Prognostic significance of histologic features in canine renal cell carcinomas: 70 nephrectomies.

The prognostic significance of histologic and clinical features was evaluated in a retrospective study of 70 dogs treated with nephrectomy for renal cell carcinoma. Dogs presenting with hematuria and cachexia had significantly decreased overall and tumor-specific survival. Mitotic index (MI), nuclear size, nuclear pleomorphism, tumor differentiation, invasiveness, Fuhrman nuclear grade, and clear cell morphology were significantly associated with survival times (overall and tumor specific) in univariate analyses. A multivariate Cox proportional hazards model was constructed using stepwise selection to evaluate potential histologic predictor variables. This multivariate analysis revealed MI, defined as the number of mitotic figures in ten 400× fields, as the sole independent prognostic variable. Median survival for dogs with an MI >30 was 187 days compared with 1184 days for dogs with an MI of <10. Dogs with an intermediate MI of 10 to 30 had a median survival of 452 days. Canine renal carcinomas were categorized into the following subtypes based on histologic features and histochemical and immunohistochemical staining: (1) clear cell, (2) chromophobe, (3) papillary, and (4) multilocular cystic renal cell carcinomas. Clear cell carcinoma was diagnosed in 6 of 70 (9%) canine tumors and was associated with a significantly decreased median survival time. Papillary carcinomas were identified in 15 of 70 tumors (21%), chromophobe in 6 of 70 (9%), and the multilocular cystic variant of canine renal cell carcinoma in 3 of 70 tumors (4%). These findings facilitate uniform categorization of canine renal cell carcinoma and provide veterinary pathologists with criteria to determine prognostic information.

Prognostic factors for cutaneous and subcutaneous soft tissue sarcomas in dogs.

Soft tissue sarcomas (STSs) develop from mesenchymal cells of soft tissues, and they commonly occur in the skin and subcutis of the dog. Although phenotypically diverse with frequently controversial histogenesis, STSs are considered as a group because they have similar features microscopically and clinically. Following resection, local recurrence rates are low in general but vary according to histologic grade and completeness of surgical margins. Complete margins predict nonrecurrence. Even most grade I STSs with "close" margins will not recur, but propensity for recurrence increases with grade. The frequency of metastasis has not been accurately estimated, but it is believed to be rare for grade I STSs and most likely to occur with grade III STSs. However, metastasis does not necessarily equate with poor survival. High mitotic index is prognostic for reduced survival time. Further research is needed to determine more precise estimates for recurrence rates and survival as related to completeness of surgical margins and to delineate potential differences in metastatic rate and median survival time between grades. Other potential indicators of prognosis that presently require further investigation include histologic type, tumor dimension, location, invasiveness, stage, markers of cellular proliferation, and cytogenetic profiles. Common issues limiting prognostic factor evaluation include biases from retrospective studies, small sample sizes, poor verification of metastasis, inconsistent STS classification and use of nomenclature, difficulties in differentiating STS phenotype, and diversity of the study population (stage of disease and treatment status).

Recommended guidelines for submission, trimming, margin evaluation, and reporting of tumor biopsy specimens in veterinary surgical pathology.

Neoplastic diseases are typically diagnosed by biopsy and histopathological evaluation. The pathology report is key in determining prognosis, therapeutic decisions, and overall case management and therefore requires diagnostic accuracy, completeness, and clarity. Successful management relies on collaboration between clinical veterinarians, oncologists, and pathologists. To date there has been no standardized approach or guideline for the submission, trimming, margin evaluation, or reporting of neoplastic biopsy specimens in veterinary medicine. To address this issue, a committee consisting of veterinary pathologists and oncologists was established under the auspices of the American College of Veterinary Pathologists Oncology Committee. These consensus guidelines were subsequently reviewed and endorsed by a large international group of veterinary pathologists. These recommended guidelines are not mandated but rather exist to help clinicians and veterinary pathologists optimally handle neoplastic biopsy samples. Many of these guidelines represent the collective experience of the committee members and consensus group when assessing neoplastic lesions from veterinary patients but have not met the rigors of definitive scientific study and investigation. These questions of technique, analysis, and evaluation should be put through formal scrutiny in rigorous clinical studies in the near future so that more definitive guidelines can be derived.

Outcome following treatment of soft tissue and visceral extraskeletal osteosarcoma in 33 dogs: 2008-2013.

Extraskeletal osteosarcoma (EOS) is a rare, highly malignant mesenchymal neoplasm arising from viscera or soft tissues characterised by the formation of osteoid in the absence of bone involvement. Owing to the rarity of these neoplasms very little information exists on treatment outcomes. The purpose of this study was to describe the outcome following surgical treatment of non-mammary and non-thyroidal soft tissue and visceral EOS in dogs. Thirty-three dogs were identified; the most common primary tumour site was the spleen. Dogs that had wide or radical tumour excision had longer survival times compared with dogs that had only marginal tumour excision performed [median survival time of 90 days (range: 0-458 days) versus median survival time of 13 days (range: 0-20 days)]. The use of surgery should be considered in the management of dogs with non-mammary and non-thyroidal soft tissue and visceral EOS.

Radiation-induced osteosarcoma in dogs after external beam or intraoperative radiation therapy.

This report describes radiation-induced osteosarcomas in two groups of dogs. One group was given radiation therapy for spontaneous tumors and the second group of normal adult beagle dogs was given experimental intraoperative radiation therapy. Secondary tumors developed between 1.7 to 5 years after irradiation. Three of 87 spontaneous tumor-bearing dogs or 3.4% of dogs treated for soft tissue sarcomas developed osteosarcoma within the field of irradiation. Twenty-two dogs or 25% of dogs treated for soft tissue sarcomas survived 20 months. This high incidence may be due to the use of fractions in excess of 3.5 Gy. These dogs received 10 fractions in 3 weeks with fractions ranging from 3.5 to 5.0 Gy. Tumor induction may be included in the late effects of irradiation which are worsened by the use of coarse fractionation. There appeared to be a dose relationship for tumors induced after single intraoperative radiation doses combined with fractionated external beam irradiation. Seven of 27 dogs given this treatment and surviving at least 4 years developed osteosarcomas in the field of irradiation. One of 26 dogs given intraoperative radiation alone developed a tumor between 4 and 5 years. The lower incidence after intraoperative radiation alone may have been due to the lower total dose. However, the sequence of a course of fractionated irradiation followed by a large single dose seemed to enhance carcinogenicity.

Impact of heterogeneity in the predictive value of kinetic parameters in canine osteosarcoma.

Intratumoral heterogeneity has been identified as a potential problem in the efficacy of predictive assays. Canine osteosarcoma is an extremely heterogeneous solid tumor that has been shown to be an excellent model for the human disease. Intratumoral heterogeneity of kinetic parameters and the effect of heterogeneity on predicting outcome of treatment (time until metastasis) were studied in dogs with naturally occurring osteosarcoma. Dogs were treated with amputation or tumor excision and limb-sparing followed by chemotherapy with cisplatin. Kinetic parameters evaluated included v, duration of DNA synthesis (Ts), and potential doubling time (Tpot), determined using in vivo labeling with bromodeoxyuridine and flow cytometry. In 30 tumors, multiple samples were obtained and evaluated. There was significantly more variation between tumors from different dogs than intratumoral variation of v, Ts, and Tpo. Variations in v, Ts, and Tpot within a tumor were associated with both sample location and tumor subpopulation. Time to metastasis was determined in 51 dogs with tumors sampled for kinetics. Multiple samples were available from 25 of these tumors. Cox proportional hazard analysis was performed using either the fastest or slowest Tpot from each sample. The fastest available Tpots were highly significant (P < 0.001) for prediction of outcome. The slowest available Tpots were also significant predictors, although the statistical strength was compromised (P = 0.024). Obtaining at least two samples in large tumors known to be heterogeneous is recommended to improve the predictive ability of Tpot. v is a more limited predictor but can useful when Tpot is not available. In canine osteosarcoma, an extremely heterogeneous tumor, kinetic parameters were shown to be predictors of outcome.

Comparison of DNA aneuploidy of primary and metastatic spontaneous canine osteosarcomas.

Spontaneous canine osteosarcomas were analyzed for DNA aneuploidy and percentage of S phase cells using flow cytometry. Forty-eight dogs were studied in which both a primary tumor and subsequent metastases were available. The DNA index distributions for the primary tumors and the metastases were quite similar. However, when individual primary tumors and metastases derived from them were compared, many of the cases had different ploidy values. The tumor cells were also analyzed for percentage of S phase. The diploid metastases had less than 17% S phase cells, whereas the aneuploid metastases had up to 40% S phase cells. There was a direct correlation between the DNA index and the percentage of S phase in the metastases.

Tetrachlorodibenzo-p-dioxin exposure alters radial arm maze performance and hippocampal morphology in female AhR mice.

Perinatal exposure to 2,3,7,8-tetrachlorodibenzo-p-dioxin (TCDD) has been reported to alter spatial learning in rats tested on a radial arm maze (RAM). TCDD is believed to exert most of its effects through binding to the aryl hydrocarbon receptor (AhR). To determine whether the AhR mediates TCDD-induced alterations in spatial learning, we tested male and female AhR-knockout (AhR-/-), heterozygous (AhR+/-) and wild-type (AhR+/+) mice on the RAM. AhR+/- male and female mice were time mated, and treated dams were dosed with 5 microg TCDD/kg body weight on day 13 of gestation. When offspring reached adulthood, male and female AhR+/+, AhR+/- and AhR-/- mice from TCDD-exposed and unexposed litters were tested on the eight-arm RAM. After testing, we examined hippocampal morphology as visualized by the Timm's silver sulfide stain. TCDD-exposed female AhR+/- mice made more errors than their respective controls on the RAM and exhibited a decrease in the size of the intra- and infrapyramidal mossy fiber (IIP-MF) field of the hippocampus. None of the other TCDD-exposed groups differed from their respective control groups with regard to maze performance or hippocampal morphology. The reduction of IIP-MF field indicates a possible morphological basis for the learning deficit that was observed in the female AhR+/- mice. It is hypothesized that the effect of TCDD exposure is AhR dependent and that TCDD may alter GABAergic activity in the hippocampus of female mice during development.

DOG1 is a sensitive and specific immunohistochemical marker for diagnosis of canine gastrointestinal stromal tumors.

Gastrointestinal stromal tumors (GISTs) and leiomyosarcomas are histologically similar primary neoplasms commonly occurring in the gastrointestinal tract of dogs and humans. Immunohistochemical staining (IHC) is needed to differentiate between these 2 entities and positive reactivity for KIT (cluster of differentiation [CD]117) is regarded as the gold standard for diagnosis of canine GIST. Studies estimate 5-10% of human GISTs stain negative or only weakly positive for KIT and have identified DOG1 (discovered on gastrointestinal stromal tumors protein 1) as a highly sensitive and specific marker for human GISTs. The purpose of this study was to evaluate immunoreactivity of a commercially available DOG1 antibody for use in diagnosis of canine GISTs. Fifty-five primary mesenchymal gastrointestinal tumors with histologic features consistent with GIST or leiomyosarcoma were evaluated via IHC for KIT, DOG1, and desmin. A subset of tumors was additionally evaluated for reactivity for smooth muscle actin (SMA). Thirty-three tumors (60%) were diagnosed as GIST based on positive immunoreactivity for KIT or DOG1 regardless of reactivity for desmin or SMA. Most GISTs (32/33, 97.0%) had similar staining for both KIT and DOG1. DOG1 expression was identified in 2 tumors (1 study tumor and 1 additional tumor) negative for KIT and desmin that had histologic features consistent with KIT-negative, platelet-derived growth factor receptor-alpha (PDGFRA)-mutant human GISTs. Our results suggest that DOG1 has improved specificity and sensitivity to that of KIT for differentiating between canine GISTs and leiomyosarcomas. Inclusion of both DOG1 and KIT IHC in diagnostic panels will improve the accuracy of canine GIST diagnosis.

A sequential study of bone lesions caused by isolates of an avian osteopetrosis virus, MAV-2(0).

The pathogenesis of avian osteopetrosis caused by rapid and slow-onset isolates of myeloblastosis associated virus, MAV-2(0), was studied by inoculation of 10-day-old chick embryos with virus. Femur and calvarium were examined at 15, 17 and 19 days in ovo and 7 and 25 days after hatching by histologic and immunoperoxidase techniques. Femur and calvarium were also examined by electron microscopy at 17 and 19 days in ovo and at 7 days after hatching. Avian osteopetrotic bone lesions were characterized by exuberant periosteal proliferation; the time of onset varied with different virus isolates. In the femur virus was first associated with osteoprogenitor cells, then with osteoblasts and finally with osteocytes as the cells progressed through normal sequences of differentiation. The amount of virus produced by these cells did not correlate with onset of periosteal proliferation. Slow onset isolates provoked early virus production, but proliferative lesions did not develop until later. Conversely, the rapid onset isolate induced little early virus production, although lesions were present. Periosteal proliferation was associated with and preceded by perivascular edema and perivascular cell necrosis within the bone cortex following infection by all isolates. However, the rapid onset isolate caused more severe lesions than other isolates. These lesions included vascular thrombosis, capillary necrosis and focal bone necrosis. The relationship between early vascular lesions and late periosteal proliferation seen with the slow onset isolates is not as clear as with the rapid onset isolate. Calvarial bone, a representative flat bone, was found to have virus present, but at a level less than the femur. Vascular lesions were rarely seen in the calvarium and bone proliferation did not occur at this site.

Late radiation response of the canine trachea with change in dose per fraction.

Seventy-two dogs were given 36 to 74 Gy to the trachea in either 2, 3, or 4 Gy per fraction. Tracheal sections were histologically and morphometrically evaluated 6 months after irradiation to determine the relative percentage of goblet cells, submucosal glands, connective tissue and blood vessels. The percent of each tissue component was plotted against total dose, regression lines calculated and isoeffective doses obtained for construction of isoeffect curves. Probit analysis for probability of surface ulceration also was done. Another group of 32 dogs received either 36, 44, or 52 Gy in 4 Gy fractions and tracheas were similarly analyzed at 1, 3, and 12 months after irradiation. Goblet cells and submucosal glands decreased with increasing total dose in each of the dose per fraction groups while connective tissue increased. Lower doses per fraction had more shallow dose response curves and higher total doses were required to produce an isoeffect. The alpha/beta ratios for tissues at 6 months after irradiation were 3.5 Gy for decrease in goblet cells, 4.7 Gy for probability for surface ulceration, 4.5 Gy for decrease in submucosal glands and 1.8 Gy for increase in connective tissue. Goblet cells and submucosal gland numbers decreased within 1 month and remained significantly decreased at higher doses at 12 months. Although there was no dose response for vasculature volume at 6 months, significant perivascular and intimal fibrosis was observed. This study revealed significant damage to the trachea at high total doses and large doses per fraction. The relatively low alpha/beta ratios obtained indicates that these adverse effects are late effects. Significant sparing of the adverse late effects was present at lower doses per fraction. These results indicate that coarser fractionation schemes that include the trachea in the treatment volume could be potentially dangerous.

Long-term adverse effects of radiation inhibition of restenosis: radiation injury to the aorta and branch arteries in a canine model.

PURPOSE: To determine the long-term effects of irradiation on large arteries in view of the possible use of radiation to prevent restenosis after angioplasty. METHODS AND MATERIALS: Groups of dogs received 10-55 Gy single-dose alone, or in combination with 50 Gy in 2-Gy fractions, or 50-80 Gy in 2-2.7-Gy fractions to an 8-cm length of aorta and branch arteries. Single doses were delivered intraoperatively. Two or 5 years after irradiation, aortas and branch arteries were evaluated histomorphometrically to determine areas of intima, media, and adventitia, and qualitatively to determine other adverse effects. RESULTS: Intimal area increased at single doses < 20 Gy and after all fractionated doses, but was normal at doses > 20 Gy 2 years after irradiation. Intimal area was greater at 5 years than at 2 years after irradiation. Adventitial area increased with increasing dose at 2 and 5 years after irradiation. Thrombosis of the aorta and branch arteries occurred at 4-5 years after irradiation with ED50s of 29.7 Gy and about 25 Gy, respectively, but did not occur after fractionated irradiation. CONCLUSION: Intimal proliferation is inhibited at single doses > 20 Gy, but may be stimulated at single doses of < 20 Gy or after fractionated irradiation. Adventitial fibrosis increases with increasing dose and could contribute to adverse late vascular remodeling. Severe adverse effects were not evident until 4-5 years after irradiation at does of > 20 Gy to an 8-cm vessel length.

Response of the canine lung to fractionated irradiation: pathologic changes and isoeffect curves.

Canine lungs were irradiated with a range of total doses given in 2, 3, or 4 Gy per fraction. Sequential histopathologic evaluations were done at 1, 3, 6, and 12 months. Pathologic changes in canine lungs were found to be similar to those found in other species demonstrating a clinically latent period, a pneumonitis phase, and late fibrosis and vascular damage. The relative impact of endothelial cell and pneumocyte injury on either early or late radiation injury of the lung is difficult to resolve. Therefore, it is not possible to define a target cell for lung injury at this time. The alpha/beta ratios determined in this study indicate that the target cell or cells associated with lung consolidation are slowly proliferating and represent late responding tissues. Lungs were evaluated histomorphometrically for alveolar air space and radiographically for alveolar consolidation at 6 months after irradiation. Alpha/beta ratios of 3 Gy and 4 Gy were calculated respectively. Both assays demonstrated an increasing effect on lung damage with increasing fraction size from 2 to 4 Gy. Application of the LQ model and use of alpha/beta ratios for calculation of dose adjustments remains theoretical. Clinical data are insufficient to define specific alpha/beta ratios for the various normal tissues at risk in radiation therapy. The data are sufficient to demonstrate the sparing effects of decreasing size of dose per fraction for late responding tissue. Results of this study suggest caution against the use of large doses per fraction for radiation therapy fields which include large lung volumes.

Late radiation injury to muscle and peripheral nerves.

Late radiation injury to muscles and peripheral nerves is infrequently observed. However, the success of radiation oncology has led to longer patient survival, providing a greater opportunity for late effects to develop, increase in severity and, possibly, impact the quality of life of the patient. In addition, when radiation therapy is combined with surgery and/or chemotherapy, the risk of late complications is likely to increase. It is clear that the incidence of complications involving muscles and nerves increases with time following radiation. The influence of volume has yet to be determined; however, an increased volume is likely to increase the risk of injury to muscles and nerves. Experimental and clinical studies have indicated that the alpha/beta ratio for muscle is approximately 4 Gy and, possibly, 2 Gy for peripheral nerve, indicating the great influence of fractionation on response of these tissues. This is of concern for intraoperative radiation therapy, and for high dose rate brachytherapy. This review of clinical and experimental data discusses the response of muscle and nerves late after radiation therapy. A grading system has been proposed and endpoints suggested.

Muscle injury following experimental intraoperative irradiation.

The paraaortic region of beagle dogs was irradiated to 15 to 55 Gy intraoperative irradiation, 10 to 47.5 Gy intraoperative irradiation following 50 Gy external beam irradiation in 25 fractions, or 50 to 80 Gy external beam irradiation in 30 fractions. Six MeV electrons were used for intraoperative irradiation, and external beam irradiation was done using photons from a 6 MV linear accelerator. The psoas muscle in the irradiation field was examined histomorphometrically 2 or 5 years after irradiation. The percentage of muscle fibers and capillaries decreased, whereas the percentage of connective tissue increased with increased dose for both intraoperative irradiation only and intraoperative irradiation plus external beam irradiation. The dose causing a 50% decrease in the percentage of muscle fibers was 21.2 Gy and 33.8 Gy at 2 and 5 years, respectively, after intraoperative irradiation alone, and 22.9 Gy and 25.2 Gy at 2 and 5 years, respectively, after intraoperative irradiation combined with 50 Gy external beam irradiation. The ED50 for severe vessel lesions was 19.2 Gy and 25.8 Gy at 2 and 5 years, respectively, after intraoperative irradiation alone and 16.0 Gy and 18.0 Gy at 2 and 5 years, respectively, after intraoperative irradiation combined with 50 Gy external beam irradiation. External beam irradiation alone caused a slight decrease in percentage of muscle fibers with increased dose, and vessel lesions were infrequent or mild. Radiation-induced muscle injury was characterized by loss of muscle fibers, decreased fiber size, severe vessel lesions, hemorrhage, inflammation, coagulation necrosis, and fibrosis. These histopathologic characteristics distinguish this muscle injury from that caused by neurogenic atrophy. These data indicate that radiation-induced muscle injury most likely was caused by injury of the supporting vasculature. The lesions produced were largely a function of the single intraoperative dose rather than the external beam fractionated doses. Furthermore, it appears that 20 to 25 Gy intraoperative irradiation combined with 50 Gy external beam irradiation may be near the maximum tolerated dose by sublumbar musculature and its supporting vasculature.

Aortic wall injury following intraoperative irradiation.

The type, extent, and probability of vasculopathy in canine abdominal aortas were determined 5 years after large single radiation doses given intraoperatively (IORT) either alone or with fractionated doses of external beam irradiation (EBRT) to compare with the response following EBRT only. Young adult beagle dogs were used. For IORT, a 5 x 8 cm electron applicator was used to deliver 6 MeV electrons to the paraaortic region. For EBRT of the paraaortic region, 6 MV photons were given in variable total doses in 30 fractions in 6 weeks. For the combination, variable IORT doses were given following an EBRT dose of 50 Gy given in 2 Gy fractions in 5 weeks. Necropsies were performed 4 to 5 years after irradiation. Transverse sections of the aorta were examined for lesions. Probit analyses were done to determine the dose with a 50% probability to cause severe lesions of the aorta 5 years after treatment. The most severe lesions were variably organized thrombi which occupied at least a third of the luminal area or intimal surface of the aorta. Six dogs with thrombi had dissecting aneurysms. That occurred at doses as low as 25 Gy IORT plus 50 Gy EBRT (1 of 4 dogs). The doses with a 50% probability for causing aneurysms and/or severe thromboses of the aorta were 35 Gy IORT (95% C.I., 29 to 46 Gy) and 27 Gy IORT plus 50 Gy EBRT (95% C.I., 20-40 Gy). No large thrombi or aneurysms were observed 5 years after EBRT to doses as high as 80 Gy. Comparison of the ED50s for IORT alone to that of IORT combined with EBRT indicated that 50 Gy given in 25 fractions had the impact of about 8 Gy IORT. Based on the response of younger adult dogs it appears that IORT doses greater than 30 Gy alone or 20 Gy IORT combined with 50 Gy EBRT would be accompanied by a significant risk of life threatening lesions of the aorta. This is in contrast with several earlier reports indicating that the tolerance dose of canine aorta was 50 Gy IORT.

Bone necrosis and tumor induction following experimental intraoperative irradiation.

The bone of the lumbar vertebrae of 153 dogs was examined 2 and 5 years after intraoperative irradiation (IORT), fractionated external beam irradiation (EBRT), or the combination. Groups of dogs received 15 to 55 Gy IORT only, 10 to 47.5 Gy IORT combined with 50 Gy EBRT in 2 Gy fractions or 60 to 80 Gy EBRT in 30 fractions. Six MeV electrons were used for IORT, and EBRT was done using photons from a 6 MV linear accelerator. The paraaortic region was irradiated and the ventral part of the lumbar vertebrae was in the 90% isodose level. Two years after irradiation, the dose causing significant bone necrosis as determined by at least 50% empty lacunae in the vertebral cortex was 38.2 Gy IORT alone and 32.5 Gy IORT combined with EBRT. Five years after irradiation, the dose causing 50% empty lacunae was 28.5 Gy IORT only and 14.4 Gy IORT combined with EBRT. The ED50 for lesions of the ventral vertebral artery was 21.7 Gy IORT only and 20.1 Gy IORT combined with 50 Gy EBRT 2 years after irradiation and 27.0 Gy IORT only and 20.0 Gy IORT combined with 50 Gy EBRT 5 years after irradiation. All lesions after EBRT only were mild. Eight dogs developed osteosarcomas 4 to 5 years after irradiation, one at 47.5 Gy IORT only and the remainder at 25.0 Gy IORT and above combined with 50 Gy EBRT. In conclusion, the extent of empty lacunae, indicating bone necrosis, was more severe 5 years after irradiation than after 2 years. The effect of 50 Gy EBRT in 2 Gy fractions was equivalent to about 6 Gy IORT 2 years after irradiation and to about 14 Gy 5 years after irradiation. Based on these estimates, IORT doses of 10 to 15 Gy have an effect 5 times or greater than the amount given in 2 Gy fractions. Osteosarcomas occurred in 21% of dogs which received doses greater than 25 Gy IORT. Doses of 15 to 20 Gy IORT in combination with 50 Gy EBRT in 2 Gy fractions may be near the tolerance level for late developing bone injury.

Response of aorta and branch arteries to experimental intraoperative irradiation.

Injury to the aorta was evaluated in dogs 2 and 5 years after fractionated irradiation (EBRT), intraoperative irradiation (IORT) or a combination. Doses greater than 20 Gy IORT combined with 50 Gy EBRT given in 2 Gy fractions or 30 Gy IORT alone were accompanied by a significant risk of aneurysms or large thrombi as determined at necropsy 4 to 5 years following irradiation. Narrowing of the aorta as detected by aortography occurred at 5 years but was not detected earlier. The ED50 for aortic narrowing was 38.8 Gy IORT and 31 Gy IORT plus 50 Gy EBRT. The ED50 for branch artery injury was 24.8 Gy IORT alone and 19.4 Gy IORT plus 50 Gy EBRT. The difference in ED50s for IORT alone and IORT plus EBRT indicates that the contribution of the EBRT dose in terms of an IORT dose for aortic narrowing was 7.8 Gy and for branch artery injury was 5.4 Gy. The ED50 for incidence of small thrombi in the aorta was about 29 Gy for IORT alone and 23.5 Gy for IORT combined with EBRT. Fibrous thickening of the adventitia was measured and the effect of the 50 Gy EBRT component of a combination of EBRT and IORT was determined to be equivalent to 10 to 12 Gy IORT. Based on the various estimates, IORT doses of 10-15 Gy have an effect of 5 times or greater the amount given in 2 Gy fractions. At all EBRT doses and at lower IORT doses the intima was greatly thickened. At IORT doses of 20 Gy or above there was a dose related decrease in intimal thickness to near normal values. This was probably due to cell killing or inhibition of intimal proliferation that predominated at higher doses. Although the risk of serious vascular complications appears low following IORT of humans, this may be due to short observation times and the fact that IORT doses currently used are usually 20 Gy or less; this may be near the tolerance for late response of larger arteries. Only one dog in this study had complete rupture of the aorta causing death. Five other dogs at high IORT doses had near ruptures of the aorta but were clinically normal.

Pathology of radiation injury to the canine spinal cord.

The histopathologic response of the canine spinal cord to fractionated doses of radiation was investigated. Forty-two dogs received 0, 44, 52, 60, or 68 Gy in 4 Gy fractions to the thoracic spinal cord. Dogs were evaluated for neurologic signs and were observed for 1 or 2 years after irradiation. Six major lesion types were observed; five in the irradiated spinal cord and one in irradiated dorsal root ganglia. The three most severe spinal cord lesions were white matter necrosis, massive hemorrhage, and segmental parenchymal atrophy which had an ED50 of 56.9 Gy (51.3-63.3 Gy 95% CI) in 4 Gy fractions. These lesions were consistently associated with abnormal neurologic signs. Radiation damage to the vasculature was the most likely cause of these three lesions. The two less severe spinal cord lesions were focal fiber loss, which had an ED50 of 49.5 Gy (44.8-53.6 Gy 95% CI) in 4 gy fractions and scattered white matter vacuolation that occurred at all doses. These less severe lesions were not consistently associated with neurologic signs and indicated the presence of residual damage that may occur after lower doses of radiation. Radiation damage to glial cells, axons, and/or vasculature were possible causes of these lesions. In the irradiated dorsal root ganglia, affected sensory neurons contained large intracytoplasmic vacuoles, and there was loss of neurons and satellite cells. Such alterations could affect sensory function. The dog is a good model for spinal cord irradiation studies as tolerance doses for lesions causing clinical signs are close to the estimated tolerance doses for humans, and studies involving volume and long-term observation can be done.

Effects of intraoperative irradiation (IORT) and intraoperative hyperthermia (IOHT) on canine sciatic nerve: histopathological and morphometric studies.

PURPOSE/OBJECTIVE: Peripheral neuropathies have emerged as the major dose-limiting complication reported after intraoperative radiation therapy (IORT). The combination of IORT with hyperthermia may further increase the risk of peripheral nerve injury. The objective of this study was to evaluate histopathological and histomorphometric changes in the sciatic nerve of dogs, after IORT with or without hyperthermia treatment. METHODS AND MATERIALS: Young adult beagle dogs were randomized into five groups of 3-5 dogs each to receive IORT doses of 16, 20, 24, 28, or 32 Gy. Six groups of 4-5 dogs each received IORT doses of 12, 16, 20, 24, or 28 Gy simultaneously with 44 degrees C of intraoperative hyperthermia (IOHT) for 60 min. One group of dogs acted as hyperthermia-alone controls. Two years after the treatment, dogs were euthanized, and histopathological and morphometric analyses were performed. RESULTS: Qualitative histological analysis showed prominent changes such as focal necrosis, mineralization, fibrosis, and severe fiber loss in dogs which received combined treatment. Histomorphometric results showed a significantly higher decrease in axon and myelin and small blood vessels, with a corresponding increase in connective tissue in dogs receiving IORT plus hyperthermia treatment. The effective dose for 50% of nerve fiber loss (ED50) in dogs exposed to IORT only was 25.3 Gy. The ED50 for nerve fiber loss in dogs exposed to IORT combined with IOHT was 14.8 Gy. The thermal enhancement ratio (TER) was 1.7. CONCLUSION: The probability of developing peripheral neuropathies in a large animal model is higher when IORT is combined with IOHT, when compared to IORT application alone. To minimize the risk of peripheral neuropathy, clinical treatment protocols for the combination of IORT and hyperthermia should not assume a thermal enhancement ratio (TER) to be lower than 1.5.