More than Armor: How Shark Skin Shapes Survival

Have you ever wondered why, if you touch a shark from head to fin, it feels smooth—but from fin to head, it’s skin is rough like sandpaper? Sharks and rays (elasmobranchs) share a common “armor” made of tooth-like dermal denticles (shark skin) embedded over a collagen-rich dermis. This design grants abrasion resistance, drag reduction, and strong defenses against biofouling. And they heal fast!

But denticle shape, size, density, and even skin thickness differ by species, sex, body region, and life stage. Around Onslow County, that means an Atlantic sharpnose shark doesn’t “feel” or function exactly like a spiny dogfish. A blacktip’s leading-edge denticles aren’t the same as those along its flank, and a cownose ray’s smoother disc tells a completely different hydrodynamic story than nearby requiem sharks.

This diversity in structure and function is not just fascinating—it’s functional biology in action, shaping how local species move, heal, and interact with the waters along Onslow County.

What all elasmobranch skin has in common

Dermal denticles (placoid scales)

Sharks and rays share an external armor of dermal denticles—tiny tooth-like structures that reduce drag, resist abrasion, and deter fouling (Domel et al., 2018; Feld et al., 2019). These micro-ridges even inspire engineered materials designed to minimize friction and bacterial attachment (Arisoy et al., 2018; Sakamoto et al., 2014).

A collagen-rich dermis

Beneath those denticles lies a collagen-dense dermis that anchors and supports them, distributing stress and contributing to flexibility and toughness (Hagood et al., 2023, 2025). 

Rapid wound healing

Many sharks heal rapidly—re-epithelializing within days and closing large injuries in weeks to months (Womersley et al., 2021).

Where shark skin differs: species, sex, body region & ontogeny

Species differences.
Denticle shape, ridge count, and spacing vary by ecology. Pelagic species emphasize hydrodynamics, while benthic species prioritize abrasion resistance (Feld et al., 2019).

Body-region mosaics.
Different zones of the same shark serve unique functions: snouts may have smooth, tile-like denticles; trunk and fin edges feature ridged, flow-controlling types (Gabler-Smith et al., 2021).

Sexual dimorphism and mechanical variation.
Hagood et al. (2023) found that male and female sharks differ in denticle structure and stiffness—traits likely linked to mating behavior and mechanical stress.

Ontogenetic and ecomorphological changes.
As sharks grow, skin stiffness and collagen fiber orientation evolve, tuning hydrodynamic and mechanical performance (Hagood et al., 2025).

Sharks vs. rays (and skates): same toolkit, different emphasis

Rays and skates share the elasmobranch blueprint but apply it differently. Cownose rays (Rhinoptera bonasus) maintain smooth discs for gliding over sand, concentrating tougher denticles along midlines or tails. Stingrays, meanwhile, modify certain denticles into venomous spines—an adaptation to benthic life (Smith & Merriner, 1987).

Mucus: the invisible modifier

Fischer, Lauder, and Wainwright (2025) discovered that mucus secretion selectively coats certain body regions, altering roughness, ridge exposure, and tactile function. This flexible coating regulates drag, microbial colonization, and frictional properties. Combined with collagen variation (Hagood et al., 2023, 2025), it reveals shark skin as a living, adaptive surface rather than static armor.

Local lens: Onslow County species & mucus implications

• Atlantic sharpnose shark (Rhizoprionodon terraenovae) — Mucus along fin and tail tips fine-tunes hydrodynamics (Fischer et al., 2025).
  
• Blacktip shark (Carcharhinus limbatus) — Fin-tip mucus reduces flow separation during rapid bursts (Domel et al., 2018; Fischer et al., 2025).
  
• Spiny dogfish (Squalus acanthias) — Abrasion-resistant denticles limit fouling; mucus films aid transitions (Feld et al., 2019; Pogoreutz et al., 2019).
  
• Bonnethead (Sphyrna tiburo) — Mucus along cephalofoil edges smooths high-shear zones (Fischer et al., 2025; Doane et al., 2020).
  
• Cownose ray (Rhinoptera bonasus) — Disc-margin mucus reduces friction and microbial buildup (Smith & Merriner, 1987; Pogoreutz et al., 2019).

Microflow around denticles: visualizing eddies and recirculation

Feld et al. (2019) used microscopy and micro-Particle Image Velocimetry to reveal recirculation bubbles and coherent vortices downstream of denticle ridges. Even at low speeds, these micro-eddies enhance self-cleaning and reduce fouling by increasing localized shear stress. In Onslow County’s spiny dogfish and other bottom dwellers, such micro-flow effects likely complement mucus modulation (Fischer et al., 2025) and the micro-whirlpools described by Choi (2012), confirming that shark skin actively interacts with flow.

Microstructure and biomimetic insights

Gabler-Smith et al. (2022) compared natural shark denticle surfaces to engineered riblet models and found that synthetic designs fail to capture the fine ridge geometry and spacing that real denticles use to control turbulent flow. These ridges, grooves, and curvature features are essential for maintaining boundary layer stability and minimizing drag.

Building on that foundation, Lang (2020) demonstrated that shortfin mako sharks (Isurus oxyrinchus) take this mechanical sophistication a step further. Their denticles can actively bristle—flexing outward up to 50° in milliseconds when the local flow begins to reverse. This rapid, passive response delays flow separation, reduces pressure drag, and smooths turbulent eddies. In essence, mako skin behaves like a living flow-control surface that adjusts dynamically to hydrodynamic forces.

Lang’s work underscores that the mako’s speed and efficiency derive not only from its streamlined body but also from this microstructural flexibility. When viewed alongside the mini-whirlpool mechanisms observed by Choi (2012) and the mucus-texture modulation reported by Fischer et al. (2025), it becomes clear that shark skin represents a hierarchy of adaptive flow solutions—ranging from microscopic bristling denticles to chemical and structural tuning at the surface.

For Onslow County species such as blacktip and spinner sharks, similar flow-adaptive strategies likely exist at smaller scales: flexible denticle alignment, mucus film adjustment, or localized stiffening along the fin and tail margins. Together, these traits demonstrate how elasmobranch skin functions as both armor and engine, a natural template for future biomimetic technologies in marine and aerospace design.

Mini whirlpools and flexible flow control

According to LiveScience, flexible shark skin samples generate tiny whirlpools that enhance propulsion when the surface bends dynamically (Choi, 2012). These results, together with mucus smoothing and collagen adaptability, show that shark skin functions as an active flow-control system—part armor, part hydrodynamic engine (Fischer et al., 2025; Hagood et al., 2023, 2025).

Interfacing skin, gills, and chemical exposure

Fish gills actively metabolize dissolved substances. Similarly, shark mucus and microbiome layers may act as chemical filters, reducing exposure to pollutants in Onslow County’s estuarine waters (Wood & Giacomin, 2016).

Conservation and historical context: denticles as time capsules

Beyond living sharks, dermal denticles persist long after death, providing a fossil record of shark diversity. Researchers have extracted and identified denticles from reef sediments to reconstruct past shark communities—essentially using these microscopic scales as ecological fingerprints through time (Dillon, 2015). Applying similar sediment-based studies to the Onslow County coast could help reveal how local shark assemblages have changed, offering a baseline for modern conservation and recovery efforts.

Functional synergy in Onslow County sharks

References

Anderson, S. D., Kanive, P. E., Chapple, T. K., Andrzejaczek, S., Block, B. A., & Jorgensen, S. J. (2025). A classification system for wounds and scars observed on white sharks (Carcharodon carcharias). Frontiers in Marine Science, 12, Article 1520348. https://doi.org/10.3389/fmars.2025.1520348

Arisoy, F. D., Gurkan, U. A., Yagci, B. B., Calamak, S., Dokmeci, M. R., & Demirci, U. (2018). Bioinspired photocatalytic shark-skin surfaces with antibacterial properties. Scientific Reports, 8, 16363. https://doi.org/10.1038/s41598-018-34334-1 

Choi, C. Q. (2012, February 21). Sharks’ scales create tiny whirlpools for speedy swimming. LiveScience. https://www.livescience.com/18385-shark-skin-mini-whirlpools.html

Dillon, E. (2015, October 9). Shark skin sleuthing. Save Our Seas Foundation. https://saveourseas.com/update/shark-skin–sleuthing/

Dillon, E. M., O’Dea, A., & Norris, R. D. (2017). Dermal denticles as a tool to reconstruct shark communities. Marine Ecology Progress Series, 566, 117–134. https://doi.org/10.3354/meps12018

Doane, M. P., Haggerty, J. M., Kacev, D., Papudeshi, B., & Dinsdale, E. A. (2020). The skin microbiome of elasmobranchs follows phylosymbiosis, but in teleost fishes, the microbiomes converge. Microbiome, 8(1), 123. https://doi.org/10.1186/s40168-020-00840-x 

Domel, A. G., Weaver, J. C., Haj-Hossein, I., Wang, Z., Bertoldi, K., Lauder, G. V., & Vaziri, A. (2018). Shark skin-inspired designs that improve aerodynamic performance. Journal of the Royal Society Interface, 15(140), 20170828. https://doi.org/10.1098/rsif.2017.0828 

Wood, C., Giacomin, M. (2016) Feeding through your gills and turning a toxicant into a solution. Journal of Experimental Biology, 219(20), 3218–3228. https://doi.org/10.1242/jeb.145625 

Feld, K., Kolborg, A. N., Nyborg, C. M., Salewski, M., Steffensen, J. F., & Berg-Sørensen, K. (2019). Dermal denticles of three slowly swimming shark species: Microscopy and flow visualization. Biomimetics, 4(2), 38. https://doi.org/10.3390/biomimetics4020038 

Fischer, M. J., Lauder, G. V., & Wainwright, D. K. (2025). Slippery and smooth shark skin: How mucus transforms surface texture. Journal of Morphology, 286(4), e70046. https://doi.org/10.1002/jmor.70046 

Gabler-Smith, M. K., Lauder, G. V., et al. (2022). Ridges and riblets: Shark skin surfaces versus biomimetic models. Frontiers in Marine Science, 9, 975062. https://doi.org/10.3389/fmars.2022.975062 

Gabler-Smith, M. K., Staab, K. L., & Motta, P. J. (2021). Dermal denticle diversity in sharks: Novel patterns on the interbranchial skin. Biology Letters, 17(12), 20210349. https://doi.org/10.1098/rsbl.2021.0349 

Hagood, M. E., Motta, P. J., Staab, K. L., & Porter, M. E. (2023). Relationships in shark skin: Mechanical and morphological correlates of dermal denticles. Integrative and Comparative Biology, 63(6), 1154–1166. https://doi.org/10.1093/icb/icad085 

Hagood, M. E., Wainwright, D. K., Motta, P. J., & Vaziri, A. (2025). Ecomorphology and ontogeny modulate the mechanical properties of shark skin. Journal of Experimental Zoology Part B: Molecular and Developmental Evolution. Advance online publication. https://doi.org/10.1016/j.jcz.2025.xxxxxx 

Lang, A. W. (2020, April). The speedy secret of shark skin. Physics Today, 73(4), 62–63. https://digital.physicstoday.org/physicstoday/april_2020/MobilePagedArticle.action?articleId=1575067

Pogoreutz, C., Yakob, L., Zhang, Y., Al-Saoudi, N. H., Olsson, A., El-Sherbiny, M., … Hajdu, E. (2019). Similar bacterial communities on healthy and injured shark skin samples suggest absence of severe bacterial infections. Animal Microbiome, 1, 11. https://doi.org/10.1186/s42523-019-0011-5 

Sakamoto, A., Oikawa, K., & Yamaguchi, M. (2014). Antibacterial effects of protruding and recessed shark-skin micropatterned surfaces. Biofouling, 30(5), 593–602. https://doi.org/10.1080/08927014.2014.930720 

Smith, J. W., & Merriner, J. V. (1987). Age and growth, movements and distribution of the cownose ray (Rhinoptera bonasus) in the western North Atlantic Ocean. Environmental Biology of Fishes, 20, 233–242. https://doi.org/10.1007/BF00004913 

Womersley, F., Rohner, C. A., Gibbons, M. J., Richardson, A. J., & Jaine, F. R. A. (2021). Wound-healing capabilities of whale sharks (Rhincodon typus). Conservation Physiology, 9(1), coaa137. https://doi.org/10.1093/conphys/coaa137