. This compares favourably with previous reports of allogeneic BMT, possibly owing to less need for corticosteroids after autologous BMT. We conclude that the incidence of PSC was high after autologous BMT where the conditioning regimen included total body irradiation.     

Young adult survivors of childhood acute lymphoblastic leukemia: spontaneous GH secretion in relation to CNS radiation

BACKGROUND: Young adults who are long-term survivors of acute lymphoblastic leukaemia (ALL) in early childhood usually do well and do not have to go to regular medical checkups. Many of these survivors did receive prophylactic cranial radiotherapy during their oncological treatment. The effect of cranial irradiation on the hypothalamus is considered to be progressive. Therefore, late effects, such as reduced growth hormone (GH) secretion, may remain undetected until adulthood. PROCEDURE: Records from all patients treated for ALL before the onset of puberty in the region of West Sweden, between 1 January 1973 and 31 December 1985 were included, provided they were in first remission with a minimum follow-up time of 15 years, and a minimum age of 20. These criteria were met by 47 young adults aged 20-32 years, of whom 35 agreed to participate. We studied spontaneous GH secretion over 24 hr, IGF-I and IGFBP-3, final height and BMI. The patients had been treated according to three consecutive Swedish childhood leukaemia group protocols. The median follow-up time was 20 years, and 19 of the patients had been treated with cranial irradiation (CRT+), 16 had not (CRT-). RESULTS: CRT+ patients had significantly lower maximal peaks of GH than CRT- patients. Fifty percent of the CRT+ patients had a GH(max) below the cut-off level (3.3 microg/l), for GH treatment. CRT- patients all had GH(max) levels considered within the normal range. Final height of all the patients, except one CRT+ women, was in the range of expected midparental height, the median loss in final height in the CRT+ patients was 0.8 standard deviation (SD). No patient in this study was obese by definition (BMI <30 kg/m(2)). IGF-I and IGFBP-3 concentrations did not correlate to variations in spontaneous GH secretion in these patients. CONCLUSIONS: In spite of the little effect on final height, we found impaired spontaneous GH secretion in 79% of young adults 20-32 years of age, and GH deficiency (GHD) in 47% after low-dose cranial irradiation in early childhood. The consequences of this low-GH secretion need to be investigated.     

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

Total body irradiation (TBI) is used as a 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. In conclusion, growth is seriously affected in children after BMT, especially if SF-TBI is administered. Decreased growth rates were also observed after FF-TBI, but to a lesser degree, despite the higher total dose of irradiation.     

Growth response to growth hormone therapy following cranial irradiation

The growth response to growth hormone (GH) therapy has been studied in 12 children who received irradiation to the cranium alone either for brain gliomas, distant from the hypothalamic-pituitary axis, or as prophylaxis against CNS leukaemia. Seven children have completed GH treatment (mean duration 4 years) and five are presently on GH (mean duration 1.2 years). This response has been compared to that seen in 14 children with isolated idiopathic GH deficiency (IGHD), following GH therapy. Before treatment, the cranially irradiated patients (C-PRGHD) had higher standard deviation scores (SDS) for standing height, sitting height and leg length, and less bone age (BA) retardation, but started treatment at a similar age, and with a similar pre-treatment growth velocity and GH peak to standard provocative tests, compared to IGHD patients. GH produced a significant and similar increase in growth velocity (cm/year and SDS for BA) over the first 2 years' treatment in both groups. However C-PRGHD patients entered puberty and thus completed growth earlier than the IGHD group. As a result, cranially-irradiated children showed no change in height SDS with GH therapy, compared to catch-up growth in IGHD. Nevertheless, GH has enabled C-PRGHD patients to maintain their centile position and to achieve a more acceptable final height.Abbreviations GH growth hormone - IGHD idiopathic growth hormone deficiency - C-PRGHD post cranial-irradiation growth hormone deficiency - SDS standard deviation score - BA bone age - ALL acute lymphatic leukaemia - TSH thyroid stimulating hormone - CA chronological age - HA height age