A Multi-Institutional Collaboration to Understand Neoplasia, Treatment and Survival of Snakes

Duke, Elizabeth G.; Harrison, Scott H.; Moresco, Anneke; Trout, Tim; Troan, Brigid V.; Garner, Michael M.; Smith, Madison; Smith, Sidney; Harrison, Tara M.

doi:10.3390/ani12030258

Open AccessArticle

A Multi-Institutional Collaboration to Understand Neoplasia, Treatment and Survival of Snakes

by

Elizabeth G. Duke

^1,2

,

Scott H. Harrison

³

,

Anneke Moresco

²

,

Tim Trout

⁴,

Brigid V. Troan

^1,2

,

Michael M. Garner

⁵,

Madison Smith

²

,

Sidney Smith

² and

Tara M. Harrison

^1,2,*

¹

Department of Clinical Sciences, North Carolina State University College of Veterinary Medicine, Raleigh, NC 27607, USA

²

Exotic Species Cancer Research Alliance, North Carolina State University College of Veterinary Medicine, Raleigh, NC 27607, USA

³

Department of Biology, North Carolina Agricultural and Technical State University, Greensboro, NC 27514, USA

⁴

Department of Animal Care, Denver Zoo, Denver, CO 80205, USA

⁵

Northwest ZooPath, Monroe, WA 98272, USA

^*

Author to whom correspondence should be addressed.

Animals 2022, 12(3), 258; https://doi.org/10.3390/ani12030258

Submission received: 24 November 2021 / Revised: 10 January 2022 / Accepted: 18 January 2022 / Published: 21 January 2022

(This article belongs to the Special Issue Biotechnologies for the Advancement of Wildlife Conservation)

Download

Browse Figures

Versions Notes

Abstract

:

Simple Summary

Multiple studies have focused on types of neoplasia found in snakes, but an overall estimation of prevalence including total populations of animals at multiple facilities has not been conducted. Additionally, an in-depth evaluation of methods of therapy and survival of snakes with neoplasia has not been carried out. This study calculated the prevalence of tumors in 133 snakes, representing 65 different species, housed in six zoos and aquariums. Survival times were evaluated to determine whether these snakes were more likely to die from their tumors versus another cause. Treatment outcomes were evaluated to determine if the used treatment types lengthened the snakes’ life spans. Common or northern watersnakes (Nerodia sipedon), eastern diamond-backed rattlesnakes (Crotalus adamanteus), and timber rattlesnakes (Crotalus horridus) had the highest prevalence of tumors. Malignant (cancerous) tumors predominated, and the snakes with these tumors were significantly more likely to die of their cancer than those with benign tumors. Thirty-six of the 133 snakes received treatment for their tumors. There was no significant difference in survival times for those treated and not treated. This population is a subset of the overall snake population under managed human care, and a larger collection of snake tumor and population data could yield different results. Therefore, additional snake cases, along with other non-domestic species, are continuing to be curated in a database (Exotic Species Cancer Research Alliance tumor database). The goal of this data collection is to provide data on a select population of snakes to help veterinarians gain greater understanding of cancer types and to treat cancer in these animals.

Abstract

This multi-institutional collaborative study of neoplasia in snakes reviewed medical records of snakes at each facility to determine species prevalence, survival, and methods of treatment. Complete species numbers of snakes were also collected at each facility. In total, 65 species, 133 snakes, and 149 unique neoplasias were included in this study. Affected species, age, sex, and their tumor prevalence, tumor type and location, metastasis, treatment, and survival data are reported. The highest species-specific tumor prevalence was in Common or Northern Watersnakes (Nerodia sipedon) (30.8%, n = 4 of 13), Eastern Diamond-Backed Rattlesnakes (Crotalus adamanteus) (26.3%, n = 5 of 19), and Timber rattlesnakes (Crotalus horridus) (22.7%, n = 5 of 22). Malignant tumors predominated (86.6%, n = 129 of 149) with soft tissue sarcomas being the most common (30.2%, n = 45 of 149). Snakes with malignant neoplasia, metastases, or indeterminate presence of metastases were statistically more likely to die from their neoplasms than snakes having either benign neoplasia or no diagnosed metastases (p < 0.05). Gender, taxonomic family, and species of those evaluated did not significantly affect the outcome of snakes with neoplasia. Only 27.1% (n = 36 of 133) of snakes received a reported form of treatment and, for those treated, surgical excision was the most common treatment modality. There was not a significant difference in outcome based on treatment; however, surgery and chemotherapy were associated with death from a cause other than their tumor.

Keywords:

Boidae; chemotherapy; Colubridae; neoplasia; oncology; surgery; prevalence; Viperida

1. Introduction

Research involving neoplasia in snakes is not new and in fact has occurred over numerous years involving evaluations of medical cases at the London Zoo, the Registry of Tumors of Lower Animals [1,2,3], and individual laboratories or facilities [4,5,6]. Overall, these previous studies have found that neoplasia appears to be common in snakes [7,8], and it is well shown in the literature that snakes tend to have higher prevalence of cancer reported than other reptiles [7,9]. However, these publications on snake neoplasia have typically focused only on the types of neoplasia diagnosed [10,11], the prevalence of neoplasia at a single institution or laboratory [4,12], or on an individual animal’s treatment [13,14]. A type of multi-institutional study on museum specimens has been done as well as a literature review, however, this study was never able to confirm the presence of neoplasia due to the lack of confirmatory testing [15]. Other studies do exist on reporting snake neoplasia prevalence within a group of snakes, including cutaneous chromatophoromas [11,16,17,18,19]. One of these previous publications evaluated the prevalence of neoplasia from cases submitted to a diagnostic laboratory and they found that the prevalence was highest in Crotalids, Viperids, and Boids [7]. This study, however, only looked at the samples submitted to their laboratory and was unable to evaluate the prevalence based on the populations of animals from where they originated. Additionally, previous studies found that malignant tumors are most commonly reported in snakes, and that they were mesenchymal or epidermal in origin [4,6,7,20].

Previous published literature also is lacking on evaluation of treatments and survival times. Although papers exist on treatments in individual snakes, as well as a report on treatment of other snakes, there is no mention of overall survival time [13,21,22]. Currently, even though snake metabolism is very different from mammal metabolism, current predictions of a snake’s survival with neoplasia are based on survival time in domestic dogs and cats with cancer due to a lack of survival studies in snakes.

The present study therefore focused on (a) investigating the prevalence of neoplasia for snakes housed at six institutions using the combined total population for each snake species at these institutions, and (b) determining if a snake with neoplasia was more likely to die or be euthanized due to neoplasia versus another cause in order to evaluate survival for snakes with neoplasia.

2. Materials and Methods

2.1. Case Selection

Six institutions participated in this study. Complete medical records were obtained for snakes that had a biopsy or necropsy report with a histologic diagnosis of neoplasia. Cases were confirmed to be neoplasia by board-certified veterinary pathologists working at either independent laboratories or university settings. Cases were confirmed to be neoplasia based on the diagnosis in the medical record and classified as to current nomenclature by board-certified veterinary pathologists specializing in zoological medicine cases (Troan, Garner). To determine prevalence for each species, the total number of individuals of that species housed at each institution for a given time were gathered from their respective medical record managers or by obtaining species totals from the Species360 Zoological Information Management System (ZIMS). Population totals included all ages and several snakes that were lost to follow-up or that were transferred to other institutions.

2.2. Medical Records Review

Medical records of the six participating institutions were reviewed. Animals were categorized taxonomically (family and species), by sex (male, female, unknown), and by maturity (adult; juvenile being <3 months of age; or unknown). Diagnoses were grouped by primary histologic diagnosis and behavior (benign versus malignant). All lymphomas or leukemias were designated as malignant due to the multicentric nature of these neoplasms. Animals that had detectable metastases were categorized in the metastasis category. Treatments were separated into general groups including (1) surgery only, (2) chemotherapy (which included steroid therapies and non-steroidal anti-inflammatory drugs (NSAIDs) used longer than 5 days for postoperative analgesia), (3) surgery and chemotherapy (including steroid and nonsteroidal therapies (as above)), (4) supportive care (which included systemic or topical antibiotics and NSAIDs (as above)), (5) unknown treatment, and (6) no treatment provided. Medical records were collected and managed using REDCap electronic data capture tools hosted at North Carolina State University College of Veterinary Medicine [23,24]. REDCap (Research Electronic Data Capture, Vanderbilt University, Nashville, TN, USA) is a secure, web-based software platform designed to support data capture for research studies, providing (1) an intuitive interface for validated data capture; (2) audit trails for tracking data manipulation and export procedures; (3) automated export procedures for seamless data downloads to common statistical packages; and (4) procedures for data integration and interoperability with external sources.

2.3. Data Analysis

Database information was analyzed using IBM Corp. Released 2019. IBM SPSS Statistics for Windows, Version 26.0. Armonk, NY, USA [25] and R statistical computing software (version 3.6.1; R Core Team 2020. R: A language and environment for statistical computing. R foundation for Statistical Computing, Vienna, Austria, https://www.R-project.org/ accessed 18 January 2022) [26]. Prevalence of neoplasia per species was done for those that have greater than 10 total individuals (those with neoplasia and without). Frequencies, survival curve analysis, and boosting analyses were used to evaluate the data. For survival curve analysis, Kaplan–Meier survival curves and log-rank tests were generated with the survminer package (R package version 0.4.1, https://CRAN.R-project.org/package=survminer accessed on 18 January 2022) [27] and survival package (R package version 2.38, https://CRAN.R-project.org/package=survival accessed 18 January 2022) [28]. For the statistical method of boosting, the mboost package (Model-based boosting, R package version 2.6.0, https://CRAN.R-project.org/package=mboost accessed 18 January 2022) [29] was used. Neoplasms were grouped into more general classification categories by behavior (benign vs. malignant) as well as by tissue and tumor type for mboost evaluation of survival of animals affected with these types of neoplasms. For boosting analysis, predictor variables were modeled with the use of btree as a base-learner for decision stumps. The set of eight predictor variables were presence or lack of detectable of metastasis, primary histological diagnosis, type of tumor, number of observed tumor types (1 or 2), type of treatment, taxonomic family, species, and sex. Outcomes were assigned to snakes, with “+1” designated for those that died or were euthanized due to the neoplasm and “0” designated for those that were euthanized due to another cause. Snakes without a known cause of death, or who were lost to follow-up, were excluded from outcome analysis. The modeled effects of the eight predictor variables with outcomes for each animal evaluated were compared to a set of 2000 null model distributions of effects generated from modeling done with permutated outcomes, with p < 0.05 being the threshold of significance regarding the tails of the null model distribution (two-sided hypothesis), similar in method to Mayr et al. [30]. Prevalence was calculated only for species with 10 or more individuals in the study population.

3. Results

3.1. Study Population

A total of 133 snake neoplasia cases representing 65 different species were included. Time spans varied by institution due to medical record accessibility. Time spans were Institution 1: (1985–2018); Institution 2: (2013–2017); Institution 3: (2003–2018); Institution 4: (1974–2018); Institution 5: (1980–2018); and Institution 6: (2002–2018). Participating institutions are located in Colorado, Ohio, North Carolina, and Texas (alphabetical order, see acknowledgements).

3.2. Neoplasia Information

There were 149 neoplasms included in the study. Malignant tumors predominated (86.6%, n = 129 of 149). Only 13 benign tumors were identified (8.7%, n = 13 of 149), and there were 7 unspecified tumors (4.7%, n = 7 of 149) as their behavior was not definitive based on histology. The sex distribution consisted of 67 females, 63 males, and 3 of undetermined sex. Of those with benign neoplasia 4 were females and 5 were males. There were 61 females and 56 males with malignant neoplasia and 2 females and 2 males with unspecified benign or malignant neoplasia. The median age at the time of diagnosis was 138 months, and ages ranged from 42–420 months. The average age of animals with benign neoplasms was 176 months (median 141 months) and the average age of those with malignant neoplasms was 150 months (132 median). Seven individuals were of unknown age. Detectable metastasis was reported in 42.9% (n = 57 of 133) of snakes with neoplasia. Multi-organ involvement existed in 27 snakes, while 17 snakes had multicentric lymphoma or leukemia (Table 1).

3.3. Neoplasia Prevalence

The neoplasia prevalence by taxonomic family (including only those species with 10 or more individuals) ranged from 3.3–7.3% and was not significantly different (χ² = 1.88, p = 0.17) among the various families.

The highest prevalence of neoplasia by species, was in the common or northern watersnake (Nerodia sipedon) (30.8%, n = 4 of 13) followed by the eastern diamond-backed rattlesnake (Crotalus adamanteus) (26.3%, n = 5 of 19) and the timber rattlesnake (Crotalus horridus) (22.7%, n = 5 of 22) (Table 1). The species with the lowest prevalence was the plains gartersnake (Thamnophis radix) (0.8%, n = 4 of 500). Both, the species with the highest neoplasia prevalence (the watersnake) and the species with the lowest prevalence (the plains gartersnake) were from the Colubridae family of snakes. The prevalence of neoplasia was significantly different between these two species, (χ² = 74.13, p < 0.01). Prevalence of neoplasia and total number of snakes per institution are listed in Table 2.

3.4. Treatment

Treatment for neoplasia was administered to 27.1% (n = 36 of 133) of the snakes. Of the 36 snakes that were treated, a survival time was reported in all but three snakes which were euthanized during surgery (Table 3 includes the 33 snakes that reported a survival time). The median survival time was 5.5 months (range 0.25–108 months). The main treatment modality used was surgery (complete or incomplete excision) (97.2%, 35 of 36). Surgery in combination with chemotherapy was employed in three snakes, and surgery and radiation were performed in two snakes. Surgery, chemotherapy, and radiation were all used to treat one snake, and chemotherapy alone was used to treat one snake. Supportive care in the form of antibiotics, fluids, or NSAIDs was used in eight snakes in addition to a treatment modality and used in four snakes without other treatment modalities (Table 3).

3.5. Outcome and Survival

Outcome effects and significance of predictors were estimated and evaluated through boosting and permutation as described, with the outcome effects representing estimates of coefficients in a generalized linear model for death due to tumor, or death due to another cause. Animals with malignant neoplasms were significantly more likely to die of their cancer (p < 0.05) and snakes with benign neoplasms were significantly less likely to die of their cancer (a cause of death other than tumor) (p < 0.5). Chromatophoromas were identified as a neoplasm significantly associated with a cause of death other than tumor (p < 0.05). Snakes without metastases were also significantly associated with a non-tumor-related cause of death (p < 0.05). Snakes with metastases or an unknown condition of metastasis were significantly associated with a tumor-related cause of death (p < 0.05). Number of unique tumors, species and sex were not significantly associated with a cause of death due to neoplastic disease and had absolute values of outcome effect <0.01, with the exception of the Thamnophis radix species having an outcome effect of 0.014. Significant outcome effects for predictor variable values are shown in Table 4.

Cases for other modalities other than surgery were too low to analyze separately, therefore cases treated with multiple modalities (surgery, chemotherapy, and/or radiation) were grouped. Median survival times for no treatment, surgery only, and multiple modalities were 1, 5.5, and 13 months respectively. Survival curves plotted for those snakes that were treated and those that were not, were not significantly different based on a log-rank test (p = 0.3) (Figure 1 and Figure 2).

4. Discussion

By collecting data from multiple institutions, this study reaffirmed that snakes have a tendency to develop malignant neoplasia indicating that histological sampling of masses may be key to early diagnosis and more successful treatment. Additionally, this study calculated species specific prevalence for 65 species and specifically for 44 species in which more than 10 individuals were included which were used to calculate overall family prevalence. The reason to only calculate prevalence for 10 or more individuals was to reduce the potential for inaccurate levels of prevalence to be reported for those species having low numbers of animals. Although this study evaluated neoplasia in 65 species, we were not able to evaluate the prevalence of neoplasia in all snakes due to which species were present at the six institutions evaluated. Therefore, results of this study can only be applied to those that were evaluated and included in this study. It is possible that a potential variation in necropsy techniques or time of death prior to sampling could have impacted the ability to diagnose neoplasia at certain facilities, but we attempted to minimize this through involving multiple facilities. Finally, snakes that received no treatment had lower survival times than those that were treated. This may have been because some snakes showed advanced disease at the time of first diagnosis and therefore were not considered suitable candidates for treatment, or those snakes may have been diagnosed at the time of death due to their cancer and as such would make their survival times lower.

By including both neoplasia cases rising to the level of treatment along with the non-affected population, the inclusion of the latter category by this study has helped address publication bias that has been oriented toward the former. This, further addresses laboratory submission bias as published reports and submitted cases preferentially include cases that are interesting, unique, or survive due to a certain therapy. We also avoided regional bias by including cases from multiple institutions across the United States. This collection of cases from multiple areas also helps to minimize a genetic component. More charismatic, larger or more colorful snakes can sometimes be chosen to be exhibited, which can skew the number of individuals representing a given species of snakes. This bias was likely reduced by using multiple institutions in different areas with different-sized facilities that, together, are less likely to ascribe to any singular modality for choosing a snake species.

The present study documented that the most prevalent neoplasms in snakes were malignant mesenchymal tumors of the skin and soft tissue (n = 45 of 149), malignant tumors of the alimentary system/liver/gallbladder (n = 31 of 149), malignant tumors of mast cell/hemolymphatic/histocytic origin (n = 18 of 149), and malignant tumors of the urinary/genital systems (n = 15 of 149).

We did not find any statistically significant difference in prevalence between families. There was a statistically significant difference in prevalence by species.

We did not find any differences in prognostic outcome between families or genera. These families and genera typically range in size and length. There could potentially be a bias introduced that with smaller or skinnier snakes it may be easier to observe neoplasia than with larger or wider diameter snakes, but as the length and width of the snakes was not routinely recorded in the medical records, it was not able to be evaluated.

It is not surprising that those animals with malignant, metastatic, or indeterminant metastatic neoplasia were more likely to die from the tumor than those with benign or non-metastatic neoplasms. Malignant and metastatic neoplasms tend to negatively affect multiple organ systems, which explains the negative outcome. The only neoplasm that did not contribute significantly to the death of the animal in our data was a chromatophoroma, which is different from previously published literature [16].

Treatment was not commonly performed in the snakes that we evaluated, possibly because very early clinical signs of neoplasia may be limited to subtle changes in behavior or physical appearance which may be difficult to detect during routine husbandry observations. These behavioral cues can include, but are not limited to, changes in feeding behavior, odd body positioning, and increases or decreases in activity [31,32]. External physical changes often are dermal abnormalities such as frequent and/or incomplete ecdysis, areas of discoloration or infection, cutaneous or intracoelomic swellings, or weight changes inconsistent with body condition [21]. Finally, clinical signs may not be observable until widespread (metastatic) or advanced disease. With continued, improved frequency of physical examinations in zoological facilities as well as in those kept as pets and with continued use of diagnostic imaging such as ultrasound, radiographs, and computed tomography (CT) scans, this could aid in diagnosing these neoplasias at an earlier stage prior to metastasis and may allow for additional diagnostics such as fine needle aspirates, biopsies, or surgical removal of masses.

Consistent with previous reports, surgical excision was the most common treatment modality and showed an increase in survival time in certain cases [13,33]. Additionally, a previous study found that even removing a portion of a neoplastic mass had a positive effect on survival, which appeared to be similar to results in this study [34]. Specifically, a cornsnake with a surgically removed soft tissue sarcoma without metastasis had the longest survival time of 108 months compared to other snakes that received some form of treatment specifically for their neoplasia. In general, the only other therapies that had a survival time of greater than 22 months were surgical or surgery and chemotherapy treatments (survival time 84 months). This survival time exceeds that of two other snakes treated with chemotherapy and surgery (5.5 and 20 months) as well as snakes treated with chemotherapy only (11 months) or surgery, chemotherapy, and radiation (12 months). Prior reports of published case reports on radiation and chemotherapy treatments in snakes, documents an increase in survival time for some patients when treated with radiation and chemotherapy as sole treatment therapies, or when used in combination with surgery [3,35]. It must be noted, however, that longer survival times may not necessarily correlate with improved quality of life due to potential side effects of chemotherapy and radiation. Many medical or radiation treatment protocols were extrapolated from domestic animal dosages and frequency schedules, which may not be appropriate for snakes and could account for the lower survival times. Overall, no treatment method demonstrated a statistically significant improvement in prognosis, but this may be due to the low number of treated animals in this study or to the treatment protocols not being tailored to snakes or their neoplasia type. As more frequent examinations occur and diagnostic techniques improve, more cases will be diagnosed and potentially treated, thereby improving our knowledge about neoplastic disease, treatment, and survival in these species.

5. Conclusions

Our data show that snakes have a moderate risk of developing neoplasia, but when they do, it is likely malignant. Surgical excision patients survive longer than patients that received no treatment. Modalities such as chemotherapy and radiation need further refinement to result in prolonged survival times compared to surgical removal only. However, relatively few cases of snakes with cancer were treated in this study. Although data and results collected for this study represent multiple institutions and reduce bias, furthering knowledge of neoplasia prevalence, behavior, and treatment in snakes will benefit from a larger aggregated dataset (www.escra.org (accessed on 18 January 2022)), in particular a larger number of treated cases.

Author Contributions

Conceptualization, T.M.H., E.G.D.; validation, B.V.T.; formal analysis, S.H.H.; data curation, E.G.D., M.S., M.M.G.; writing—original draft preparation, E.G.D., T.M.H., A.M., B.V.T., M.S., S.S.; writing—E.G.D., T.M.H., A.M., B.V.T., S.H.H., T.T., M.M.G.; supervision, T.M.H.; project administration, T.M.H., E.G.D. All authors have read and agreed to the published version of the manuscript.

Funding

This research was funded by the National Institutes of Health, grant number U54 CA217376.

Institutional Review Board Statement

This study was conducted in approval of North Carolina State University’s Institutional Animal Care and Use Committee 21-117.

Informed Consent Statement

Not applicable due to this study consisting of animal patients.

Data Availability Statement

Deidentified data are available through an approved research request to the Exotic Species Cancer Research Alliance (https://escra.cvm.ncsu.edu/ (accessed on 18 January 2022)).

Acknowledgments

The authors thank the following staff for help with gathering data from the zoos’ record systems: Emily Christiansen and Heather Broadhurst (VT) (North Carolina Aquariums), Randy Junge (Columbus Zoo and Aquarium), Larry “Jb” Minter (North Carolina Zoo), Rob Coke (San Antonio Zoo), and Jessica Grote (Denver Zoo).

Conflicts of Interest

The authors declare no conflict of interest.

References

Harshbarger, J.C. Registry of Tumors in Lower Animals; Activities Report Supplement (1974–1977); Museum of Natural History, Smithsonian Institution: Washington, DC, USA; Available online: https://library.si.edu/digital-library/book/activitiesrep19741977regi (accessed on 23 November 2021).
Harshbarger, J.C. Registry of Tumors in Lower Animals; Activities Report Supplement (1978–1981); Museum of Natural History, Smithsonian Institution: Washington, DC, USA; Available online: https://library.si.edu/digital-library/book/activitiesrep19781981regi (accessed on 23 November 2021).
Harshbarger, J.C. Activities Report: Registry of Tumors in Lower Animals; 1965–1973; National Museum of Natural History: Washington, DC, USA, 1974. [Google Scholar]
Catão-Dias, J.L.; Nichols, D.K. Neoplasia in snakes at the National Zoological Park, Washington, DC (1978–1997). J. Comp. Pathol. 1999, 120, 89–95. [Google Scholar] [CrossRef]
Lucke, B.; Schlumberger, H.C. Neoplasia in cold-blooded vertebrates. Physiol. Rev. 1949, 29, 91–126. [Google Scholar] [CrossRef] [PubMed]
Ramsay, E.C.; Munson, L.; Lowenstine, L.; Fowler, M.E. A Retrospective Study of Neoplasia in a Collection of Captive Snakes. J. Zoo Wildl. Med. March 1996, 27, 28–34. [Google Scholar]
Christman, J.; Devau, M.; Wilson-Robles, H.; Hoppes, S.; Rech, R.; Russell, K.E.; Heatley, J.J. Oncology of Reptiles: Diseases, Diagnosis, and Treatment. Vet. Clin. N. Am. Exot. Anim. Pract. 2017, 20, 87–110. [Google Scholar] [CrossRef]
Garner, M.M.; Hernandez-Divers, S.M.; Raymond, J.T. Reptile neoplasia: A retrospective study of case submissions to a specialty diagnostic service. Vet. Clin. N. Am. Exot. Anim. Pract. 2004, 7, 653–671. [Google Scholar] [CrossRef]
Hernandez-Divers, S.M.; Garner, M.M. Neoplasia of reptiles with an emphasis on lizards. Vet. Clin. N. Am. Exot. Anim. Pract. 2003, 6, 251–273. [Google Scholar] [CrossRef]
Dietz, J.; Heckers, K.O.; Aupperle, H.; Pees, M. Cutaneous and Subcutaneous Soft Tissue Tumours in Snakes: A Retrospective Study of 33 Cases. J. Comp. Pathol. 2016, 155, 76–87. [Google Scholar] [CrossRef]
Lamglait, B.; Lemberger, K. Colonic adenocarcinomas in a familial group of captive amur rat snakes (elaphe schrencki). J. Zoo Wildl. Med. 2017, 48, 491–496. [Google Scholar] [CrossRef]
Sykes, J.M.; Trupkiewicz, J.G. Reptile neoplasia at the Philadelphia Zoological Garden, 1901–2002. J. Zoo Wildl. Med. 2006, 37, 11–19. [Google Scholar] [CrossRef]
Kaye, S.W.; Daverio, H.; Eddy, R.; Ossiboff, R.J.; Peters-Kennedy, J.; Morrisey, J.K. Surgical resection of an interrenal cell adenocarcinoma in a woma python (Aspidites ramsayi) with 18 month follow-up. J. Herpetol. Med. Surg. 2016, 26, 26–31. [Google Scholar] [CrossRef]
Summa, N.M.; Guzman, D.S.M.; Hawkins, M.G.; Grosset, C.; Chen, V.S.; Goldsmith, D.; Keel, K.; Woolard, K.; Young, A.C.; Bucy, D.S.; et al. Tracheal and colonic resection and anastomosis in a boa constrictor (Boa constrictor) with T-cell lymphoma. J. Herpetol. Med. Surg. 2015, 25, 87–99. [Google Scholar] [CrossRef]
Hall, A.S.; Jacobs, J.L.; Smith, E.N. Possible osteosarcoma reported from a new world elapid snake and review of reptilian bony tumors. Anat. Rec. 2020, 303, 2955–2966. [Google Scholar] [CrossRef]
Muñoz-Gutiérrez, J.F.; Garner, M.M.; Kiupel, M. Cutaneous Chromatophoromas in Captive Snakes. Vet. Pathol. 2016, 53, 1213–1219. [Google Scholar] [CrossRef]
Page-Karjian, A.; Hahne, M.; Leach, K.; Murphy, H.; Lock, B.; Rivera, S. Neoplasia in snakes at zoo atlanta during 1992–2012. J. Zoo Wildl. Med. 2017, 48, 521–524. [Google Scholar] [CrossRef]
Pereira, M.E.; Viner, T.C. Oviduct adenocarcinoma in some species of captive snakes. Vet. Pathol. 2008, 45, 693–697. [Google Scholar] [CrossRef] [Green Version]
Taggart, P.L.; Woolford, L.; Dunstan, N.; Allen, L.; Buote, M.; Lindsay, S.A. Cutaneous Chromatophoromas in Four Species of Australian Elapid Snake. J. Comp. Pathol. 2021, 183, 33–38. [Google Scholar] [CrossRef]
Elkan, E.; Cooper, J.E. Tumours and pseudotumours in some reptiles. J. Comp. Pathol. 1976, 86, 337–348. [Google Scholar] [CrossRef]
Anderson, E.T.; Kennedy-Stoskopf, S.; Sandy, J.R.; Dorn, B.; Boyette, T.; Harms, C.A. Squamous cell carcinoma with vascular invasion in a diamondback rattlesnake (Crotalus adamanteus). J. Zoo Wildl. Med. 2010, 41, 745–748. [Google Scholar] [CrossRef] [PubMed]
Frye, F.L. Diagnosis and surgical treatment of reptilian neoplasms with a compilation of cases 1966–1993. Vivo 1994, 8, 885–892. [Google Scholar]
Harris, P.; Taylor, R.; Minor, B.; Elliott, V.; Fernandez, M.; O’Neal, L.; McLeod, L.; Delacqua, G.; Delacqua, F.; Kirby, J.; et al. The REDCap consortium: Building an international community of software partners. J. Biomed. Inform. 2019, 95, 103208. [Google Scholar] [CrossRef] [PubMed]
Harris, P.; Taylor, R.; Thielke, R.; Payne, J.; Gonzalez, N.; Conde, J. Research electronic data capture (REDCap)—A metadata-driven methodology and workflow process for providing translational research informatics support. J. Biomed. Inform. 2009, 42, 377–381. [Google Scholar] [CrossRef] [PubMed] [Green Version]
IBM Corp. IBM SPSS Statistics for Windows, 26.0; IBM Corp: Armonk, NY, USA, 2019. [Google Scholar]
Team, R.C. R: A Language and Environment for Statistical Computing; R Foundation for Statistical Computing: Vienna, Austria, 2019. [Google Scholar]
Kassambara, A.; Kosinski, M.; Biecek, P. Survminer: Drawing Survival Curves Using ‘ggplot2’. R package version 0.4.9. 2021. Available online: https://CRAN.R-project.org/package=survminer (accessed on 18 January 2022).
Therneau, T. A Package for Survival Analysis in S. version 2.38. 2015. Available online: https://CRAN.R-project.org/package=survival (accessed on 18 January 2022).
Hothorn, T.; Buehlmann, P.; Kneib, T.; Schmid, M.; Hofner, B. M Boost: Model-Based Boosting. R package version 2.6.0. 2018. Available online: https://CRAN.R-project.org/package=mboost (accessed on 18 January 2022).
Mayr, A.; Hofner, B.; Waldmann, E.; Hepp, T.; Meyer, S.; Gefeller, O. An Update on Statistical Boosting in Biomedicine. Comput. Math. Methods Med. 2017, 2017, 6083072. [Google Scholar] [CrossRef] [PubMed] [Green Version]
Baron, H.R.; Allavena, R.; Melville, L.M.; Doneley, R.J.T. Gastric adenocarcinoma in a diamond python (Morelia spilota spilota). Aust. Vet. J. 2014, 92, 405–409. [Google Scholar] [CrossRef]
Steeil, J.C.; Schumacher, J.; Hecht, S.; Baine, K.; Ramsay, E.C.; Ferguson, S.; Miller, D.; Lee, N.D. Diagnosis and treatment of a pharyngeal squamous cell carcinoma in a Madagascar ground boa (Boa madagascariensis). J. Zoo Wildl. Med. 2013, 44, 144–151. [Google Scholar] [CrossRef] [PubMed]
Diethelm, G.; Stauber, E.; Tillson, M.; Ridgley, S. Tracheal resection and anastomosis for an intratracheal chondroma in a ball python. J. Am. Vet. Med. Assoc. 1996, 209, 786–788. [Google Scholar]
Hopewell, E.; Harrison, S.H.; Posey, R.; Duke, E.; Troan, B.; Harrison, T.M. Analysis of Published Amphibian Neoplasia Case Reports. J. Herpetol. Med. Surg. 2020, 30, 148–155. [Google Scholar] [CrossRef]
Bryant, B.R.; Vogelnest, L.; Hulst, F. The use of cryosurgery in a diamond python, Morelia spilota spilota, with fibrosarcoma and radiotherapy in a common death adder, Acanthophis antarcticus, with melanoma. Bull. Assoc. Reptil. Amphib. Vet. 1997, 7, 9–12. [Google Scholar] [CrossRef]

Figure 1. Overall survival curve of snakes treated for their neoplasia.

Figure 2. Overall survival curve of snakes not treated for their neoplasia.

Table 1. Tumor Type and Prevalence by Species.

Family	Species and Prevalence	Common Name	Benign	Malignant	Unspecified
Boidae	Acrantophis dumerili 2.4% (1/41)	Dumeril’s Ground Boa		(1) Soft Tissue Sarcoma
	Boa constrictor 14.3% (2/14)	Boa Constrictor		(1) Neuroendocrine Tumor (1) Soft Tissue Sarcoma
	Chilabothrus granti 7.7% (1/13)	Virgin Islands Boa		(1) Thyroid Carcinoma (1) Hepatocellular Carcinoma
	Eunectes murinus 4.3% (1/23)	Green Anaconda			(1) Sertoli Cell Tumor
	Lichanura trivirgata 15.8% (3/19)	Rosy Boa	(1) Pancreatic Adenoma	(1) Undifferentiated Carcinoma (1) Histiocytic Sarcoma
	Sanzinia madagascariensis 20.0% (1/5)	Madagascar Tree Boa		(1) Soft Tissue Sarcoma
Colubridae	Coelognathus radiatus 4% (4/101)	Radiated Ratsnake		(2) Hepatocellular Carcinoma (1) Lymphoma/Leukemia (1) Renal Adenocarcinoma
	Elaphe taeniura 11.1% (1/9)	Taiwan Beauty Snake		(1) Soft Tissue Sarcoma
	Heterodon nasicus 10.3% (3/29)	Western Hog-Nosed Snake		(2) Hepatocellular Carcinoma (1) Soft Tissue Sarcoma
	Heterodon platirhinos 25.0% (2/8)	Eastern Hog-Nosed Snake		(1) Soft Tissue Sarcoma (1) Malignant Chromatophoroma (unspecified)
	Lampropeltis getula 17.9% (5/28)	Kingsnake	(1) Renal Adenoma	(3) Soft Tissue Sarcoma (1) Renal Carcinoma (1) Hepatic Adenocarcinoma	(1) Chromatophoroma (iridophoroma)
	Lampropeltis triangulum 1.8% (1/56)	Eastern Milksnake		(1) Gastrointestinal Adencocarcinoma
	Leioheterodon madagascariensis 1.3% (1/78)	Madagascar Giant Hognose Snake		(1) Osteosarcoma
	Nerodia sipedon 30.8% (4/13)	Common Or Northern Watersnake		(3) Soft Tissue Sarcoma (1) Malignant Chromatophoroma (iridophoroma) (1) Malignant Chromatophoroma (Uncharacterized)
	Oreocryptophis porphyraceus 5.3% (1/19)	Black-Banded Trinket Snake		(1) Hepatocellular Carcinoma
	Pantherophis guttatus 9.6% (11/115)	Corn snake		(1) Granulosa Cell Tumor (1) Lymphoma/Leukemia (7) Soft Tissue Sarcoma (1) Osteosarcoma (2) Hemangiosarcoma
	Pantherophis obsoletus (Or) alleghaniensis 7.4% (14/189)	Ratsnake		(5) Soft Tissue Sarcoma (1) Gastrointestinal Adencocarcinoma (1) Renal Carcinoma (1) Chondrosarcoma (4) Lymphoma/leukemia (1) Osteosarcoma	(1) Granulosa Cell Tumor
	Pituophis catenifer 5.4% (2/37)	Gophersnake (or) Bullsnake		(2) Hepatobiliary Carcinoma
	Pituophis lineaticollis 25.0% (1/4)	Middle American Gophersnake		(1) Undifferentiated Carcinoma
	Pituophis ruthveni 2.4% (1/42)	Louisiana Pinesnake		(1) Soft Tissue Sarcoma
	Rhamphiophis oxyrhynchus 14.3% (1/7)	Rufous-Beaked Snake		(1) Neuroendocrine Tumor
	Rhinocheilus lecontei 16.7% (1/6)	Long-Nosed Snake		(1) Gastrointestinal Adencocarcinoma
	Rhynchophis boulengeri 5.3% (1/19)	Rhinoceros Snake		(1) Lymphoma/Leukemia
	Salvadora bairdi 4.8% (1/21)	Baird’s Patchnose Snake		(1) Renal Adenocarcinoma
	Thamnophis cyrtopsis 100.0% (1/1)	Black-Necked Gartersnake		(1) Malignant Chromatophoroma (Melanoma)
	Thamnophis exsul 10.5% (2/19)	Exiled Gartersnake	(2) Biliary Cystadenoma
	Thamnophis radix (4) 0.8% (4/500)	Plains Gartersnake		(1) Malignant Chromatophoroma (Melanoma) (1) Granulosa Cell Tumor (1) Undifferentiated Carcinoma (1) Hepatocellular Carcinoma
	Thamnophis sirtalis 100.0% (1/1)	Common Gartersnake	(1) Biliary Cystadenoma	(1) Squamous Cell Carcinoma
	Trimorphodon lambda 25.0% (1/4)	Sonoran Lyresnake		(1) Renal Carcinoma
Elapidae	Hemachatus haemachatus 14.3% (2/14)	Ringhals Cobra		(1) Lymphoma/Leukemia (1) Gastrointestinal Adencocarcinoma
	Hydrodynastes gigas 1.4% (1/72)	False Water Cobra		(1) Renal Adenocarcinoma (1) Pancreatic Adenocarcinoma
	Naja pallida 3.8% (1/26)	Red Spitting Cobra		(1) Renal Adenocarcinoma
	Ophiophagus hannah 15.4% (2/13)	King Cobra	(1) Granulosa Cell Tumor	(1) Lymphoma/Leukemia (1) Undifferentiated Adenocarcinoma
Pythonidae	Antaresia childreni 2.3% (1/44)	Children’s Python		(1) Lymphoma/Leukemia (1) Soft Tissue Sarcoma
	Liasis mackloti 50.0% (1/2)	Macklot’s Python		(1) Lymphoma/Leukemia
	Malayopython reticulatus 25.0% (1/4)	Reticulated Python		(1) Hepatocellular Carcinoma
	Morelia spilota 12.5% (1/8)	Carpet Python		(1)Esophageal Carcinoma
	Morelia viridis 1.7% (1/59)	Green Tree Python		(1) Squamous Cell Carcinoma
	Python bivittatus 12.5% (1/8)	Burmese Python		(1) Soft Tissue Sarcoma
	Python regius 10.5% (2/19)	Ball Python		(1) Squamous Cell Carcinoma (1) Gastrointestinal Adenocarcinoma	(1) Chromatophoroma (melanophoroma)
Viperidae	Agkistrodon contortrix 37.5% (3/8)	Copperhead	(2) Hepatocellular Adenoma	(1) Lymphoma/Leukemia
	Agkistrodon piscivorus 18.2% (2/11)	Cottonmouth		(1) Soft Tissue Sarcoma (1) Lymphoma/Leukemia
	Atheris squamigera 7.4% (2/27)	African Bush Viper		(1) Hepatic Cystadenocarcinoma (1) Oviduct Adenocarcinoma
	Bitis arietans 50.0% (2/4)	Puff Adder		(1) Renal Carcinoma (1) Soft Tissue Sarcoma
	Bitis nasicornis 5.9% (3/51)	Rhinoceros Viper		(1) Renal Adenocarcinoma (1) Cholangiocellular carcinoma (1) Renal Carcinoma (1) Lymphoma/Leukemia
	Bothriechis rowleyi 4.2% (2/48)	Rowley’s Palm Pit Viper		(1) Soft Tissue Sarcoma (1) Squamous Cell Carcinoma
	Bothriechis schlegelii 4.4% (2/45)	Eyelash Viper		(2) Soft Tissue Sarcoma
	Bothrops asper 2.4% (1/41)	Terciopelo	(1) Renal Cystadenoma	(1) Soft Tissue Sarcoma
	Crotalus adamanteus 26.3% (5/19)	Eastern Diamond-Backed Rattlesnake		(2) Soft Tissue Sarcoma (1) Lymphoma/Leukemia (1) Squamous Cell Carcinoma (1) Hemangiosarcoma	(1) Sertoli Cell Tumor
	Crotalus atrox 9.5% (2/21)	Western Diamond-Backed Rattlesnake		(1) Renal Adenocarcinoma (1) Cholangiocellular Carcinoma	(1) Sertoli Cell Tumor
	Crotalus cerastes 20.0% (1/5)	Sidewinder	(1) Hepatic Adenoma		(1) Chromatophoroma (Melanophoroma)
	Crotalus culminatus 3.6% (2/55)	Northwestern Neotropical Rattlesnake		(1) Soft Tissue Sarcoma (1) Biliary Adenocarcinoma
	Crotalus horridus 22.7% (5/22)	Timber Rattlesnake	(1) Lipoma	(3) Soft Tissue Sarcoma (1) Ovarian Carcinoma
	Crotalus lepidus 14.3% (1/7)	Rock Rattlesnake	(1) Hepatic Adenoma	(1) Malignant Chromatophoroma (Melanophoroma)
	Crotalus molossus 20.0% (1/5)	Black-Tailed Rattlesnake		(1) Soft Tissue Sarcoma (1) Hepatocellular Carcinoma
	Crotalus viridis 20.0% (1/5)	Prairie Rattlesnake		(1) Hepatocellular Carcinoma (1) Soft Tissue Sarcoma
	Lachesis muta 15.4% (2/13)	South American Bushmaster		(2) Hepatocellular Carcinoma
	Montivipera raddei 7.7% (1/13)	Armenian Viper		(1) Pancreatic Carcinoma
	Protobothrops flavoviridis 16.7% (1/6)	Habu		(1) Soft Tissue Sarcoma
	Sistrurus catenatus 25.0% (1/4)	Eastern Massasauga		(1) Osteosarcoma
	Sistrurus miliarius 14.3% (2/14)	Pygmy Rattlesnake	(1) Pancreatic Adenoma	(1) Biliary Adenocarcinoma
	Trimeresurus flavomaculatus 10.0% (1/10)	Philippine Pit Viper		(1) Lymphoma/Leukemia
	Trimeresurus mcgregori 2.3% (1/44)	McGregor’s Tree Viper		(1) Soft Tissue Sarcoma
	Trimeresurus sumatranus 1.4% (1/74)	Sumatran Pit Viper		(1) Lymphoma/Leukemia
	Vipera transcaucasiana 5.3% (1/19)	Transcaucasian Long-Nosed Viper		(1) Soft Tissue Sarcoma

Table 2. Prevalence of neoplasia at each participating institution.

Institution	Total Snakes with Neoplasia	Total Number of Snakes of Affected Species	Number of Different Affected Species	Prevalence
1	32	162	20	19.8%
2	10	72	4	13.9%
3	16	77	9	20.8%
4	19	250	14	7.6%
5	31	651	26	4.8%
6	25	1049	16	2.4%

Table 3. Treatment and Survival.

Family	Common Name/Scientific Name	Tumor (s)	Survival in Months	Treatment ± Supportive Care
Boidae	Boa constrictor Boa constrictor	Benign carcinoid tumor	0.25	none
	Boa constrictor Boa constrictor	Soft tissue sarcoma	1	surgical excision only
	Rosy boa Lichanura trivirgata	Histiocytic sarcoma	7	surgical excision only
	Madagascar tree boa Sanzinia madagascariensis	Soft tissue sarcoma	22	surgical excision only
Colubridae	Western hog-nosed snake Heterodon nasicus	Hepatocellular carcinoma	10	none
	Western hog-nosed snake Heterodon nasicus	Soft tissue sarcoma	6	surgical excision *
	Eastern hog-nosed snake Heterodon platirhinos	Soft tissue sarcoma	15.5	none
	Kingsnake Lampropeltis getula	Soft tissue sarcoma, Hepatocellular adenocarcinoma	10.5	none
	Kingsnake Lampropeltis getula	Soft tissue sarcoma, Chromatophoroma (uncharacterized)	8	surgical excision only
	Common or northern watersnake Nerodia sipedon	Soft tissue sarcoma, Malignant chromatophoroma	5	surgical excision *
	Common or northern watersnake Nerodia sipedon	Malignant chromatophoroma	1	surgical excision only
	Common or northern watersnake Nerodia sipedon	Soft tissue sarcoma	0.5	surgical excision only
	Corn snake Pantherophis guttatus	Soft tissue sarcoma	2	none
	Corn snake Pantherophis guttatus	Soft tissue sarcoma	12	surgical excision and radiation and chemotherapy (Piroxicam) *
	Corn snake Pantherophis guttatus	Hemangiosarcoma	2	surgical excision only
	Corn snake Pantherophis guttatus	Soft tissue sarcoma	108	surgical excision only *
	Corn snake Pantherophis guttatus	Soft tissue sarcoma	18	surgical excision and radiation
	Corn snake Pantherophis guttatus	Soft tissue sarcoma	5.5	surgical excision and chemotherapy (Cyclophosphamide and Piroxicam)
	Ratsnake Pantherophis obsoletus or alleghaniensis	Colonic adenocarcinoma	7	surgical excision only *
	Ratsnake Pantherophis obsoletus or alleghaniensis	Chondrosarcoma	15	none
	Ratsnake Pantherophis obsoletus or alleghaniensis	Leukemia	1	none
	Ratsnake Pantherophis obsoletus or alleghaniensis	Osteosarcoma	6	supportive care only *
	Ratsnake Pantherophis obsoletus or alleghaniensis	Soft tissue sarcoma	4	surgical excision only
	Gophersnake(or) Bullsnake Pituophis catenifer	Hepatocellular carcinoma	1	none
	Black-necked gartersnake Thamnophis cyrtopsis	Malignant chromatophoroma	5.5	surgical excision only
	Plains gartersnake Thamnophis radix	Malignant chromatophoroma	13	surgical excision and radiation
	Plains gartersnake Thamnophis radix	Malignant granulosa cell tumor	1	surgical excision only
	Common gartersnake Thamnophis sirtali	Squamous cell carcinoma	9	not known
Elapidae	Ringhals cobra Hemachatus haemachatus	Lymphoma	0.75	none
	False water cobra Hydrodynastes gigas	Renal and Pancreatic adenocarcinoma	71	surgical excision only
	Red spitting cobra Naja pallida	Renal carcinoma/adenocarcinoma	35	surgical excision only
	King cobra Ophiophagus hannah	Lymphoma	11	chemotherapy only (Lomustine)
Pythonidae	Children’s python Antaresia childreni	Lymphoma, Soft tissue sarcoma	3	surgical excision only
	Carpet python Morelia spilota	Esophageal carcinoma	2.5	surgical excision only
	Green tree python Morelia viridis	Squamous cell carcinoma	7	not known
	Burmese python Python bivittatus	Soft tissue sarcoma	1	surgical excision only
	Ball python Python regius	Squamous cell carcinoma	84	surgical excision and chemotherapy (Carboplatin) *
Viperidae	Cottonmouth Agkistrodon piscivorus	Soft tissue sarcoma	0.25	surgical excision only
	Eyelash viper Bothriechis schlegelii	Soft tissue sarcoma	16	surgical excision only
	Eyelash viper Bothriechis schlegelii	Soft tissue sarcoma	5	none
	Eastern diamond-backed rattlesnake Crotalus adamanteus	Lymphoma	20	surgical excision and chemotherapy (Cyclophosphamide)
	Eastern diamond-backed rattlesnake Crotalus adamanteus	Squamous cell carcinoma	18.5	surgical excision only
	Eastern diamond-backed rattlesnake Crotalus adamanteus	Hemangiosarcoma, Sertoli cell tumor (uncharacterized)	7	surgical excision only
	Sidewinder Crotalus cerastes	Chromatophoroma (uncharacterized), Hepatobiliary adenoma	1	none
	Timber rattlesnake Crotalus horridus	Ovarian carcinoma	0.25	none
	Timber rattlesnake Crotalus horridus	Soft tissue sarcoma	0.25	none
	Timber rattlesnake Crotalus horridus	Soft tissue sarcoma	1	surgical excision only
	Timber rattlesnake Crotalus horridus	Lipoma	24	surgical excision only
	Rock rattlesnake Crotalus lepidus	Malignant chromatophoroma, Hepatobiliary adenoma	1	none
	Prairie rattlesnake Crotalus viridis	Hepatocellular carcinoma, Soft tissue sarcoma	1	none
	South american bushmaster Lachesis muta	Hepatocellular carcinoma/adenocarcinoma	3	none
	Eastern massasauga Sistrurus catenatus	Osteosarcoma	3.5	surgical excision *
	Sumatran pit viper Trimeresurus sumatranus	Lymphoma	0.36	none

* A nonsteroidal anti-inflammatory (NSAID) was also used less than 5 days for pain control.

Table 4. Predictor variable values of snakes that had a significant association with tumor versus non-tumor causes of death based on boosting and comparing each variable’s modeled outcome effect to null model distribution of effects generated from modeling done with permutated cause of death outcomes (p < 0.05).

Predictor Variable	Predictor Variable Value	Sample Size ^a	Outcome Effect ^b
Type of Neoplasm	Malignant	112	0.71
Type of Neoplasm	Benign	9	−0.71
Metastasis (Yes/No)	Yes	56	0.060
Metastasis (Yes/No)	Unknown Metastasis	2	0.060
Metastasis (Yes/No)	No	63	−0.055
Tumor Type	Chromatophoroma	4	−0.20

^a This is a subset of clinical case counts for which there were specific values reported across the set of eight predictor variables with a determined outcome of death due to tumor or death due to another cause. In the case of multiple tumor types and status of being malignant or benign, the tally and modeling is based on random sampling of a tumor type and its associated status for each clinical case. ^b Outcome effects are relative to death due to tumor or death due to another cause with each clinical case scored as +1 and 0 respectively.

Publisher’s Note: MDPI stays neutral with regard to jurisdictional claims in published maps and institutional affiliations.

© 2022 by the authors. Licensee MDPI, Basel, Switzerland. This article is an open access article distributed under the terms and conditions of the Creative Commons Attribution (CC BY) license (https://creativecommons.org/licenses/by/4.0/).

Share and Cite

MDPI and ACS Style

Duke, E.G.; Harrison, S.H.; Moresco, A.; Trout, T.; Troan, B.V.; Garner, M.M.; Smith, M.; Smith, S.; Harrison, T.M. A Multi-Institutional Collaboration to Understand Neoplasia, Treatment and Survival of Snakes. Animals 2022, 12, 258. https://doi.org/10.3390/ani12030258

AMA Style

Duke EG, Harrison SH, Moresco A, Trout T, Troan BV, Garner MM, Smith M, Smith S, Harrison TM. A Multi-Institutional Collaboration to Understand Neoplasia, Treatment and Survival of Snakes. Animals. 2022; 12(3):258. https://doi.org/10.3390/ani12030258

Chicago/Turabian Style

Duke, Elizabeth G., Scott H. Harrison, Anneke Moresco, Tim Trout, Brigid V. Troan, Michael M. Garner, Madison Smith, Sidney Smith, and Tara M. Harrison. 2022. "A Multi-Institutional Collaboration to Understand Neoplasia, Treatment and Survival of Snakes" Animals 12, no. 3: 258. https://doi.org/10.3390/ani12030258

APA Style

Duke, E. G., Harrison, S. H., Moresco, A., Trout, T., Troan, B. V., Garner, M. M., Smith, M., Smith, S., & Harrison, T. M. (2022). A Multi-Institutional Collaboration to Understand Neoplasia, Treatment and Survival of Snakes. Animals, 12(3), 258. https://doi.org/10.3390/ani12030258

Note that from the first issue of 2016, this journal uses article numbers instead of page numbers. See further details here.

Article Menu

A Multi-Institutional Collaboration to Understand Neoplasia, Treatment and Survival of Snakes

Abstract

Simple Summary

Abstract

1. Introduction

2. Materials and Methods

2.1. Case Selection

2.2. Medical Records Review

2.3. Data Analysis

3. Results

3.1. Study Population

3.2. Neoplasia Information

3.3. Neoplasia Prevalence

3.4. Treatment

3.5. Outcome and Survival

4. Discussion

5. Conclusions

Author Contributions

Funding

Institutional Review Board Statement

Informed Consent Statement

Data Availability Statement

Acknowledgments

Conflicts of Interest

References

Share and Cite

Article Metrics

Article Access Statistics

Further Information

Guidelines

MDPI Initiatives

Follow MDPI