Your search keyword '"Werth AJ"' showing total 31 results

1. Peer Review #1 of "Morphological variation of the relictual alveolar structures in the mandibles of baleen whales (v0.1)"

Author

Werth, AJ, additional

Published

2021

2. The impact of hormones in autoimmune cutaneous diseases.

Author

Lopes Almeida Gomes L, Werth AJ, Thomas P, and Werth VP

Subjects

Pregnancy, Male, Infant, Newborn, Humans, Female, Hormones, Gonadal Steroid Hormones, Menopause, Autoimmune Diseases drug therapy, Breast Neoplasms, Lupus Erythematosus, Systemic

Abstract

Introduction: Dermatomyositis, systemic and cutaneous lupus erythematosus have a significantly higher prevalence in women than men, emphasizing the relevance of exploring the relationship between sex hormones and autoimmune skin diseases. This review analyzes the interplay between sex hormones and these two skin diseases., Materials and Methods: We performed an extensive literature search using the PubMed database from July to August 2023. Search terms included 'contraceptives', 'pregnancy', 'hormone replacement', 'tamoxifen', and 'aromatase inhibitors'., Results and Discussion: This comprehensive literature review shows that there remains considerable debate regarding the use of hormonal contraceptives and hormonal replacement therapy in individuals with autoimmune skin conditions. Nonetheless, it is well established that their use is contraindicated in patients with antiphospholipid syndrome or when antiphospholipid antibodies are positive. Individuals experiencing disease flares and uncontrolled symptoms should also avoid these interventions. Pregnancy planning should be timed to coincide with well-managed disease states to minimize obstetric and neonatal complications. Hormonal breast cancer treatment requires close skin monitoring., Conclusion: Pregnancy, menopause, contraceptive use, hormone replacement therapy, and breast cancer treatment drugs result in substantial shifts in hormone levels. Additionally, hormone levels are altered by aromatase inhibitors and anti-estrogen medications. These fluctuations can modulate mechanisms influencing autoimmune skin abnormalities.

Published

2024

3. Cetacean tongue mobility and function: A comparative review.

Author

Werth AJ and Crompton AW

Subjects

Animals, Male, Sheep, Tongue, Biological Evolution, Water, Feeding Behavior, Cetacea anatomy & histology

Abstract

Cetaceans are atypical mammals whose tongues often depart from the typical (basal) mammalian condition in structure, mobility, and function. Their tongues are dynamic, innovative multipurpose tools that include the world's largest muscular structures. These changes reflect the evolutionary history of cetaceans' secondary adaptation to a fully aquatic environment. Cetacean tongues play no role in mastication and apparently a greatly reduced role in nursing (mainly channeling milk ingestion), two hallmarks of Mammalia. Cetacean tongues are not involved in drinking, breathing, vocalizing, and other non-feeding activities; they evidently play no or little role in taste reception. Although cetaceans do not masticate or otherwise process food, their tongues retain key roles in food ingestion, transport, securing/positioning, and swallowing, though by different means than most mammals. This is due to cetaceans' aquatic habitat, which in turn altered their anatomy (e.g., the intranarial larynx and consequent soft palate alteration). Odontocetes ingest prey via raptorial biting or tongue-generated suction. Odontocete tongues expel water and possibly uncover benthic prey via hydraulic jetting. Mysticete tongues play crucial roles driving ram, suction, or lunge ingestion for filter feeding. The uniquely flaccid rorqual tongue, not a constant volume hydrostat (as in all other mammalian tongues), invaginates into a balloon-like pouch to temporarily hold engulfed water. Mysticete tongues also create hydrodynamic flow regimes and hydraulic forces for baleen filtration, and possibly for cleaning baleen. Cetacean tongues lost or modified much of the mobility and function of generic mammal tongues, but took on noteworthy morphological changes by evolving to accomplish new tasks., (© 2023 Anatomical Society.)

Published

2023

4. HPV51-associated Leiomyosarcoma: A Novel Class of TP53/RB1-Wildtype Tumor With Predilection for the Female Lower Reproductive Tract.

Author

Williams EA, Montesion M, Lincoln V, Tse JY, Hiemenz MC, Mata DA, Shah BB, Shoroye A, Alexander BM, Werth AJ, Foley-Peres K, Milante RR, Ross JS, Ramkissoon SH, Williams KJ, Adhikari LJ, Zuna RE, LeBoit PE, Lin DI, and Elvin JA

Subjects

Female, Humans, In Situ Hybridization, Middle Aged, Papillomaviridae genetics, Retinoblastoma Binding Proteins genetics, Tumor Suppressor Protein p53 genetics, Ubiquitin-Protein Ligases genetics, Leiomyosarcoma genetics, Leiomyosarcoma pathology, Papillomavirus Infections

Abstract

Inactivating mutations in tumor suppressor genes TP53 and RB1 are considered central drivers in leiomyosarcomas (LMSs). In high-risk human papillomavirus (HPV)-related tumors, a similar functional outcome is achieved through oncoproteins E6 and E7, which inactivate the p53 and RB1 proteins, respectively. Here, we hypothesized that HPV infection could provide an alternative mechanism for tumorigenesis in a subset of TP53/RB1-wildtype LMS. We evaluated tumor samples from 2585 consecutive unique patients carrying a diagnosis of gynecologic or soft tissue LMS. Tumor DNA and available RNA were analyzed by hybrid-capture-based next-generation sequencing/comprehensive genomic profiling of 406 genes and transcripts (FoundationOneHeme). Of the initial 2585 cases, we excluded 16 based on the presence of molecular alterations that are considered defining for sarcomas other than LMS. In the remaining 2569 cases, we searched for LMS that were TP53/RB1-wildtype (n=486 of 2569; 18.9%). We also searched LMS tumors for HPV sequences that we then classified into genotypes by de novo assembly of nonhuman sequencing reads followed by alignment to the RefSeq database. Among TP53/RB1-wildtype LMS, we identified 18 unique cases harboring HPV sequences. Surprisingly, most (n=11) were HPV51-positive, and these 11 represented all HPV51-positive tumors in our entire LMS database (n=11 of 2569; 0.4%). The absence of genomic alterations in TP53 or RB1 in HPV51-positive LMS represented a marked difference from HPV51-negative LMS (n=2558; 0% vs. 72% [P<0.00001], 0% vs. 53% [P=0.0002]). In addition, compared with HPV51-negative LMS, HPV51-positive LMS were significantly enriched for genomic alterations in ATRX (55% vs. 24%, P=0.027) and TSC1 (18% vs. 0.6%, P=0.0047). All HPV51-positive LMS were in women; median age was 54 years at surgery (range: 23 to 74 y). All known primary sites were from the gynecologic tract or adjacent anogenital area, including 5 cases of vaginal primary site. Histology was heterogeneous, with evaluable cases showing predominant epithelioid (n=5) and spindle (n=5) morphology. In situ hybridization confirmed the presence of high-risk HPV E6/E7 mRNA in tumor cells in three of three evaluable cases harboring HPV51 genomic sequences. Overall, in our pan-LMS analysis, HPV reads were identified in a subset of TP53/RB1-wildtype LMS. For all HPV51-associated LMS, the striking absence of any detectable TP53 or RB1 mutations and predilection for the female lower reproductive tract supports our hypothesis that high-risk HPV can be an alternative tumorigenic mechanism in this distinct class of LMS., Competing Interests: Conflicts of Interest and Source of Funding: E.A.W., M.M., J.Y.T., M.C.H., D.A.M., B.B.S., B.M.A., J.S.R., S.H.R., D.I.L., and J.A.E. are employees or consultants of Foundation Medicine Inc., a wholly owned subsidiary of Roche Holdings Inc. and Roche Finance Ltd, and these employees have equity interest in an affiliate of these Roche entities. For the remaining authors none were declared., (Copyright © 2022 The Author(s). Published by Wolters Kluwer Health, Inc.)

Published

2022

5. Case studies on longitudinal mercury content in humpback whale ( Megaptera novaeangliae ) baleen.

Author

Lowe CL, Jordan-Ward R, Hunt KE, Rogers MC, Werth AJ, Gabriele C, Neilson J, von Hippel FA, and Buck CL

Abstract

Quantification of contaminant concentrations in baleen whales is important for individual and population level health assessments but is difficult due to large migrations and infrequent resighings. The use of baleen allows for a multiyear retrospective analysis of contaminant concentrations without having to collect repeated samples from the same individual. Here we provide case studies of mercury analysis using cold vapor atomic absorption spectroscopy in three individual humpback whales ( Megaptera novaeangliae ), a 44.5-year-old female and two males aged ≥35 and 66 years, over approximately three years of baleen growth. Mercury concentrations in the female's baleen were consistently 2-3 times higher than in either male. Age did not affect mercury concentrations in baleen; the younger male had comparable levels to the older male. In the female, mercury concentrations in the baleen did not change markedly during pregnancy but mercury did spike during the first half of lactation. Stable isotope profiles suggest that diet likely drove the female's high mercury concentrations. In conclusion, variations in baleen mercury content can be highly individualistic. Future studies should compare sexes as well as different populations and species to determine how the concentrations of mercury and other contaminants vary by life history parameters and geography., Competing Interests: The authors declare no conflict of interest., (© 2022 The Authors.)

Published

2021

6. The brain limit.

Author

Werth AJ and Corbett JE

Subjects

Acoustics, Animals, Brain, Whales, Echolocation

Abstract

How fast the brain and muscles can respond to information about prey location constrains visual and echolocating predators in similar ways., Competing Interests: AW, JC No competing interests declared, (© 2021, Werth and Corbett.)

Published

2021

7. Rorqual Lunge-Feeding Energetics Near and Away from the Kinematic Threshold of Optimal Efficiency.

Author

Potvin J, Cade DE, Werth AJ, Shadwick RE, and Goldbogen JA

Abstract

Humpback and blue whales are large baleen-bearing cetaceans, which use a unique prey-acquisition strategy-lunge feeding-to engulf entire patches of large plankton or schools of forage fish and the water in which they are embedded. Dynamically, and while foraging on krill, lunge-feeding incurs metabolic expenditures estimated at up to 20.0 MJ. Because of prey abundance and its capture in bulk, lunge feeding is carried out at high acquired-to-expended energy ratios of up to 30 at the largest body sizes (∼27 m). We use bio-logging tag data and the work-energy theorem to show that when krill-feeding at depth while using a wide range of prey approach swimming speeds (2-5 m/s), rorquals generate significant and widely varying metabolic power output during engulfment, typically ranging from 10 to 50 times the basal metabolic rate of land mammals. At equal prey field density, such output variations lower their feeding efficiency two- to three-fold at high foraging speeds, thereby allowing slow and smaller rorquals to feed more efficiently than fast and larger rorquals. The analysis also shows how the slowest speeds of harvest so far measured may be connected to the biomechanics of the buccal cavity and the prey's ability to collectively avoid engulfment. Such minimal speeds are important as they generate the most efficient lunges. Sommaire Les rorquals à bosse et rorquals bleus sont des baleines à fanons qui utilisent une technique d'alimentation unique impliquant une approche avec élan pour engouffrer de larges quantités de plancton et bancs de petits poissons, ainsi que la masse d'eau dans laquelle ces proies sont situés. Du point de vue de la dynamique, et durant l'approche et engouffrement de krill, leurs dépenses énergétiques sont estimées jusqu'à 20.0 MJ. À cause de l'abondance de leurs proies et capture en masse, cette technique d'alimentation est effectuée à des rapports d'efficacité énergétique (acquise -versus- dépensée) estimés aux environs de 30 dans le cas des plus grandes baleines (27 m). Nous utilisons les données recueillies par des capteurs de bio-enregistrement ainsi que le théorème reliant l'énergie à l'effort pour démontrer comment les rorquals s'alimentant sur le krill à grandes profondeurs, et à des vitesses variant entre 2 et 5 m/s, maintiennent des taux de dépenses énergétiques entre 10 et 50 fois le taux métabolique basal des mammifères terrestres. À densités de proies égales, ces variations d'énergie utilisée peuvent réduire le rapport d'efficacité énergétique par des facteurs entre 2x et 3x, donc permettant aux petits et plus lents rorquals de chasser avec une efficacité comparable à celle des rorquals les plus grands et rapides. Notre analyse démontre aussi comment des vitesses d'approche plus lentes peuvent être reliées à la biomécanique de leur poche ventrale extensible, et à l'habilitée des proies à éviter d'être engouffrer. Ces minimums de vitesses sont importants car ils permettent une alimentation plus efficace énergétiquement., (© The Author(s) 2021. Published by Oxford University Press on behalf of the Society for Integrative and Comparative Biology.)

Published

2021

8. Lunge filter feeding biomechanics constrain rorqual foraging ecology across scale.

Author

Kahane-Rapport SR, Savoca MS, Cade DE, Segre PS, Bierlich KC, Calambokidis J, Dale J, Fahlbusch JA, Friedlaender AS, Johnston DW, Werth AJ, and Goldbogen JA

Subjects

Animals, Biomechanical Phenomena, Body Size, Whales, Energy Metabolism, Feeding Behavior

Abstract

Fundamental scaling relationships influence the physiology of vital rates, which in turn shape the ecology and evolution of organisms. For diving mammals, benefits conferred by large body size include reduced transport costs and enhanced breath-holding capacity, thereby increasing overall foraging efficiency. Rorqual whales feed by engulfing a large mass of prey-laden water at high speed and filtering it through baleen plates. However, as engulfment capacity increases with body length (engulfment volume∝body length 3.57 ), the surface area of the baleen filter does not increase proportionally (baleen area∝body length 1.82 ), and thus the filtration time of larger rorquals predictably increases as the baleen surface area must filter a disproportionally large amount of water. We predicted that filtration time should scale with body length to the power of 1.75 (filter time∝body length 1.75 ). We tested this hypothesis on four rorqual species using multi-sensor tags with corresponding unoccupied aircraft systems-based body length estimates. We found that filter time scales with body length to the power of 1.79 (95% CI: 1.61-1.97). This result highlights a scale-dependent trade-off between engulfment capacity and baleen area that creates a biomechanical constraint to foraging through increased filtration time. Consequently, larger whales must target high-density prey patches commensurate to the gulp size to meet their increased energetic demands. If these optimal patches are absent, larger rorquals may experience reduced foraging efficiency compared with smaller whales if they do not match their engulfment capacity to the size of targeted prey aggregations., Competing Interests: Competing interestsThe authors declare no competing or financial interests., (© 2020. Published by The Company of Biologists Ltd.)

Published

2020

9. Structure and properties of baleen in the Southern right (Eubalaena australis) and Pygmy right whales (Caperea marginata).

Author

Loch C, Vaz Viegas S, Waddell JN, Kemper C, Cook RB, and Werth AJ

Subjects

Animals, Keratins, Whales

Abstract

Baleen is a resilient and keratinised filter-feeding structure attached to the maxilla of mysticete whales. It is strong and tough, yet a pliant and resilient material, that withstands extreme pressures in the oral cavity during feeding. We investigated the structure, water content, wettability and mechanical properties of baleen of the Southern right (SRW) and Pygmy right whales (PRW), to understand the effects of hydration on the physical and mechanical properties of baleen. Sixty 25 × 15mm baleen subsamples were prepared from one individual of SRW and PRW. Half were hydrated in circulated natural seawater for 21 days and half were dry. Water content analysis showed that SRW baleen was 21.2% water weight and PRW was 26.1%. Wettability testing indicated that surfaces of both hydrated and dried SRW and PRW baleen were hydrophilic, with hydrated samples of both species having lower contact angle values. For the SRW, the average contact angle of hydrated baleen was 40° ± 13.2 and 73° ± 6 for dried samples. Hydrated PRW baleen had an average contact angle of 44° ± 15.3, which was lower than in dried samples (74° ± 2.9). Three-point bending mechanical tests showed that the average maximum flexural stress of dried SRW (134.1 ± 34.3 MPa) and PRW samples (117.8 ± 22.3 MPa) were significantly higher than those of hydrated SRW (25.7 ± 6.3 MPa) and PRW (19.7 ± 4.8 MPa) baleen. Scanning electron microscope images showed the stratification of the outer cortical layer, with cross-linked keratin fibres observed within and between baleen keratin sheets. Hydrated baleen, as in its natural and functional behaviour, has greater flexibility and strength, attributes necessary for the complex filter feeding mechanism characteristic of whales. Hydration must be considered when addressing the physical and mechanical properties of baleen, especially when using dried museum specimens., (Copyright © 2020 Elsevier Ltd. All rights reserved.)

Published

2020

10. CDKN2C -Null Leiomyosarcoma: A Novel, Genomically Distinct Class of TP53 / RB1 -Wild-Type Tumor With Frequent CIC Genomic Alterations and 1p/19q-Codeletion.

Author

Williams EA, Sharaf R, Decker B, Werth AJ, Toma H, Montesion M, Sokol ES, Pavlick DC, Shah N, Williams KJ, Venstrom JM, Alexander BM, Ross JS, Albacker LA, Lin DI, Ramkissoon SH, and Elvin JA

Abstract

Purpose: Leiomyosarcoma (LMS) harbors frequent mutations in TP53 and RB1 but few actionable genomic alterations. Here, we searched for recurrent actionable genomic alterations in LMS that occur in the absence of common untreatable oncogenic drivers., Methods: Tissues from 276,645 unique advanced cancers, including 2,570 uterine and soft tissue LMS, were sequenced by hybrid-capture-based next-generation DNA and RNA sequencing/comprehensive genomic profiling of up to 406 genes. We characterized clinicopathologic features of relevant patient cases., Results: Overall, 77 LMS exhibited homozygous copy loss of CDKN2C at chromosome 1p32.3 (3.0% of LMS). Genomic alterations (GAs) in TP53 , RB1 , and ATRX were rare compared with the remainder of the LMS cohort (11.7% v 73.4%, 0% v 54.5%, 2.6% v 24.5%, respectively; all P < .0001). CDKN2C -null LMS patient cases were significantly enriched for GAs in CIC (40.3% v 1.4%) at 19q13.2, CDKN2A (46.8% v 7.0%), and RAD51B (16.9% v 1.7%; all P < .0001). Chromosome arm-level aneuploidy analysis of available LMS patient cases (n = 1,284) found that 81% (58 of 72) of CDKN2C -null LMS exhibited 1p/19q-codeletion, a significant enrichment compared with 5.1% in the remainder of the LMS cohort ( P < .0001). In total, 99% of CDKN2C -null LMS were in women; the median age was 61 years at surgery (range, 36-81 years). Fifty-five patient cases were uterine primary, four were nonuterine, and the remaining 18 were of uncertain primary site. Sixty percent of cases showed at least focal epithelioid variant histology. Most patients had advanced-stage disease, with 62% of confirmed uterine primary LMS at International Federation of Gynecology and Obstetrics stage IVB. We further validated our findings in two publicly available datasets: The Cancer Genome Atlas and the Project GENIE initiative., Conclusion: CDKN2C -null LMS defines a genomically distinct tumor that may have prognostic and/or therapeutic clinical implications, including possible use of specific cyclin-dependent kinase inhibitors., Competing Interests: The following represents disclosure information provided by authors of this manuscript. All relationships are considered compensated unless otherwise noted. Relationships are self-held unless noted. I = Immediate Family Member, Inst = My Institution. Relationships may not relate to the subject matter of this manuscript. For more information about ASCO's conflict of interest policy, please refer to www.asco.org/rwc or ascopubs.org/po/authors/author-center. Open Payments is a public database containing information reported by companies about payments made to US-licensed physicians (Open Payments). Erik A. WilliamsEmployment: Foundation Medicine, Inc. Stock and Other Ownership Interests: F. Hoffmann-La RocheRadwa SharafEmployment: Foundation Medicine Stock and Other Ownership Interests: RocheBrennan DeckerStock and Other Ownership Interests: Avidea Technologies Consulting or Advisory Role: Foundation Medicine, Avidea TechnologiesMeagan MontesionStock and Other Ownership Interests: RocheEthan S. SokolEmployment: Foundation Medicine Stock and Other Ownership Interests: Roche (Parent of FMI)Dean C. PavlickStock and Other Ownership Interests: RocheNikunj ShahEmployment: Foundation MedicineKevin Jon WilliamsStock and Other Ownership Interests: Hygieia, Gemphire Therapeutics Consulting or Advisory Role: Gemphire Therapeutics Research Funding: Novo NordiskJeffrey M. VenstromEmployment: Genentech, Foundation Medicine Leadership: Genentech Stock and Other Ownership Interests: Genentech Research Funding: Genentech, Roche, Foundation Medicine Travel, Accommodations, Expenses: GenentechBrian M. AlexanderEmployment: Foundation Medicine Leadership: Foundation Medicine Stock and Other Ownership Interests: Roche Research Funding: Eli Lilly (Inst), Puma (Inst), Celgene (Inst) (OPTIONAL) Open Payments Link: https://openpaymentsdata.cms.gov/physician/854258/summaryJeffrey S. RossEmployment: Foundation Medicine Leadership: Foundation Medicine Stock and Other Ownership Interests: Foundation Medicine Consulting or Advisory Role: Celsius Therapeutics Research Funding: Foundation MedicineLee A. AlbackerEmployment: Foundation Medicine Stock and Other Ownership Interests: RocheDouglas I. LinEmployment: Foundation MedicineShakti H. RamkissoonEmployment: Foundation Medicine Stock and Other Ownership Interests: Foundation MedicineJulia A. ElvinEmployment: Foundation Medicine No other potential conflicts of interest were reported., (© 2020 by American Society of Clinical Oncology.)

Published

2020

11. Retraction: Whale jaw joint is a shock absorber.

Author

Werth AJ and Ito H

Published

2020

12. Vulvar Squamous Cell Carcinoma: Comprehensive Genomic Profiling of HPV+ Versus HPV- Forms Reveals Distinct Sets of Potentially Actionable Molecular Targets.

Author

Williams EA, Werth AJ, Sharaf R, Montesion M, Sokol ES, Pavlick DC, McLaughlin-Drubin M, Erlich R, Toma H, Williams KJ, Venstrom JM, Alexander BM, Shah N, Danziger N, Hemmerich AC, Severson EA, Killian JK, Lin DI, Ross JS, Tse JY, Ramkissoon SH, Mochel MC, and Elvin JA

Abstract

Purpose: Vulvar squamous cell carcinoma (vSCC) encompasses two predominant variants: one associated with detectable high-risk strains of human papillomavirus (hrHPV) and a second form often occurring in the context of chronic dermatitis in postmenopausal women. Genomic assessment of a large-scale cohort of patients with aggressive vSCC may identify distinct mutational signatures., Materials and Methods: Tumor samples from a total of 280 patients with vSCC underwent hybridization capture with analysis of up to 406 cancer-related genes. Human papillomavirus (HPV) sequences were detected by de novo assembly of nonhuman sequencing reads and aligned to the RefSeq database. Immunohistochemistry for programmed death-ligand 1 (PD-L1) was assessed., Results: One hundred two of 280 vSCCs (36%) contained hrHPV sequences, predominantly HPV 16 (88%). The HPV-positive (HPV+) group was significantly younger (median age, 59 v 64 years; P = .001). Compared with HPV-negative (HPV-) vSCCs, HPV+ tumors showed more frequent pathogenic alterations in PIK3CA (31% v 16%; P = .004), PTEN (14% v 2%; P < .0001), EP300 (14% v 1%; P < .0001), STK11 (14% v 1%; P < .0001), AR (5% v 0%; P = .006), and FBXW7 (10% v 3%; P = .03). In contrast, HPV- vSCCs showed more alterations in TP53 (83% v 6%; P < .0001), TERTp (71% v 9%; P < .0001), CDKN2A (55% v 2%; P < .0001), CCND1 amplification (22% v 2%; P < .0001), FAT1 (25% v 4%; P < .0001), NOTCH1 (19% v 6%; P = .002), and EGFR amplification (11% v 0%; P < .0001), as well as a higher rate of 9p24.1 ( PDL1/PDL2) amplification (5% v 1%) and PD-L1 immunohistochemistry high-positive tumor staining (33% v 9%; P = .04)., Conclusion: Comprehensive molecular profiles of vSCC vary considerably with hrHPV status and may inform patient selection into clinical trials. Sixty-one percent of HPV+ vSCCs had a pathogenic alteration in the PI3K/mTOR pathway, whereas HPV- vSCCs showed alterations in TP53 , TERTp , CDKN2A , CCND1 , and EGFR , and biomarkers associated with responsiveness to immunotherapy., Competing Interests: The following represents disclosure information provided by authors of this manuscript. All relationships are considered compensated unless otherwise noted. Relationships are self-held unless noted. I = Immediate Family Member, Inst = My Institution. Relationships may not relate to the subject matter of this manuscript. For more information about ASCO's conflict of interest policy, please refer to www.asco.org/rwc or ascopubs.org/po/author-center. Open Payments is a public database containing information reported by companies about payments made to US-licensed physicians (Open Payments). Erik A. WilliamsEmployment: Foundation Medicine Stock and Other Ownership Interests: F. Hoffmann-La RocheRadwa SharafEmployment: Foundation Medicine Stock and Other Ownership Interests: RocheMeagan MontesionStock and Other Ownership Interests: RocheEthan S. SokolEmployment: Foundation Medicine Stock and Other Ownership Interests: Roche (Parent of FMI)Dean C. PavlickStock and Other Ownership Interests: RocheMolly McLaughlin-DrubinEmployment: Foundation Medicine Employment: PatientsLikeMe (I), Precision for Medicine (I) Stock and Other Ownership Interests: Roche Travel, Accommodations, Expenses: Foundation MedicineRachel ErlichEmployment: Foundation Medicine Stock and Other Ownership Interests: Foundation MedicineKevin Jon WilliamsStock and Other Ownership Interests: Hygieia Stock and Other Ownership Interests: Gemphire Therapeutics Consulting or Advisory Role: Gemphire Therapeutics, Inc. Research Funding: Novo NordiskJeff M. VenstromEmployment: Genentech, Foundation Medicine Leadership: Genentech Stock and Other Ownership Interests: Genentech Research Funding: Genentech, Foundation Medicine Travel, Accommodations, Expenses: GenentechBrian M. AlexanderEmployment: Foundation Medicine Leadership: Foundation Medicine Stock and Other Ownership Interests: Roche Research Funding: Eli Lilly (Inst), Puma (Inst), Celgene (Inst) Open Payments Link: https://openpaymentsdata.cms.gov/physician/854258/summaryNikunj ShahEmployment: Foundation MedicineNatalie DanzigerEmployment: Foundation MedicineAmanda C. HemmerichEmployment: Foundation Medicine Stock and Other Ownership Interests: Foundation Medicine (Inst)Eric A. SeversonEmployment: Foundation Medicine, Partners Healthcare Stock and Other Ownership Interests: Foundation MedicineJonathan Keith KillianEmployment: Foundation Medicine Stock and Other Ownership Interests: Foundation MedicineDouglas I. LinEmployment: Foundation MedicineJeffrey S. RossEmployment: Foundation Medicine Leadership: Foundation Medicine Stock and Other Ownership Interests: Foundation Medicine Consulting or Advisory Role: Celsius Therapeutics Research Funding: Foundation MedicineJulie Y. TseEmployment: Foundation Medicine, Pathology Watch Travel, Accommodations, Expenses: Foundation MedicineShakti H. RamkissoonEmployment: Foundation Medicine Stock and Other Ownership Interests: Foundation MedicineJulia A. ElvinEmployment: Foundation Medicine No other potential conflicts of interest were reported., (© 2020 by American Society of Clinical Oncology.)

Published

2020

13. Whale jaw joint is a shock absorber.

Author

Werth AJ and Ito H

Abstract

The non-synovial temporomandibular jaw joint of rorqual whales is presumed to withstand intense stresses when huge volumes of water are engulfed during lunge feeding. Examination and manipulation of temporomandibular joints (TMJs) in fresh carcasses, plus CT scans and field/lab mechanical testing of excised tissue blocks, reveals that the TMJ's fibrocartilage pad fully and quickly rebounds after shrinking by 68-88% in compression (by axis) and stretching 176-230%. It is more extensible along the mediolateral axis and less extensible dorsoventrally, but mostly isotropic, with collagen and elastin fibers running in all directions. The rorqual TMJ pad compresses as gape increases. Its stiffness is hypothesized to damp acceleration, whereas its elasticity is hypothesized to absorb shock during engulfment, allow for rotation or other jaw motion during gape opening/closure, and aid in returning jaws to their closed position during filtration via elastic recoil with conversion of stored potential energy into kinetic energy., Competing Interests: Competing interestsThe authors declare no competing or financial interests., (© 2020. Published by The Company of Biologists Ltd.)

Published

2020

14. Whale breaching says it loud and clear.

Author

Werth AJ and Lemon CL

Subjects

Animals, Whales

Abstract

A whale leaping above the surface expends an enormous amount of energy, displaying its health and strength to peers and potential mates., Competing Interests: AW, CL No competing interests declared, (© 2020, Werth and Lemon.)

Published

2020

15. Multiaxial movements at the minke whale temporomandibular joint.

Author

Werth AJ, Ito H, and Ueda K

Subjects

Animals, Feeding Behavior physiology, Female, Humans, Jaw physiology, Male, Minke Whale anatomy & histology, Range of Motion, Articular physiology, Rotation, Temporomandibular Joint anatomy & histology, Temporomandibular Joint diagnostic imaging, Tomography, X-Ray Computed, Minke Whale physiology, Movement, Temporomandibular Joint physiology

Abstract

Mandibular mobility accompanying gape change in Northern and Antarctic minke whales was investigated by manipulating jaws of carcasses, recording jaw movements via digital instruments (inclinometers, accelerometers, and goniometers), and examining osteological and soft tissue movements via computed tomography (CT)-scans. We investigated longitudinal (α) rotation of the mandible and mediolateral displacement at the symphysis (Ω 1 ) and temporomandibular joint (Ω 2 ) as the mouth opened (Δ). Results indicated three phases of jaw opening. In the first phase, as gape increased from zero to 8°, there was slight (<1°) α and Ω rotation. As gape increased between 20 and 30°, the mandibles rotated slightly laterally (Mean 3°), the posterior condyles were slightly medially displaced (Mean 4°), and the anterior ends at the symphysis were laterally displaced (Mean 3°). In the third phase of jaw opening, from 30° to full (≥90°) gape, these motions reversed: mandibles rotated medially (Mean 29°), condyles were laterally displaced (Mean 14°), and symphyseal ends were medially displaced (Mean 1°). Movements were observed during jaw manipulation and analyzed with CT-images that confirmed quantitative inclinometer/accelerometer data, including the unstable intermediate (Phase 2) position. Together these shifting movements maintain a constant distance for adductor muscles stretched between the skull's temporal fossa and mandible's coronoid process. Mandibular rotation enlarges the buccal cavity's volume as much as 36%, likely to improve prey capture in rorqual lunge feeding; it may strengthen and stabilize jaw opening or closure, perhaps via a simple locking or unlocking mechanism. Rotated lips may brace baleen racks during filtration. Mandibular movements may serve a proprioceptive mechanosensory function, perhaps via the symphyseal organ, to guide prey engulfment and water expulsion for filtration., (© 2020 Wiley Periodicals, Inc.)

Published

2020

16. Pectoral herding: an innovative tactic for humpback whale foraging.

Author

Kosma MM, Werth AJ, Szabo AR, and Straley JM

Abstract

Humpback whales ( Megaptera novaeangliae ) have exceptionally long pectorals (i.e. flippers) that aid in shallow water navigation, rapid acceleration and increased manoeuvrability. The use of pectorals to herd or manipulate prey has been hypothesized since the 1930s. We combined new technology and a unique viewing platform to document the additional use of pectorals to aggregate prey during foraging events. Here, we provide a description of 'pectoral herding' and explore the conditions that may promote this innovative foraging behaviour. Specifically, we analysed aerial videos and photographic sequences to assess the function of pectorals during feeding events near salmon hatchery release sites in Southeast Alaska (2016-2018). We observed the use of solo bubble-nets to initially corral prey, followed by calculated movements to establish a secondary boundary with the pectorals-further condensing prey and increasing foraging efficiency. We found three ways in which humpback whales use pectorals to herd prey: (i) create a physical barrier to prevent evasion, (ii) cause water motion to guide prey towards the mouth, and (iii) position the ventral side to reflect light and alter prey movement. Our findings suggest that behavioural plasticity may aid foraging in changing environments and shifts in prey availability. Further study would clarify if 'pectoral herding' is used as a principal foraging tool by the broader humpback whale population and the conditions that promote its use., Competing Interests: We declare we have no competing interests., (© 2019 The Authors.)

Published

2019

17. New views of humpback whale flow dynamics and oral morphology during prey engulfment.

Author

Werth AJ, Kosma MM, Chenoweth EM, and Straley JM

Abstract

The rise of inexpensive, user-friendly cameras and editing software promises to revolutionize data collection with minimal disturbance to marine mammals. Video sequences recorded by aerial drones and GoPro cameras provided close-up views and unique perspectives of humpback whales engulfing juvenile salmon at or just below the water surface in Southeast Alaska and Prince William Sound. Although humpback feeding is famous for its flexibility, several stereotyped events were noted in the 47 lunges we analyzed. Engulfment was rapid (mean 2.07 s), and the entrance through which the tongue inverts into the ventral pouch was seen as water rushes in. Cranial elevation was a major contributor to gape, and pouch contraction sometimes began before full gape closure, with reverberating waves indicating rebounding flow of water within the expanded pouch. Expulsion of filtered water began with a small splash at the anterior of the mouth, followed by sustained excurrent flow in the mouth's central or posterior regions. Apart from a splash of rebounding water, water within the mouth was surprisingly turbulence-free during engulfment, but submersion of the whale's head created visible surface whirlpools and vortices which may aggregate prey for subsequent engulfment.

Published

2019

18. Oil adsorption does not structurally or functionally alter whale baleen.

Author

Werth AJ, Blakeney SM, and Cothren AI

Abstract

Mysticete whales filter small prey from seawater using baleen, a unique keratinous oral tissue that grows from the palate, from which it hangs in hundreds of serial plates. Laboratory experiments testing effects of oils on material strength and flexibility, particle capture and tissue architecture of baleen from four mysticete species (bowhead, Balaena mysticetus ; North Atlantic right, Eubalaena glacialis ; fin, Balaenoptera physalus ; humpback, Megaptera novaeangliae ) indicate that baleen is hydrophilic and oleophobic, shedding rather than adsorbing oil. Oils of different weights and viscosities were tested, including six petroleum-based oils and two fish or plankton oils of common whale prey. No notable differences were found by oil type or whale species. Baleen did not adsorb oil; oil was readily rinsed from baleen by flowing water, especially from moving fringes. Microscopic examination shows minimal wrinkling or peeling of baleen's cortical keratin layers, probably due to oil repelling infiltrated water. Combined results cast doubt on fears of baleen fouling by oil; filter porosity is not appreciably affected, but oil ingestion risks remain. Particle capture studies suggest potentially greater danger to mysticetes from plastic pollution than oil., Competing Interests: The authors declare no competing interests.

Published

2019

19. Slick, Stretchy Fascia Underlies the Sliding Tongue of Rorquals.

Author

Werth AJ, Lillie MA, Piscitelli MA, Wayne Vogl A, and Shadwick RE

Subjects

Animals, Balaenoptera anatomy & histology, Biomechanical Phenomena, Elasticity, Fascia physiology, Tongue physiology, Balaenoptera physiology, Fascia anatomy & histology, Feeding Behavior physiology, Tongue anatomy & histology

Abstract

The tongue of rorqual (balaenopterid) whales slides far down the throat into the expanded oral pouch as an enormous mouthful of water is engulfed during gulp feeding. As the tongue and adjacent oral floor expands and slides caudoventrally, it glides along a more superficial (outer) layer of ventral body wall musculature, just deep to the accordion-like ventral throat pleats. We hypothesize that this sliding movement of adjacent musculature is facilitated by a slick, stretchy layer of loose areolar connective tissue that binds the muscle fibers and reduces friction: fascia. Gross anatomical examination of the gular region of adult minke, fin, and humpback whales confirms the presence of a discrete, three-layered sublingual fascia interposed between adhering fasciae of the tongue and body wall. Histological analysis of this sublingual fascia reveals collagen and elastin fibers loosely organized in a random feltwork along with numerous fibroblasts in a watery extracellular matrix. Biomechanical testing of tissue samples in the field and laboratory, via machine-controlled or manual stretching, demonstrates expansion of the sublingual fascia and its three layers up to 250% beyond resting dimensions, with slightly more extension observed in anteroposterior (rather than mediolateral or oblique) stretching, and with the most superficial of the fascia's three layers. Anat Rec, 2018. © 2018 Wiley Periodicals, Inc. Anat Rec, 302:735-744, 2019. © 2018 Wiley Periodicals, Inc., (© 2018 Wiley Periodicals, Inc.)

Published

2019

20. How do baleen whales stow their filter? A comparative biomechanical analysis of baleen bending.

Author

Werth AJ, Rita D, Rosario MV, Moore MJ, and Sformo TL

Subjects

Animals, Biomechanical Phenomena, Keratins, Mouth physiology, Whales physiology, Mouth anatomy & histology, Whales anatomy & histology

Abstract

Bowhead and right whale (balaenid) baleen filtering plates, longer in vertical dimension (≥3-4 m) than the closed mouth, presumably bend during gape closure. This has not been observed in live whales, even with scrutiny of video-recorded feeding sequences. To determine what happens to the baleen during gape closure, we conducted an integrative, multifactorial study including materials testing, functional (flow tank and kinematic) testing and histological examination. We measured baleen bending properties along the dorsoventral length of plates and anteroposterior location within a rack of plates via mechanical (axial bending, composite flexure, compression and tension) tests of hydrated and air-dried tissue samples from balaenid and other whale baleen. Balaenid baleen is remarkably strong yet pliable, with ductile fringes, and low stiffness and high elasticity when wet; it likely bends in the closed mouth when not used for filtration. Calculation of flexural modulus from stress/strain experiments shows that the balaenid baleen is slightly more flexible where it emerges from the gums and at its ventral terminus, but kinematic analysis indicates plates bend evenly along their whole length. Fin and humpback whale baleen has similar material properties but less flexibility, with no dorsoventral variation. The internal horn tubes have greater external and hollow luminal diameter but lower density in the lateral relative to medial baleen of bowhead and fin whales, suggesting a greater capacity for lateral bending. Baleen bending has major consequences not only for feeding morphology and energetics but also for conservation given that entanglement in fishing gear is a leading cause of whale mortality., Competing Interests: Competing interestsThe authors declare no competing or financial interests., (© 2018. Published by The Company of Biologists Ltd.)

Published

2018

21. Sling, Scoop, and Squirter: Anatomical Features Facilitating Prey Transport, Processing, and Swallowing in Rorqual Whales (Mammalia: Balaenopteridae).

Author

Werth AJ and Ito H

Subjects

Animals, Biomechanical Phenomena, Dissection, Energy Metabolism, Feeding Behavior physiology, Whales physiology, Adaptation, Physiological, Deglutition physiology, Jaw anatomy & histology, Mouth anatomy & histology, Oropharynx anatomy & histology, Whales anatomy & histology

Abstract

Much is known about lunge feeding in balaenopterid whales, but many key aspects of structure, function, and behavior have not yet been explained in detail, especially with regard to concentrating, positioning, and swallowing large aggregations of prey. We describe a novel system of three integrated structural components, all of which are involved in sequential feeding activities (intraoral transport, filtration, and swallowing of prey) that follow lunge-feeding engulfment of prey-laden water in rorquals: (1) a hammock-like muscular sling comprising extrinsic lingual musculature along the midline of the ventral pouch; (2) the flattened scoop-like arrangement of caudal-most baleen plates converging in the oropharynx adjacent to the esophageal opening; and (3) a flow-diverting flange at the posterior dorsum of the lip, by a flow channel at the angle of the mouth. Subsequent to contraction of the ventral pouch and concomitant expulsion of the mouthful of ingested water, these three structures together, we contend, aid in (1) channeling prey posteriorly toward the esophageal opening; (2) concentrating prey as excess water is squeezed from (what is presumed to be) the slurry-like mixture of nektonic and/or planktonic prey and water; and (3) guiding prey into the isthmus of the fauces while simultaneously (4) facilitating expulsion of water. These related functions occur along with, and are in part achieved by, elevation and retraction of the tongue and oral floor. Given their presumed functional role, these systems are best described as a suite of integrated structural adaptations. Anat Rec, 2017. © 2017 Wiley Periodicals, Inc. Anat Rec, 300:2070-2086, 2017. © 2017 Wiley Periodicals, Inc., (© 2017 Wiley Periodicals, Inc.)

Published

2017

22. Oral cavity hydrodynamics and drag production in Balaenid whale suspension feeding.

Author

Potvin J and Werth AJ

Subjects

Animals, Balaenoptera physiology, Feeding Behavior, Hydrodynamics, Mouth physiology

Abstract

Balaenid whales feed on large aggregates of small and slow-moving prey (predominantly copepods) through a filtration process enabled by baleen. These whales exhibit continuous filtration, namely, with the mouth kept partially opened and the baleen exposed to oncoming prey-laden waters while fluking. The process is an example of crossflow filtration (CFF) in which most of the particulates (prey) are separated from the substrate (water) without ever coming into contact with the filtering surface (baleen). This paper discusses the simulation of baleen filtration hydrodynamics based on a type of hydraulic circuit modeling commonly used in microfluidics, but adapted to the much higher Reynolds number flows typical of whale hydrodynamics. This so-called Baleen Hydraulic Circuit (BHC) model uses as input the basic characteristics of the flows moving through a section of baleen observed in a previous flume study by the authors. The model has low-spatial resolution but incorporates the effects of fluid viscosity, which doubles or more a whale's total body drag in comparison to non-feeding travel. Modeling viscous friction is crucial here since exposing the baleen system to the open ocean ends up tripling a whale's total wetted surface area. Among other findings, the BHC shows how CFF is enhanced by a large filtration surface and hence large body size; how it is carried out via the establishment of rapid anteroposterior flows transporting most of the prey-water slurry towards the oropharyngeal wall; how slower intra-baleen flows manage to transfer most of the substrate out of the mouth, all the while contributing only a fraction to overall oral cavity drag; and how these anteroposterior and intra-baleen flows lose speed as they approach the oropharyngeal wall.

Published

2017

23. How Baleen Whales Feed: The Biomechanics of Engulfment and Filtration.

Author

Goldbogen JA, Cade DE, Calambokidis J, Friedlaender AS, Potvin J, Segre PS, and Werth AJ

Subjects

Animals, Body Size, Hydrodynamics, Feeding Behavior, Whales

Abstract

Baleen whales are gigantic obligate filter feeders that exploit aggregations of small-bodied prey in littoral, epipelagic, and mesopelagic ecosystems. At the extreme of maximum body size observed among mammals, baleen whales exhibit a unique combination of high overall energetic demands and low mass-specific metabolic rates. As a result, most baleen whale species have evolved filter-feeding mechanisms and foraging strategies that take advantage of seasonally abundant yet patchily and ephemerally distributed prey resources. New methodologies consisting of multi-sensor tags, active acoustic prey mapping, and hydrodynamic modeling have revolutionized our ability to study the physiology and ecology of baleen whale feeding mechanisms. Here, we review the current state of the field by exploring several hypotheses that aim to explain how baleen whales feed. Despite significant advances, major questions remain about the processes that underlie these extreme feeding mechanisms, which enabled the evolution of the largest animals of all time.

Published

2017

24. Hydration affects the physical and mechanical properties of baleen tissue.

Author

Werth AJ, Harriss RW, Rosario MV, George JC, and Sformo TL

Abstract

Baleen, an anisotropic oral filtering tissue found only in the mouth of mysticete whales and made solely of alpha-keratin, exhibits markedly differing physical and mechanical properties between dried or (as in life) hydrated states. On average baleen is 32.35% water by weight in North Atlantic right whales ( Eubalaena glacialis ) and 34.37% in bowhead whales ( Balaena mysticetus ). Baleen's wettability measured by water droplet contact angles shows that dried baleen is hydrophobic whereas hydrated baleen is highly hydrophilic. Three-point flexural bending tests of mechanical strength reveal that baleen is strong yet ductile. Dried baleen is brittle and shatters at about 20-30 N mm -2 but hydrated baleen is less stiff; it bends with little force and absorbed water is squeezed out when force is applied. Maximum recorded stress was 4× higher in dried (mean 14.29 N mm -2 ) versus hydrated (mean 3.69 N mm -2 ) baleen, and the flexural stiffness was >10× higher in dried (mean 633N mm -2 ) versus hydrated (mean 58 N mm -2 ) baleen. In addition to documenting hydration's powerful effects on baleen, this study indicates that baleen is far more pliant and malleable than commonly supposed, with implications for studies of baleen's structure and function as well as its susceptibility to oil or other hydrophobic pollutants.

Published

2016

25. Baleen wear reveals intraoral water flow patterns of mysticete filter feeding.

Author

Werth AJ, Straley JM, and Shadwick RE

Subjects

Animals, Keratins, Mouth anatomy & histology, Tongue anatomy & histology, Feeding Behavior physiology, Whales anatomy & histology, Whales physiology

Abstract

A survey of macroscopic and microscopic wear patterns in the baleen of eight whale species (Cetacea: Mysticeti) discloses structural, functional, and life history properties of this neomorphic keratinous tissue, including evidence of intraoral water flow patterns involved in filter feeding. All baleen demonstrates wear, particularly on its medial and ventral edges, as flat outer layers of cortical keratin erode to reveal horn tubes, also of keratin, which emerge as hair-like fringes. This study quantified five additional categories of specific wear: pitting of plates, scratching of plates, scuffing of fringes, shortening of fringes, and reorientation of fringes (including fringes directed between plates to the exterior of the mouth). Blue whale baleen showed the most pitting and sei whale baleen the most scratching; gray whale baleen had the most fringe wear. The location of worn baleen within the mouth suggests that direct contact with the tongue is not responsible for most wear, and that flowing water as well as abrasive prey or sediment carried by the flowing water likely causes pitting and scratching of plates as well as fringe fraying, scuffing, shortening, and reorientation. Baleen also has elevated vertical and horizontal ridges that are unrelated to wear; these are probably related to growth and may allow for age determination., (© 2016 Wiley Periodicals, Inc.)

Published

2016

26. Baleen Hydrodynamics and Morphology of Cross-Flow Filtration in Balaenid Whale Suspension Feeding.

Author

Werth AJ and Potvin J

Subjects

Animal Structures anatomy & histology, Animal Structures physiology, Animals, Biomechanical Phenomena, Bowhead Whale anatomy & histology, Hydrodynamics, Models, Biological, Mouth anatomy & histology, Mouth physiology, Bowhead Whale physiology, Feeding Behavior

Abstract

The traditional view of mysticete feeding involves static baleen directly sieving particles from seawater using a simple, dead-end flow-through filtration mechanism. Flow tank experiments on bowhead (Balaena mysticetus) baleen indicate the long-standing model of dead-end filtration, at least in balaenid (bowhead and right) whales, is not merely simplistic but wrong. To recreate continuous intraoral flow, sections of baleen were tested in a flume through which water and buoyant particles circulated with variable flow velocity. Kinematic sequences were analyzed to investigate movement and capture of particles by baleen plates and fringes. Results indicate that very few particles flow directly through the baleen rack; instead much water flows anteroposteriorly along the interior (lingual) side of the rack, allowing items to be carried posteriorly and accumulate at the posterior of the mouth where they might readily be swallowed. Since water flows mainly parallel to rather than directly through the filter, the cross-flow mechanism significantly reduces entrapment and tangling of minute items in baleen fringes, obviating the need to clean the filter. The absence of copepods or other prey found trapped in the baleen of necropsied right and bowhead whales supports this hypothesis. Reduced through-baleen flow was observed with and without boundaries modeling the tongue and lips, indicating that baleen itself is the main if not sole agent of crossflow. Preliminary investigation of baleen from balaenopterid whales that use intermittent filter feeding suggests that although the biomechanics and hydrodynamics of oral flow differ, cross-flow filtration may occur to some degree in all mysticetes.

Published

2016

27. Flow-dependent porosity and other biomechanical properties of mysticete baleen.

Author

Werth AJ

Subjects

Alaska, Animal Structures anatomy & histology, Animal Structures physiology, Animals, Biomechanical Phenomena, Body Weights and Measures, Keratins metabolism, Movement physiology, Porosity, Animal Structures chemistry, Bowhead Whale physiology, Feeding Behavior physiology, Keratins physiology

Abstract

Despite its vital function in a highly dynamic environment, baleen is typically assumed to be a static material. Its biomechanical and material properties have not previously been explored. Thus I tested sections of baleen from bowhead whales, Balaena mysticetus, and humpback whales, Megaptera novaeangliae, alone or in groups representing miniature 'racks', in a flow tank through which water and buoyant particles circulated with variable flow velocity. Kinematic sequences were recorded through an endoscopic camera or viewing window. One set of experiments investigated particle capture; another series analyzed biomechanical behavior, including fringe spacing, movement and interaction. Baleen fringe porosity directly correlates, in a mostly linear fashion, with velocity of incident water flow. However, undulation and interaction of fringes (especially of bowheads) at higher flow velocities can decrease porosity. Fringe porosity depends on distance from the baleen plate. Porosity also varies, with fringe length, by position along the length of an individual plate. Plate orientation, which varied from 0 to 90 deg relative to water flow, is crucial in fringe spacing and particle capture. At all flow velocities, porosity is lowest with plates aligned parallel to water flow. Turbulence introduced when plates rotate perpendicular to flow (as in cross-flow filtration) increases fringe interaction, so that particles more easily strike fringes yet more readily dislodge. Baleen of bowhead whales, which feed by continuous ram filtration, differs biomechanically from that of humpbacks, which use intermittent lunge filtration. The longer, finer fringes of bowhead baleen readily form a mesh-like mat, especially at higher flow velocities, to trap tiny particles.

Published

2013

28. An intraoral thermoregulatory organ in the bowhead whale (Balaena mysticetus), the corpus cavernosum maxillaris.

Author

Ford TJ Jr, Werth AJ, and George JC

Subjects

Animals, Bowhead Whale physiology, Palate, Hard blood supply, Palate, Hard physiology, Sense Organs blood supply, Sense Organs physiology, Thermoreceptors physiology, Thermosensing, Body Temperature Regulation, Bowhead Whale anatomy & histology, Palate, Hard anatomy & histology, Sense Organs anatomy & histology

Abstract

The novel observation of a palatal retial organ in the bowhead whale (Balaena mysticetus) is reported, with characterization of its form and function. This bulbous ridge of highly vascularized tissue, here designated the corpus cavernosum maxillaris, runs along the center of the hard palate, expanding cranially to form two large lobes that terminate under the tip of the rostral palate, with another enlarged node at the caudal terminus. Gross anatomical and microscopic observation of tissue sections discloses a web-like internal mass with a large blood volume. Histological examination reveals large numbers of blood vessels and vascular as well as extravascular spaces resembling a blood-filled, erectile sponge. These spaces, as well as accompanying blood vessels, extend to the base of the epithelium. We contend that this organ provides a thermoregulatory adaptation by which bowhead whales (1) control heat loss by transferring internal, metabolically generated body heat to cold seawater and (2) protect the brain from hyperthermia. We postulate that this organ may play additional roles in baleen growth and in detecting prey, and that its ability to dissipate heat might maintain proper operating temperature for palatal mechanoreceptors or chemoreceptors to detect the presence and density of intraoral prey., (Copyright © 2013 Wiley Periodicals, Inc.)

Published

2013

29. Adaptations of the cetacean hyolingual apparatus for aquatic feeding and thermoregulation.

Author

Werth AJ

Subjects

Animals, Female, Male, Tongue anatomy & histology, Tongue physiology, Adaptation, Physiological, Body Temperature Regulation physiology, Feeding Behavior physiology, Hyoid Bone anatomy & histology, Hyoid Bone physiology, Whales anatomy & histology, Whales physiology

Abstract

Foraging methods vary considerably among semiaquatic and fully aquatic mammals. Semiaquatic animals often find food in water yet consume it on land, but as truly obligate aquatic mammals, cetaceans (whales, dolphins, and porpoises) must acquire and ingest food underwater. It is hypothesized that differences in foraging methods are reflected in cetacean hyolingual apparatus anatomy. This study compares the musculoskeletal anatomy of the hyolingual apparatus in 91 cetacean specimens, including 8 mysticetes (baleen whales) in two species and 91 odontocetes (toothed whales) in 11 species. Results reveal specific adaptations for aquatic life. Intrinsic fibers are sparser and extrinsic musculature comprises a significantly greater proportion of the cetacean tongue relative to terrestrial mammals and other aquatic mammals such as pinnipeds and sirenians. Relative sizes and connections of cetacean tongue muscles to the hyoid apparatus relate to differences in feeding methods used by cetaceans, specifically filtering, suction, and raptorial prehension. In odontocetes and eschrichtiids (gray whales), increased tongue musculature and enlarged hyoids allow grasping and/or lingual depression to generate intraoral suction for prey ingestion. In balaenopterids (rorqual whales), loose and flaccid tongues enable great distention of the oral cavity for prey engulfing. In balaenids (right and bowhead whales), large but stiffer tongues direct intraoral water flow for continuous filtration feeding. Balaenid and eschrichtiid (and possibly balaenopterid) mysticete tongues possess vascular retial adaptations for thermoregulation and large amounts of submucosal adipose tissue for nutritional storage. All cetacean tongues also function in prey transport and swallowing. These hyolingual musculoskeletal differences are unique cetacean anatomical adaptations for foraging entirely in an aquatic environment., (2007 Wiley-Liss, Inc.)

Published

2007

30. Odontocete suction feeding: Experimental analysis of water flow and head shape.

Author

Werth AJ

Subjects

Animals, Biomechanical Phenomena, Feeding Behavior physiology, Head physiology, Jaw anatomy & histology, Jaw physiology, Muscles anatomy & histology, Muscles physiology, Tongue anatomy & histology, Tongue physiology, Dolphins physiology, Head anatomy & histology, Predatory Behavior physiology, Sucking Behavior physiology, Water metabolism

Abstract

The role of cranial morphology in the generation of intraoral and oropharyngeal suction pressures in odontocetes was investigated by manipulating the jaw and hyolingual apparatus of submerged heads of three species presenting varied shapes. Hyoid and gular muscles were manually employed to depress and retract the tongue. Pressures were recorded at three locations in the oral cavity, as gape and site, speed, and force of pull were varied. A biomechanical model was also developed to evaluate pressure data. The species with the shortest, bluntest head and smallest mouth opening generated greater negative pressures. Suction generation diminished sharply as gape increased. Greatest negative pressures attained were around -45 mmHg (-6,000 Pa), a magnitude deemed suitable for capture of small live prey. Odontocetes utilizing this bidirectional flow system should profit by evolution of a rounder mouth opening through progressive shortening and widening of the rostrum and jaws, a trend evident in cranial measurements from fossil and recent odontocetes. Blunt heads correlate with anatomical, ecological, and behavioral traits associated with suction feeding. Small-gape suction (with minimally opened jaws) could be used by odontocetes of all head and oral shapes to draw prey sufficiently close to the mouth for suction ingestion or grasping via dentition. Principal limitations of the experimental and mathematical simulations include assumption of a stationary odontocete with static (open or closed) jaws and potential scaling issues with differently sized heads and gapes., (Copyright 2006 Wiley-Liss, Inc.)

Published

2006

31. Models of hydrodynamic flow in the bowhead whale filter feeding apparatus.

Author

Werth AJ

Subjects

Animals, Biomechanical Phenomena, Body Weights and Measures, Models, Anatomic, Pressure, Whales anatomy & histology, Feeding Behavior physiology, Models, Biological, Mouth anatomy & histology, Water Movements, Whales physiology

Abstract

Anatomical and behavioral analyses suggest that the filtration mechanism of bowhead and right whales (Balaenidae) is driven by hydrodynamic as well as ram hydraulic pressures. Complementary models were devised to investigate biomechanical aspects of water flow in the buccal cavity of the bowhead whale Balaena mysticetus during continuous filter feeding. A mathematical model was created to test and quantify water flow predictions with steady state hydromechanical equations; a physical model of the bowhead mouth (approximately 1/15 scale) was constructed to visualize flow processes. Both models rely on morphometric data obtained from whales harvested by Inupiat Eskimos for subsistence purposes along with information on foraging ecology (locomotor velocity, gape, etc.). Results indicate that unique features of balaenid oral construction and function (e.g. subrostral gap, orolabial sulcus, curvature of baleen, extensive mandibular rotation and lingual mobility) not only permit steady, unidirectional flow of water through the mouth, but also establish Bernoulli and Venturi effects during feeding. These hydrodynamic conditions allow balaenids to improve filtering efficiency and avoid creation of an anterior compressive wave (by increasing flow velocity and thereby reducing pressure) so that they may capture elusive prey even at slow swimming speeds.

Published

2004