Fact-checked by Grok 2 weeks ago

Dermatoglyphics

Dermatoglyphics is the scientific study of the epidermal ridge patterns, known as dermatoglyphs, found on the skin of the fingers, palms, toes, and soles.^[1] These patterns form during early fetal development, specifically between the 10th and 16th weeks of intrauterine life, through a process involving the interaction of epidermal cells and underlying dermal structures, resulting in unique, permanent configurations that do not change after birth.^[2] The term "dermatoglyphics," derived from the ancient Greek words derma (skin) and glyphē (carving), was coined in 1926 by anatomists Harold Cummins and Charles Midlo to describe these ridge formations systematically.^[3] The study of dermatoglyphics originated from earlier observations, such as Johannes Evangelista Purkinje's 1823 classification of fingerprint patterns into nine types, but gained prominence in the 20th century through its integration with genetics and anthropology.^[4] These ridge patterns are influenced by both genetic and environmental factors during embryogenesis, serving as an indelible record of fetal hand and foot morphology, and exhibit variations that can indicate population differences or hereditary traits.^[5] Dermatoglyphic analysis has revealed associations between specific ridge configurations and chromosomal disorders, such as trisomy 21 (Down syndrome), where patterns like increased ulnar loops and simian creases are more prevalent.^[6] Beyond identification in forensics—where fingerprints provide a reliable means of personal authentication—dermatoglyphics finds applications in medical diagnostics, biological anthropology, and even dentistry, aiding in the early detection of genetic conditions, assessment of ethnic variations, and evaluation of predispositions to diseases like schizophrenia or certain cancers.^[7] In anthropology, it helps trace human migration and genetic diversity by comparing ridge minutiae across populations, while ongoing research explores its potential in personalized medicine and pharmaceutical development.^[8] Despite its utility, interpretations must account for the interplay of multifactorial influences to avoid overgeneralization.

Fundamentals

Definition and Scope

Dermatoglyphics is the scientific study of the ridge patterns formed by friction ridges on the volar surfaces of the hands and feet, including the fingers, palms, toes, and soles.^[1] The term derives from the Ancient Greek words derma, meaning "skin," and glyphē, meaning "carving," reflecting the carved-like configurations of these epidermal features.^[8] These patterns encompass both qualitative elements, such as the arrangement of loops, whorls, and arches, and quantitative measures, like ridge counts between specific landmarks.^[9] The scope of dermatoglyphics extends to the analysis of these patterns' formation, variation, and implications across populations, with a focus on their establishment during fetal development between approximately 10 and 24 weeks of gestation.^[10] Once formed, the ridges remain permanent throughout life, resisting significant alteration from postnatal growth, environmental factors, or most injuries, though scarring from severe trauma can disrupt them locally.^[11] Biologically, friction ridges serve to enhance grip and traction by increasing surface friction and regulating moisture during manipulation of objects, while also amplifying tactile sensitivity through greater contact area with the environment.^[12] They arise from primary dermal ridges, which develop first and contain sweat glands, and secondary ridges, which form between them to further expand the skin's surface.^[10] Unlike pseudoscientific practices such as chiromancy, or palm reading, which interpret hand features for divination or personality assessment, dermatoglyphics relies on empirical methods to examine ridge patterns for objective insights.^[13] It is also distinct from clinical dermatology, which addresses skin pathologies, by instead emphasizing anthropological population studies, genetic inheritance patterns, and forensic identification based on ridge uniqueness.^[3]

Embryological Formation

The formation of dermatoglyphic patterns takes place during the first trimester of fetal development, primarily through interactions between the ectoderm and mesoderm at the epidermal-dermal junction.^[10] This process is influenced by both genetic programming and environmental factors, such as mechanical stresses from fetal movements and the configuration of temporary volar pads on the digits.^[14] Volar pads, which emerge around 6-7 weeks of gestation as localized swellings of mesenchymal tissue, serve as scaffolds that guide the orientation of emerging ridges, for instance, determining whether loops form radially or ulnarly based on pad positioning and regression timing.^[15] Ridge development follows a precise timeline: primary dermal ridges initiate at 10-12 weeks of gestation via focal proliferation of basal keratinocytes, aligning with underlying capillaries and nerves to form the foundational epidermal undulations.^[10] Secondary ridges, which are shallower and lack sweat gland associations, develop between 16 and 21 weeks through interstitial growth between primaries, completing the mature pattern by 24 weeks.^[14] At this stage, patterns are largely fixed, as subsequent fetal growth occurs uniformly without disrupting the established architecture, minimizing the impact of later environmental teratogens.^[15] Genetically, dermatoglyphics arise from polygenic inheritance, with multiple loci contributing to trait variation and no single gene dominating the process.^[16] Heritability estimates are modest for qualitative pattern types (e.g., arches versus whorls) due to their categorical nature but substantially higher for quantitative features like ridge counts, ranging from 0.65 to 0.96 across traits.^[17] Key pathways include epidermal growth factor signaling through EGFR, which drives ridge outgrowth and sweat gland induction, as evidenced by altered patterns in EGFR-mutant models.^[14] Limb development genes, such as those in WNT and EDAR pathways, further modulate pattern formation by influencing pre-ridge dermal organization.^[16] Postnatally, dermatoglyphic patterns exhibit remarkable permanence, remaining unaltered due to the limited regenerative capacity of volar epidermis and the stable anchoring of ridges to the dermis, which prevents remodeling except in cases of severe injury.^[10] This developmental outcome yields the diverse ridge configurations analyzed in subsequent classifications.^[15]

Ridge Patterns and Classification

Dermatoglyphic ridge patterns on the fingers, palms, and soles are formed by the arrangement of epidermal ridges and furrows, primarily classified into three main types: arches, loops, and whorls, based on the direction of ridge flow and the presence of triradii, which are points where three ridge systems meet.^[9] Arches, occurring in approximately 5-10% of patterns, feature ridges that enter from one side of the digit or palm, rise in the center, and exit on the opposite side without forming a recurve or enclosing a core; subtypes include simple arches, with a gentle rise, and tented arches, characterized by a steeper, more peaked central elevation.^[9] Loops, the most prevalent type at 60-70%, involve ridges that enter and exit on the same side, forming a single recurve with one triradius (delta) on the side opposite the recurve; they are subdivided into ulnar loops, opening toward the ulnar (pinky) side, and radial loops, opening toward the radial (thumb) side.^[9] Whorls, comprising 25-35% of patterns, exhibit ridges that form circular, spiral, or elliptical arrangements around a central core, typically with two triradii; subtypes include plain whorls with symmetrical concentric circles, central pocket loops with a small loop inside a whorl, double loops (or twinned loops) featuring two adjacent loops, and accidental whorls as complex composites not fitting other categories.^[9]^[18] On the palms and soles, ridge patterns extend beyond digital configurations to include configurational areas and linear features. The main line index traces the primary palmar ridge systems, labeled A (from triradius a near the base of the index finger), B (from triradius b in the palm center), C (from triradius c near the hypothenar eminence), and D (from triradius d on the hypothenar), which course across the palm and are used to assess overall ridge alignment.^[9] Flexion creases, stable furrows overlying deeper flexor tendons, include the distal transverse crease (heart line), proximal transverse crease (head line), and radial longitudinal crease (life line); variants such as the simian crease represent a fusion of the heart and head lines into a single transverse crease.^[9] Hypothenar patterns, located on the ulnar side of the palm opposite the thumb, commonly feature whorls, twinned loops, elongated whorls, or arches, while thenar mounts on the radial side exhibit loops (opening downward, rightward, leftward, or upward) or whorls.^[9] Plantar patterns mirror palmar ones, with analogous main lines (A' to D'), triradii, and flexion creases on the soles, though arches and loops predominate in toe patterns similar to digits.^[19] Classification systems standardize these patterns for identification and comparative studies. Sir Francis Galton's foundational tripartite system categorizes digital patterns alphabetically as arches (A), loops (L), or whorls (W), enabling basic sorting of impressions from multiple fingers.^[18] Sir Edward Henry's extension, the 10-fingerprint classification, refines this by assigning numerical values to whorls (e.g., 16 for right thumb, 1 for left little finger) in a primary ratio, supplemented by secondary codes for index finger patterns (e.g., A for arch, T for tented arch, R for radial loop, U for ulnar loop, W for whorl) and subsecondary ridge tracings, yielding over 1,000 groupings for forensic filing.^[18] For anthropological comparisons, international standards employ hierarchical schemes with five major configurational classes (e.g., arches, ulnar loops, radial loops, whorls, composites), each subdivided into up to 90 categories based on ridge symmetry, core positions, and triradii, facilitating cross-population analyses.^[20] Pattern variations reflect biological influences, including sexual dimorphism, ethnic differences, and bilateral asymmetry. Males typically exhibit a higher frequency of whorls (around 36-37%) compared to females (34-35%), with females showing more ulnar loops, as observed in South Asian populations.^[21] Ethnic groups display distinct distributions; for instance, East Asian populations, such as Han Chinese, have lower arch frequencies (2-5%) and higher whorl prevalences (up to 50-60%) relative to European or African groups, where arches may reach 5-10% and loops dominate more evenly.^[22]^[23] Asymmetry between hands is common, with the right hand often showing more whorls and the left more loops in right-handed individuals, though patterns remain stable bilaterally within the same person.^[21]

Historical Development

Early Observations and Pioneers

Early observations of dermatoglyphics, the study of skin ridge patterns on fingers, palms, toes, and soles, trace back to ancient civilizations where fingerprint impressions appeared incidentally on artifacts, though without systematic analysis or recognition of their uniqueness for identification. In ancient Mesopotamia, around 3000 B.C., finger impressions were pressed into clay bricks from the Lagash dynasty and onto tablets associated with contracts, serving as rudimentary token marks rather than deliberate identifiers. Similarly, in Babylon circa 1900 B.C., impressions appear on clay tablets associated with business transactions, as evidenced by archaeological finds, but these were not studied scientifically.^[24] The first anatomical precursor to modern dermatoglyphics came in the 17th century from Italian physician Marcello Malpighi, who in 1686 used early microscopes to describe the ridged structure of friction skin in his treatise De pulpitis (later compiled as Concerning the External Tactile Organs in 1687), noting the layered papillae and their role in tactile sensation, which laid groundwork for understanding ridge formation without proposing identification uses.^[25] Scientific interest emerged in the 19th century with Jan Evangelista Purkyně, a Czech physiologist, who in his 1823 doctoral thesis Commentatio de examine physiologico organi visus et systematis cutanei provided the earliest systematic classification of fingerprint patterns, identifying nine types based on geometric forms such as arches, loops, whorls, and composites, accompanied by engravings that highlighted variations in papillary lines. This work, though limited in circulation and not focused on individuality, represented the inaugural attempt at categorizing dermatoglyphic features.^[26]^[25] Practical applications began in 1858 when British administrator William James Herschel, serving in India, required handprints on contracts to deter fraud and confirm identities among illiterate workers, observing the permanence and variability of ridge patterns over time, which convinced him of their utility for establishing personal uniqueness in administrative contexts. Building on such insights, Scottish missionary Henry Faulds, working in Japan in the mid-1870s, recognized fingerprints' potential in criminal investigations after studying impressions left at crime scenes, publishing his findings in 1880 in Nature magazine, where he advocated for their use in identification due to inherent uniqueness and classifiability.^[25]

Key Scientific Milestones

In 1892, Francis Galton published his seminal book Finger Prints, which rigorously demonstrated the uniqueness of fingerprint patterns and their hereditary nature through extensive comparative analysis of prints from diverse populations. Galton calculated the probability of two individuals sharing identical fingerprints as approximately 1 in 64 billion, based on the variability in ridge formations and minutiae, laying the foundational statistical framework for their use in personal identification. This work shifted dermatoglyphics from anecdotal observation to a scientifically grounded discipline, influencing subsequent forensic and genetic applications. Building on Galton's insights, Edward Henry developed a systematic classification scheme for fingerprints in the 1890s, first detailed in his 1900 book Classification and Uses of Finger Prints. This system, which categorized prints by core types (loops, whorls, arches) and ridge counts, was adopted by Scotland Yard in 1901 as the standard for criminal identification, replacing anthropometric measurements like Bertillonage. By the early 1900s, Henry's method achieved global standardization in law enforcement agencies, enabling efficient filing and matching of prints across international borders and solidifying dermatoglyphics' role in forensics. The term "dermatoglyphics" was coined in 1926 by anatomist Harold Cummins to encompass the scientific study of epidermal ridge patterns on fingers, palms, and soles, distinguishing it from narrower fingerprint analysis. In collaboration with Charles Midlo, Cummins published Finger Prints, Palms and Soles: An Introduction to Dermatoglyphics in 1929, which provided the first comprehensive systematization of the field, including morphological classifications, developmental embryology, and anthropological variations. This text established dermatoglyphics as an interdisciplinary science bridging anatomy, genetics, and anthropology, with enduring influence on methodological standards. From the 1940s to the 1960s, Lionel Penrose advanced dermatoglyphics into medical genetics by identifying distinctive ridge patterns in individuals with Down syndrome (trisomy 21), such as increased ulnar loops and single transverse palmar creases, through studies at the Galton Laboratory. Penrose's research, including his 1963 memorandum on nomenclature and analyses of pattern asymmetries, highlighted dermatoglyphics as markers of chromosomal anomalies formed during early fetal development. He also pioneered the total finger ridge count (TFRC)—the sum of ridge tracings from all ten fingers—as a quantitative, heritable trait with high genetic correlation (heritability estimates around 0.95), facilitating its use in population genetics and twin studies. In the 1970s, following the 1950s discovery of DNA structure and advances in cytogenetics, Beverly Schaumann and Milton Alter synthesized these developments in their 1976 book Dermatoglyphics in Medical Disorders, a comprehensive review drawing on hundreds of references on ridge pattern deviations in chromosomal and congenital conditions. This work integrated dermatoglyphics with karyotyping techniques, demonstrating how epidermal patterns serve as non-invasive proxies for genetic screening, particularly in trisomies, and spurred further research in clinical cytogenetics.

Analytical Techniques

Qualitative Assessment

Qualitative assessment in dermatoglyphics involves the visual examination and categorization of epidermal ridge configurations on fingers, palms, and soles to identify pattern types and structural features without relying on numerical metrics. This approach emphasizes descriptive classification to discern overall morphology, aiding in initial pattern recognition for further analysis or comparison. Common tools include rolled ink prints, where the digit is rolled from nail to nail edge to capture complete ridge flow, or inkless scanners that produce digital images via chemical reactions on coated paper for cleaner, non-messy collection.^[27]^[28] Pattern identification on digits follows a systematic process focusing on ridge flow, cores (innermost ridge points), and deltas (triangular ridge junctions). First, observe the general direction of ridges: arches are characterized by simple, wave-like flows entering one side of the digit and exiting the opposite without recurving, lacking any deltas. Loops exhibit ridges entering from one side (ulnar or radial), recurving around a core, and exiting the same side, marked by a single delta. Whorls display circular or spiral ridge arrangements encircling a central core, typically with two deltas where ridges diverge. These distinctions rely on tracing ridge paths relative to the core and delta positions to confirm subtype variations, such as tented arches or central pocket loops.^[29]^[30] Palmar analysis entails tracing the four primary main lines—A originating near the base of the index finger from triradius a, B from the middle finger base via triradius b, C from the ring finger base through triradius c, and D from the percussion border via triradius d—to assess their terminations and intersections. Triradii positions are located as focal points where three ridge systems converge, providing landmarks for line mapping. Anomalies, such as the single transverse palmar crease formed by the fusion of the proximal and distal transverse creases into a single continuous line across the palm, are noted for their deviation from the typical three-crease configuration.^[31] Standardization employs established systems like the Galton classification, which delineates eight primary finger pattern subtypes including plain arches, tented arches, ulnar loops, and various whorls to ensure consistent categorization across studies. Manual assessments demonstrate reliable inter-observer agreement, with Cohen's kappa values around 0.86 indicating low variability, though slight discrepancies (typically under 10%) can arise compared to automated tools due to subjective interpretation of ridge boundaries. Practical protocols for soles involve similar inking techniques but with added magnification (e.g., 10x lenses) to resolve finer, more spaced ridges, while systems like AFIS facilitate preliminary qualitative sorting by grouping prints into broad pattern classes before detailed review.^[32]^[33]^[34]

Quantitative Measurements

Quantitative measurements in dermatoglyphics involve numerical assessments of epidermal ridge configurations on fingers and palms, providing quantifiable data for genetic, medical, and anthropological analyses. These metrics, developed from early ridge-counting methods, enable statistical comparisons across populations and individuals, often revealing subtle developmental influences fixed during fetal gestation. Key measurements focus on ridge densities and distributions, with formulas standardized to ensure reproducibility across studies. The Total Finger Ridge Count (TFRC) is a primary quantitative metric, calculated as the sum of ridge counts from the core of each finger pattern to the nearest triradius (delta), excluding the ridges forming the core itself. For loop patterns, the count is the number of ridges intersected by a straight line from the core to the delta; arches are assigned a count of zero; and whorls use the higher count from either triradius to the core. Thumbs are included, though partial patterns may yield lower counts. The formula is:

\text{TFRC} = \sum_{i=1}^{10} \text{ridge count on finger } i

In general populations, average TFRC values range from 140 to 150, with sexual dimorphism evident as males typically exhibit higher counts (approximately 145) than females (around 130), reflecting androgen influences on prenatal ridge formation.^[35]^[36] The A-B ridge count measures the number of epidermal ridges between the a-triradius (located proximally on the palm's axial side) and the b-triradius (on the hypothenar eminence), serving as a proxy for prenatal brain lateralization and overall neurological development. This count is taken along the most direct path between the two triradii, typically yielding values of 35 to 40 in healthy adults, with females often showing slightly higher averages than males due to differences in palmar ridge spacing.^[37]^[38] Additional metrics include the Absolute Finger Ridge Count (AFRC), which sums all possible ridge counts across the ten fingers—including both directions for whorls, unlike TFRC—resulting in higher totals that emphasize overall ridge density. Pattern intensity, calculated as the ratio of complex to simple patterns, uses the formula:

\text{Pattern Intensity} = \frac{2 \times \text{number of whorls} + \text{number of loops}}{10}

This yields values from 0 (all arches) to 2 (all whorls), with population averages around 1.0 to 1.5, higher in males. Fluctuating asymmetry assesses developmental instability by computing the absolute difference between left and right hand values for traits like TFRC (e.g., \text{FA}_{\text{TFRC}} = |\text{TFRC}_{\text{left}} - \text{TFRC}_{\text{right}}|), where elevated asymmetry indicates prenatal stress or genetic perturbations.^[39]^[40]^[41] Statistical analysis of these measurements relies on normative databases stratified by ethnicity, sex, and age, such as those derived from large-scale population surveys, to compute z-scores for detecting anomalies (e.g., a TFRC exceeding 2 standard deviations from the population mean may signal chromosomal disorders). These tools facilitate probabilistic assessments in clinical settings, prioritizing high-impact deviations over exhaustive data.^[42]^[43]

Applications in Genetics

Associations with Chromosomal Disorders

Dermatoglyphic anomalies are prominent in Down syndrome (trisomy 21), where fingertip patterns show a marked increase in ulnar loops, comprising approximately 70-80% of patterns compared to 50-65% in the general population. A single transverse palmar crease, also known as the simian crease, occurs in about 50% of cases, and there is characteristic distal displacement of triradii, resulting in an elevated atd angle. The total finger ridge count (TFRC) is typically reduced by 20-30% relative to unaffected individuals, reflecting disrupted ridge development during embryogenesis.^[44]^[45]^[46] In Klinefelter syndrome (47,XXY), arch patterns on the fingers are more frequent, observed in roughly 15% of cases versus 5% in controls, accompanied by elevated hypothenar patterns on the palms. The a-b ridge count is increased, contributing to quantitative differences from normal karyotypes.^[47]^[48] Turner syndrome (45,X) features a high incidence of the simian crease, increased TFRC (averaging 150-160 compared to 144 in female controls), and increased radial loops on the fingertips.^[43] Trisomy 13 and trisomy 18 exhibit distinctive patterns including elevated radial loops and ectopic axial triradii on the palms. In fragile X syndrome, individuals often display narrow palms with a predominance of arch patterns.^[49]^[43] These specific dermatoglyphic markers aid in the non-invasive screening of chromosomal disorders, offering a sensitivity of 70-90% when integrated with karyotype analysis for confirmatory diagnosis.^[43]^[50]

Inheritance and Population Studies

Dermatoglyphic traits demonstrate moderate to high heritability, reflecting a strong genetic basis shaped by polygenic and multifactorial inheritance mechanisms. Ridge counts, such as the total finger ridge count (TFRC), exhibit high heritability estimates ranging from 80% to 90%, while qualitative pattern types like loops, whorls, and arches show lower heritability of approximately 40% to 60%. Twin studies consistently support these findings, revealing higher concordance rates for TFRC in monozygotic (MZ) twins compared to dizygotic (DZ) twins, indicating predominant additive genetic effects with minimal shared environmental influence. For instance, MZ twin pairs display intraclass correlations for TFRC exceeding 0.90, far surpassing those in DZ pairs (around 0.50), underscoring the role of genetic factors in ridge formation during embryogenesis.^[51]^[52]^[53] Inheritance of dermatoglyphics does not follow simple Mendelian patterns but involves multiple genes interacting with environmental factors during fetal development, with no single locus accounting for major variation. Sex-linked influences are evident, particularly from the X and Y chromosomes, which affect loop directionality; for example, the X chromosome contributes to radial-ulnar loop asymmetry, with males showing stronger Y-linked effects on radial loop prevalence. This multifactorial mode is further evidenced by the absence of dominant-recessive segregation and the presence of epistatic interactions among polygenic loci.^[54]^[55] Population studies highlight geographic variations in dermatoglyphic traits, reflecting genetic drift, founder effects, and historical migrations. Europeans typically exhibit higher whorl frequencies (around 35%), while African populations show a predominance of loops (approximately 70%), with arches being less common across groups. These differences aid in admixture analyses, where intermediate pattern frequencies in mixed populations, such as African-European descendants, track gene flow and migration histories, as seen in studies of admixed Latin American cohorts. Evolutionary pressures likely favored ridge configurations for enhanced grip and friction control in primates, including humans, promoting adaptations for arboreal and terrestrial locomotion. Additionally, fluctuating asymmetry in ridge counts and patterns serves as a proxy for heterozygosity, with increased bilateral differences indicating reduced genetic diversity and higher developmental instability under inbreeding or stress.^[56]^[57] Recent advances in research methods, such as genome-wide association studies (GWAS), have pinpointed specific loci influencing dermatoglyphic variation. In East Asian populations, GWAS identified 18 loci associated with fingerprint patterns, including variants near limb development genes like EVI1, which modulate whorl and loop formation through ectodermal signaling pathways. These findings emphasize polygenic control and offer insights into how ancient selective sweeps shaped population-specific traits.^[58]

Applications in Medicine

Diagnostic Indicators for Congenital Conditions

Dermatoglyphics serve as valuable markers for non-chromosomal congenital malformations, reflecting disruptions in fetal development during the critical period of epidermal ridge formation between the 10th and 16th weeks of gestation. These patterns, formed concurrently with organogenesis, can indicate prenatal insults such as genetic mutations, environmental teratogens, or vascular anomalies that affect multiple systems without altering chromosomal structure. By analyzing fingerprint types (arches, loops, whorls), ridge counts, and palmar configurations, clinicians can identify subtle deviations that strengthen diagnostic suspicions when integrated with physical examinations and imaging.^[59] In congenital heart defects, such as ventricular septal defects or tetralogy of Fallot, affected individuals often exhibit altered whorl patterns on the fingertips and elevated a-b ridge counts on the palms. These alterations are attributed to disrupted fetal blood flow or genetic factors impacting limb bud development, providing a non-invasive indicator for at-risk pregnancies.^[60] For cleft lip with or without cleft palate, dermatoglyphic profiles typically show an increased frequency of arch patterns and reduced total finger ridge count (TFRC). These features arise from maxillary process fusion failures around weeks 6-10, mirroring ectodermal disruptions, and have been employed in prenatal risk assessment to evaluate multifactorial inheritance, particularly in families with recurrence risks of 3-5%.^[61]^[62] Rubella embryopathy, resulting from maternal infection in the first trimester, is characterized by distal displacement of palmar triradii (e.g., t" triradius positioned proximally) and heightened pattern symmetry across hands. These symmetric shifts reflect teratogenic effects on epidermal growth around week 8, often co-occurring with cataracts and deafness, and aid in confirming intrauterine rubella exposure retrospectively.^[63]^[64] Neural tube defects, including spina bifida and anencephaly, demonstrate elevated ulnar loop frequencies and variants of single transverse palmar creases. Such patterns signal neural crest migration anomalies during weeks 3-4, preceding ridge formation, and correlate with incomplete spinal closure, offering ancillary evidence in dysmorphology evaluations.^[65] In clinical practice, dermatoglyphic analysis is integrated with prenatal ultrasound for enhanced detection of these conditions, as ridge patterns remain stable postnatally and complement real-time imaging of structural anomalies. Seminal 1960s work by Lionel Penrose established scoring criteria using multiple traits—like ridge counts, triradii positions, and pattern intensities—to quantify syndrome probabilities, with scores above 4 indicating high likelihood in non-chromosomal malformations when combined with clinical signs. This multivariate approach, refined from earlier topological models, supports risk stratification without invasive testing.^[59]

Links to Acquired Diseases

Dermatoglyphic patterns, formed during fetal development, have been investigated for their potential associations with acquired diseases that manifest later in life, offering insights into prenatal influences on adult-onset conditions. These correlations are thought to reflect early neurodevelopmental or physiological disruptions, though they remain probabilistic rather than deterministic markers.^[40] In schizophrenia, studies have identified overall dermatoglyphic deviations, including lower total finger ridge count (TFRC), consistent with meta-analytic evidence of small but significant deviations (effect size g = -0.20 for TFRC). These findings support the neurodevelopmental hypothesis of schizophrenia, suggesting prenatal disruptions around weeks 14-16 of gestation. Meta-analyses further indicate overall dermatoglyphic deviations of approximately 10-15% from normative patterns across multiple traits.^[40] For hypertension, research consistently shows a higher frequency of whorl patterns in affected individuals compared to normotensive controls, observed across multiple studies including those from the late 20th century. Palmar a-b ridge counts are often reduced, though total ridge counts may be higher overall. Investigations from the 1970s and onward, such as those examining digital patterns, have linked these traits to an approximate 20% increased risk of hypertension in predisposed populations.^[66] In diabetes mellitus, type 1 cases exhibit altered patterns including increased whorls, while type 2 cases show excess arches (e.g., 6.57% prevalence vs. 5.5% in controls), with decreased whorl frequency. These patterns have been explored for use in epidemiological screening to identify at-risk individuals in populations.^[7]^[67] Regarding breast cancer, specific palmar patterns serve as potential risk markers, particularly in high-risk families; for instance, a higher mean ATD angle (e.g., 48.07° on the right palm vs. 45.12° in controls) has been associated with increased susceptibility. Elevated b-c ridge counts and alterations in main line A (indicating proximal displacement or higher ridge termination) have also been reported as indicative traits in affected women. These quantitative palmar features may aid in early risk stratification.^[68]^[69] Despite these associations, dermatoglyphic links to acquired diseases are correlative rather than causal, often influenced by confounders such as ethnicity, age, and environmental factors during prenatal development. Large-scale validation is needed to establish clinical utility, as patterns reflect fixed developmental outcomes without implying direct pathogenesis.^[66]^[40]

Broader Applications

Forensic and Identification Uses

Dermatoglyphics, particularly fingerprints, have been integral to forensic science since the early 20th century, when law enforcement agencies began adopting them for identifying latent prints left at crime scenes. In 1901, New Scotland Yard established the world's first Fingerprint Branch, utilizing the Henry System to classify and compare latent impressions for criminal investigations.^[70] By 1903, the New York State Prison System implemented fingerprinting, marking a key milestone in the United States where it resolved cases of mistaken identity previously reliant on anthropometric measurements.^[71] This shift was driven by the recognition of fingerprints' permanence and individuality, as demonstrated by Francis Galton in his 1892 work Finger Prints, where he calculated the probability of two full fingerprints matching at approximately 1 in 64 billion based on ridge pattern variations.^[70] The uniqueness of fingerprints underpins their forensic reliability, with the traditional 12-point matching rule—requiring agreement on at least 12 minutiae points—historically ensuring identification certainty.^[72] Modern analyses, building on Galton's foundational probability models, estimate the chance of a coincidental 12-minutiae match between distinct fingerprints as extraordinarily low, often below 1 in 10^30 depending on print quality and minutiae count, far exceeding practical population scales for false positives.^[73] Automated systems like the Automated Fingerprint Identification System (AFIS), developed in the 1970s, enhance this process by algorithmically extracting and comparing minutiae—primarily ridge endings and bifurcations—to search vast databases.^[34] AFIS achieves over 99% accuracy in ten-print-to-ten-print matching with human verification, though latent print searches yield 70-80% success rates due to variability in impression quality.^[34] In contemporary applications, dermatoglyphic patterns serve as core biometrics for personal identification in security and humanitarian contexts. Fingerprint scans are standard in passports and visas, with the U.S. Department of State collecting ten fingerprints from applicants to verify identity against watchlists and prevent fraud.^[74] At borders, systems like U.S. Customs and Border Protection's biometric tools match fingerprints in real-time against law enforcement databases to facilitate secure entry and exit.^[75] For disaster victim identification (DVI), partial fingerprints recovered from remains are compared via AFIS to antemortem records, as coordinated by INTERPOL, enabling rapid identification in mass casualty events where visual recognition is impossible.^[76] Despite these advances, challenges persist in forensic dermatoglyphic analysis, particularly with partial or smudged latent prints that distort minutiae and reduce matching reliability.^[77] Such impressions, often comprising only 20% of a full print and affected by surface conditions or contaminants, can lead to subjective examiner judgments and error rates up to 7.5% in false negatives.^[78] To address cross-border inconsistencies, INTERPOL establishes standards for fingerprint exchange using the ANSI/NIST-ITL format (version 6.0 or later), enabling secure, standardized transmission of digitized prints in XML or binary for international investigations.^[79] Extensions of dermatoglyphic principles beyond humans appear in wildlife forensics, where unique paw print patterns enable individual animal identification. In tiger conservation, pugmark analysis—examining footprint morphology and patterns in hind paw impressions—has historically been used for tracking and population estimation in anti-poaching efforts.^[80] Similarly, technologies like Footprint Identification Technique (FIT) use smartphone-captured paw prints from species such as elephants and rhinos to determine individual identity, sex, and age, aiding forensic reconstruction of poaching incidents.^[81]

Anthropological and Evolutionary Insights

Dermatoglyphics display notable ethnic variations that reflect genetic diversity and historical population dynamics. Whorl patterns, in particular, show a gradient across groups, with frequencies ranging from approximately 24% in White populations to 39% in Asian groups, while Native American ancestral samples exhibit even higher rates at 47.5%, surpassing the general population average of 35%. These differences arise from polygenic inheritance and have been employed in anthropological studies to infer migration patterns, such as the close dermatoglyphic affinities between Australian Aboriginals and Melanesian populations, supporting models of shared Australo-Melanesian ancestry through ancient dispersals into Sahul around 50,000 years ago.^[56]^[82]^[83] Evolutionary comparisons with nonhuman primates highlight the antiquity of dermatoglyphic features. The simian crease—a single transverse palmar crease formed by the fusion of proximal and distal folds—is a standard trait in anthropoid apes, representing a primitive condition that persists in some human lineages as a vestigial marker of shared ancestry. Fingerprint ridges themselves evolved in the common primate ancestor, likely over 60 million years ago, to enhance frictional grip by regulating moisture on volar surfaces, thereby aiding locomotion, foraging, and precision manipulation; this adaptation may have been particularly advantageous for early hominins engaging in tool use during the Pleistocene, around 2-3 million years ago.^[84]^[85] In population genetics, quantitative dermatoglyphic traits like total finger ridge count (TFRC) act as proxies for admixture events. Admixed groups, such as American Blacks with African-European ancestry, display intermediate ridge-count components compared to parental populations, with principal components analysis revealing values on key axes (e.g., component 6) that align with expected genetic contributions from European gene flow, accounting for up to 45% of intergroup distance in males.^[86] Paleodermatoglyphics extends these insights into prehistory through preserved impressions on artifacts and fossils. Ancient fingerprints on pottery, such as those from Late Roman oil lamps in Israel, reveal handedness preferences—e.g., left-hand molding and right-hand pressing—indicating specialized labor techniques and potential individual identification across multiple items. Fossil evidence includes Neanderthal fingerprints on birch resin from approximately 80,000 years before present in Germany and Upper Paleolithic modern human prints on clay figurines from Gravettian sites (27,000–24,000 years BP) in Central Europe, offering direct windows into prehistoric manual activities.^[87] Ongoing research investigates environmental influences on dermatoglyphics, including adaptations to climatic stressors. Populations at high altitudes, often correlating with cold environments, exhibit elevated fluctuating asymmetry in finger ridge counts, suggesting developmental responses to hypoxia and thermal stress that may enhance ridge density for improved insulation and grip stability.^[88]

References

[1]
Dermatoglyphics - an overview | ScienceDirect Topics
Dermatoglyphics is defined as the study of ridge patterns in the skin, particularly focusing on unique patterns found in fingerprints and plantar surfaces, ...
[2]
Embryogenesis and Applications of Fingerprints- a review
Oct 19, 2025 · Finger prints are imprints of epidermal ridges, which are formed in early embryonic life, during 10 th to 16 th week of intrauterine life and ...
[3]
Dermatoglyphics - CHRISMED Journal of Health and Research
Dermatoglyphics is a study of configurations of epidermal ridges on certain body parts, namely, palms, fingers, soles, and toes.
[4]
Dermatoglyphics -A Review - Biomedical and Pharmacology Journal
Jan 8, 2016 · Cummins in 1926 first introduced the term “dermatoglyphics” which refers to the study of the naturally occurring patterns of the surface of the ...
[5]
The genesis of dermatoglyphics - ScienceDirect.com
Dermatoglyphics, then, are not primarily genetically determined, but provide an indirect, indelible historical perspective of the form of the early fetal hand.
[6]
clinical ambitions and uncertainty in dermatoglyphics - PMC - NIH
May 14, 2018 · This article examines the history of one application of dermatoglyphic knowledge: the development of techniques to diagnose Down syndrome.Missing: review | Show results with:review
[7]
[PDF] Dermatoglyphics: in health and disease - a review
Dec 2, 2013 · Dermatoglyphics is the study of skin ridge patterns on fingers, toes, palms, and soles, formed in early embryonic life.
[8]
[PDF] bose-dermatoglyphics-historical-perspectives.pdf
The paper here discussed the historical approach in the growth of dermatoglyphics and its wide application in modern science. Thus, the wide application of ...
[9]
The Dermal Ridges as the Infallible Signature of Skin: An Overview
Dermal ridges are skin lines formed before birth, unique and permanent, and are studied in dermatoglyphics, which is the study of these ridges.
[10]
[PDF] Embryology and Morphology of Friction Ridge Skin
Friction ridges begin to form around 10.5 weeks EGA, and their uniqueness is traced back to late embryological and early fetal development periods.
[11]
The permanence of friction ridge skin and persistence of friction ...
This study addresses the permanence and persistence of friction ridges and the persistence of impressions made from these friction ridges over months and years.
[12]
Finger pad friction and its role in grip and touch - PubMed Central
Many aspects of both grip function and tactile perception depend on complex frictional interactions occurring in the contact zone of the finger pad.
[13]
Can Cheiromancy Predict Mean Survival or Fatality of a Patient with ...
May 2, 2020 · However, one should not confuse between the palmistry and dermatoglyphic as the latter is considered as more scientific method of analyzing and ...Missing: distinction | Show results with:distinction<|control11|><|separator|>
[14]
The developmental basis of fingerprint pattern formation and variation
Mar 2, 2023 · Primary ridge formation is completed by week 17, and smaller secondary ridges then begin to appear between them. The skin surface becomes ...
[15]
Dermatoglyphics – A Concise Review on Basic Embryogenesis,...
This review paper is a systematic compilation on basic embryogenesis, classification of fingerprints and several canonical mechanisms involved in fingerprint ...
[16]
https://www.cell.com/cell/fulltext/S0092-8674(21)01446-X
[17]
Genetic variant influence on whorls in fingerprint patterns - PMC
A very high heritability (h2 = .65-.96) has been reported for up to 12 dermatoglyphic characteristics (Machado et al., 2010), suggesting a genetic basis for ...
[18]
[PDF] Systems of Friction Ridge Classification - Office of Justice Programs
In his book, Galton formulated a classification system that was based on the alphabetical enumerations of the three fingerprint patterns: L represented a loop, ...<|separator|>
[19]
Fundamentals of Dermatoglyphics - JAMA Network
Dermatoglyphics are furrows in the skin of the digital pads, palms, and soles which can be cleanly and permanently recorded on specially.
[20]
ANTHROPOLOGICAL DERMATOGL YPHIC ... - Annual Reviews
During the past two decades the use of dermatoglyphics in anthropology has increased. Both the kinds of questions asked and the methodological.
[21]
Sexual dimorphism in digital dermatoglyphic traits among Sinhalese ...
They are typified by having a high frequency of loops compared to whorls and arches. Ulnar loop is the most commonly observed pattern followed by PW, DLW ...
[22]
Dermatoglyphics from All Chinese Ethnic Groups Reveal ...
This paper reports the results of a comprehensive analysis of dermatoglyphics from all ethnic groups in China.Missing: Asians | Show results with:Asians<|control11|><|separator|>
[23]
Investigation and analysis of hand characteristics of Chinese Han ...
Jun 27, 2025 · These patterns included arch (A), ulnar loop (Lu), radial loop (Lr), whorl (W), and double loop whorl (Wd).
[24]
[PDF] Ancient Finger Prints in Clay - Scholarly Commons
Ancient finger prints in clay are impressions of fingers pressed into clay, forming a mold that can be preserved for centuries.Missing: oushitsu | Show results with:oushitsu
[25]
[PDF] THE FINGERPRINT SOURCEBOOK - Office of Justice Programs
While Herschel and Faulds were studying friction ridge skin, another scientist was devising an alternate identification method. Alphonse Bertillon (Figure 1 ...Missing: Purkyně | Show results with:Purkyně
[26]
https://www.cidjournal.com/article/S0738-081X(14)00153-9/fulltext
[27]
[PDF] A Simplified Guide To Fingerprint Analysis
Fingerprint analysis has been used to identify suspects and solve crimes for more than 100 years, and it remains an extremely valuable tool for law enforcement.
[28]
Correlation between dermatoglyphics and dental caries in children
Jun 30, 2020 · Ink method: This is the most commonly used technique which uses an inking slab, paper, ink, and roller. Farrot inkless method: In this ...
[29]
The Science of Fingerprints - Crime Scene Investigator Network
The delta is the point from which to start in ridge counting. In the loop type pattern the ridges intervening between the delta and the core are counted.
[30]
The Qualitative Dermatoglyphics PATTERNS in Both Hands for ...
Fingerprint ridge pattern can be separated into three major types, arches, loops, and whorls. Arches have no triradii, loops have one triradii, and whorls have ...Missing: assessment | Show results with:assessment
[31]
Improved analysis of palm creases - PMC - NIH
Palm creases are helpful in revealing anthropologic characteristics and diagnosing chromosomal aberrations, and have been analyzed qualitatively and ...
[32]
[PDF] Understanding Changing Trends to Study Human Behavior through ...
Oct 15, 2017 · The 8 types classified by Sir Francis Galton were plain arch, tented arch, simple loop (ulnar loop), central pocket loop, double loop, lateral ...
[33]
[PDF] Association Between Fingerprint Patterns and ABO (±Rh) Blood ...
Inter-Observer Reliability. Two independent observers analyzed all fingerprint samples. Inter-observer agreement was excellent, with Cohen's kappa (κ) = 0.86 ...Missing: variability | Show results with:variability
[34]
[PDF] Automated Fingerprint Identification System (AFIS)
AFIS, or Automated Fingerprint Identification System, was developed to use computers to assist in classifying, searching, and matching fingerprint cards.Missing: qualitative | Show results with:qualitative
[35]
[PDF] Descriptive Statistics of Fingerprints from the Files of NTSIIS
Feb 2, 2021 · For Caucasian male non-criminals, the mean ridge count is 13.94, for the Negro group it is 13.57; for females the respective means are 12.88 and ...
[36]
Total Finger Ridge Count - an overview | ScienceDirect Topics
Total finger ridge count (TFRC) is defined as the number of ridge counts between the core of a finger pattern and its corresponding triradius, where arch ...
[37]
Distribution and Sex Variation of the a-b Ridge Count
It is the best known and the most satisfactory ridge count on the palm, partly because the a and b triradii are clearly defined, and part ly because there is ...
[38]
Dermatoglyphic a-b ridge count as a possible marker for ... - PubMed
TFRC (Total Finger Ridge Count) and TABRC (Total a-b Ridge Count) were studied in a sample of 38 schizophrenic patients and 69 healthy individuals. A ...
[39]
[PDF] UNIT 3 DERMATOGLYPHICS* - eGyanKosh
Dermatoglyphics is the study of the epidermal ridge patterns of the skin of the fingers, palms, toes and soles. Dermatoglyphics is derived from two Greek words.
[40]
The Presentation of Dermatoglyphic Abnormalities in Schizophrenia
Aug 13, 2012 · Similarly, TFRC fluctuating asymmetry (or fluctuating asymmetry of total finger ridge count; FAFRC) is determined by subtracting right TFRC ...
[41]
(PDF) Dermatoglyphic fluctuating asymmetry in twins and singletons
The influence of twinning on developmental stability was measured by comparing fluctuating asymmetry in dermatologlyphic traits in monozygotic twins, ...
[42]
Study of the Fingertip Pattern as a Tool for the Identification of ... - NIH
A Total Finger Ridge Count (TFRC) represents the sum of the ridge counts of all the 10 fingers. To some extent, the ridge count may reflect the pattern type [9] ...Missing: Lionel | Show results with:Lionel
[43]
Dermatoglyphics: in health and disease - a review
In this review, we will be discussing Dermatoglyphics and its important role in the diagnosis of chromosomal disorders and other diseases which have some ...Missing: cytogenetics | Show results with:cytogenetics
[44]
Dermatoglyphics in Down's syndrome - PubMed
Dermatoglyphic data were obtained from 235 cytogenetically confirmed patients of Down's syndrome. The data were correlated and compared with 230 controls.
[45]
Dermatoglyphic Variations Among Clinically Diagnosed Down's ...
Nov 9, 2015 · The fingerprint patterns, simian crease, and total ridge count of 21 mentally retarded, Down syndrome (DS) patients were compared with a control group of 21 ...
[46]
Dermatoglyphics in Down's syndrome - ResearchGate
Aug 25, 2025 · ... reduced total ridge count (12.61 ± 2.21). Conclusion and application of findings: The results demonstrate that dermatoglyphic patterns and ...
[47]
Analysis of the dermatoglyphics in Turkish patients with Klinefelter's ...
Sep 15, 2008 · This investigation was aimed to analyze dermatoglyphic patterns in Klinefelter's syndrome (KS) patients. The study cohort consisted of 57 cases ...
[48]
Dermatoglyphics of Klinefelter's Syndrome - SpringerLink
The karyotype most commonly associated with this condition is 47,XXY. For this reason, the dermatoglyphic characteristics of 47,XXY males have been more ...
[49]
Dermatoglyphics and Syndromes | JAMA Pediatrics
The relative frequencies of various dermatoglyphic features have been reviewed for nine chromosomal disorders, three single-gene defects, three syndromes of ...
[50]
Dermatoglyphics and Karyotype Analysis in Primary Amenorrhoea
Dec 5, 2014 · Dermatoglyphics is in use as a supportive diagnostic tool in genetic or chromosomal disorders as well as in clinical conditions with genetic ...
[51]
Genetic Parameters of Dermal Patterns of Ridge Counts - PubMed
These estimates varied from 0.23 for radial loops to 0.80 for total ridge count. The heritability estimates were lower for ridge counts of single hands or ...
[52]
Three Patterns of Inheritance of Quantitative Dermatoglyphic Traits
Jan 25, 2022 · This is confirmed with univariate genetic analyses. Ridge counts on five fingers have high heritability estimates (from 49% to 81%), an ...
[53]
Digital dermatoglyphic heritability differences as evidenced by a ...
Results confirmed the predominant genetic influence on the total ridge count. The heritability indexes varied in up to 8 times between different fingers and its ...
[54]
The influence of sex chromosomes on finger dermatoglyphic patterns
The X and Y chromosomes had about equal influence on radial-ulnar difference, but the Y had a stronger effect on radial loop asymmetry. It is postulated that ...
[55]
Evidence for polygenic epistatic interactions in man? - PubMed
Studies of multifactorial inheritance in man have ignored nonadditive gene action or attributed it entirely to dominance. Reanalyses of dermatoglyphic data ...
[56]
[PDF] Ethnic Variations in Fingerprint Patterns: A Texas A&M University ...
The radial loop pattern was the most frequent subtype in all the groups in the following order: Hispanics 55.66%, Blacks 50.32%,. Whites 63.02%, and Asians ...
[57]
Digital dermatoglyphic variation and migratory pattern of ethnic ...
It is also a valuable means of tracking the migratory pattern of these genetically related groups within a large demographic expression.
[58]
Limb development genes underlie variation in human fingerprint ...
Jan 6, 2022 · There are three main types: arch, loop, and whorl. Each main group contains two sub-types according to the steepness, direction of ridges and ...Missing: dimorphism | Show results with:dimorphism
[59]
Dermatoglyphics of Congenital Abnormalities without Chromosomal ...
This review outlines the dermatoglyphics of congenital abnormalities without chromosomal aberrations. When combined with other clinical features of a ...Missing: indicators malformations
[60]
Dermatoglyphics in Congenital Heart Disease
DERMATOGLYPHICS IN CONGENITAL HEART DISEASE hypothenar patterns. Hypothenar patterns are associated with distal axial triradii and wider atd angles ...
[61]
[PDF] Dermatoglyphics pattern in children with congenital malformations
Mar 17, 2018 · The mean a-b ridge count among children with CHD was higher 34.16±8.39 for males and 38.06±8.17 for females as compared to that of normal ranges ...
[62]
Dermatoglyphic evaluation in subjects and parents of cleft lip with ...
Results : Increased frequency of loops and arches and low mean total ridge count was observed in cleft subjects. Increased frequency of loops and arches ...Missing: excess | Show results with:excess
[63]
Dermatoglyphics in Health and Oral Diseases-A Review
Jul 11, 2014 · Thus the study of dermatoglyphics is considered as a window of congenital abnormalities and is a sensitive indicator of intrauterine anomalies ...Missing: malformations | Show results with:malformations
[64]
Unusual dermatoglyphic findings associated with rubella embryopathy
Unusual dermatoglyphic findings associated with rubella embryopathy. N Engl J Med. 1966 Jan 20;274(3):148-50. doi: 10.1056/NEJM196601202740307.
[65]
An investigation of dermatoglyphic asymmetry in rubella embryopathy
May 6, 2005 · The trends in all cases indicated that, contrary to the hypothesis, all measures of asymmetry were decreased in the rubella infants. Asymmetry ...
[66]
12 Dermatoglyphics and Trichoglyphics - Oxford Academic
A hair whorl over the lower spine can be a sign of a defect of neural tube closure, a congenital tumor, or a neurofibroma. In the coccygeal area there may ...
[67]
Dermatoglyphics and abnormal palmar flexion creases as markers ...
The aim of the present study was to analyse dermatoglyphic traits and abnormal palmar flexion creases as markers of environmental prenatal stress in children ...
[68]
Dermatoglyphics in patients with schizophrenia - PMC - NIH
This study examined four dermatoglyphic traits of left and right index fingerprints of 290 patients with schizophrenia (case group) and 290 normal subjects ( ...
[69]
Dermatoglyphics in hypertension: a review - PMC - NIH
Aug 12, 2015 · The aim of this review was to search for and appraise available studies that pertain to the association between hypertension and dermatoglyphics.
[70]
Evaluation of Dermatoglyphic Features of Type 2 Diabetic Patients ...
Apr 24, 2022 · The study was aimed to compare the finger and palmar dermatoglyphics features in type 2 diabetic and non-diabetic patients and to evaluate the association with ...
[71]
Predictive Analysis of Palmar Dermatoglyphics in Patients with ...
Conclusion: These results indicate that the quantitative palmar parameter, ATD-angle, can play a role in identifying women with increased risk of breast cancer.
[72]
[PDF] predictive values of quantitative analysis of finger and palmar ...
Jun 11, 2018 · A pattern of less than six finger loops was found more frequently in breast cancer patients than in the control group. The ATD angle and the b-c ...<|control11|><|separator|>
[73]
History of Fingerprints - Onin.com
The English began using fingerprints in July 1858 when Sir William James Herschel, Chief Magistrate of the Hooghly District in Jungipoor, India, first used ...Missing: dermatoglyphics Purkyně
[74]
History of Fingerprinting - CPI OpenFox
Jul 17, 2023 · By 1903, America had begun using fingerprints. Some of the first police departments to adopt this investigative tool was the New York Police ...
[75]
[PDF] scientific research supporting the foundations of friction ridge ...
When some people think of research, what comes to mind are images of individuals in white lab coats, looking up intermittently to take data measurements and ...<|control11|><|separator|>
[76]
[PDF] On the individuality of fingerprints - Biometrics Research Group
For example, the probability that a fingerprint with 36 minutiae points will share 12 minutiae points with another arbitrarily chosen fingerprint with 36 ...
[77]
Safety & Security of U.S. Borders: Biometrics - Travel.gov
The US standard for biometric screening is ten fingerprint scans collected at all US Embassies and Consulates for visa applicants seeking to come to the United ...
[78]
CBP Biometric Testing | U.S. Customs and Border Protection
Jan 21, 2025 · A handheld, mobile device that allows officers on the jetway to run travelers' fingerprints through law enforcement databases as travelers are exiting the US.
[79]
Disaster Victim Identification (DVI) - Interpol
It is rarely possible to identify a victim of a major disaster by visual recognition; fingerprints, dental records or DNA samples are often required for a ...
[80]
Fingerprints Are Not a Gold Standard
Especially when an examiner evaluates a partial latent print—a print that may be smudged, distorted, and incomplete—it is impossible on the basis of our current ...Missing: INTERPOL | Show results with:INTERPOL
[81]
Accuracy and reliability of forensic latent fingerprint decisions - PMC
Eighty-five percent of examiners made at least one false negative error for an overall false negative rate of 7.5%. Independent examination of the same ...
[82]
[PDF] Guidelines concerning Fingerprint Transmission 2024 - Interpol
Fingerprints are transmitted in NIST format, using either binary (v5.3) or XML (v6.0). Both are acceptable. A tool is available to convert JPEG to NIST.
[83]
Pug Marks - Scientist who draws
Jan 15, 2024 · Pug mark analysis can be used to identify and track specific individuals, which is valuable for conservation efforts and wildlife management.
[84]
Footprint Identification Technology - WildTrack
Using a smartphone app we can collect images of animal footprints to determine their species, which individual they are, which sex, and sometimes their age- ...Missing: forensics | Show results with:forensics
[85]
[PDF] IS IT ALL IN THE - ShareOK
Having the knowledge that this study has shown the highest frequency in whorls within the Native American ancestral group could help investigators narrow down ...
[86]
Dermatoglyphics in Australian aborigines (Arnhem Land) - PubMed
Dermatoglyphics in Australian aborigines (Arnhem Land). Am J Phys Anthropol. 1951 Dec;9(4):455-60. doi: 10.1002/ajpa.1330090406.Missing: Melanesians migrations
[87]
Simian crease in man: some methodological considerations
The Simian crease, invariably present among anthropoid apes and frequent among mongoloid idiots, is also present in varying degrees among normal populations.
[88]
Fingerprint ridges allow primates to regulate grip - PMC
Why have primates evolved epidermal ridges on the volar regions of the hands and feet and with a much greater density of sweat glands than flat skin, ...
[89]
[PDF] Components of racial variation in finger ridge-counts - Sci-Hub
ABSTRACT. Principal components analysis was used to evaluate finger ridge-count variability as an indicator of genetic relationships between popu- lations.
[90]
Studying Fingerprints in Archaeology: Potentials and Limitations of ...
Feb 24, 2023 · This article introduces paleodermatoglyphics and discusses its potentials and limitations as an archaeometric method.
[91]
The asymmetry of dermatoglyphic finger ridge counts and the ...
Significant differences in fluctuating asymmetry of ridge counts between fingers were found in relationship with geographical altitude as a stressful condition ...