Quantifying Whole Human Hair Scalp Fibres of Varying Curl: A Micro-computed Tomographic Study

Overview

Journal J Microsc

Specialty Radiology

Date 2024 Nov 20

PMID 39564786

Authors

Claire van den Berg

Nonhlanhla P Khumalo

Malebogo N Ngoepe

Affiliations

Soon will be listed here.

Abstract

Scalp hair is a key feature of humans and its variability has been the subject of a broad range of studies. A small subset of these studies has focused on geometric quantification of human scalp hair fibres, however the use of race- and ethnicity-based classification systems makes it challenging to draw objective conclusions about fibre variability. Furthermore, sample preparation techniques for micro-imaging studies often alter the original form of hair fibres. This study sought to determine which of the commonly reported descriptors could be resolved using micro-computed tomography (micro-CT) for fibres of varying curl. Images obtained from micro-CT were used to reconstruct three-dimensional images that were then analysed. The study also explored the capabilities and limitations of micro-CT as an imaging modality by comparing and cross-validating findings with those obtained from scanning electron microscopy (SEM) and laser micrometry. The former deals with surface imaging while the latter deals with cross-sectional measurements. Micro-CT was found to be highly effective at resolving cross-sectional ellipsoidal parameters, but performed more poorly than SEM in reconstructing surface level details at a 2 resolution. The technique was, however, able to reveal the presence of the medulla in type VI (high curl) hair fibres. When compared with high curl fibres, greater intra-fibre variability was observed for the low and medium curl fibres, highlighting the importance more objective classification systems.

Citing Articles

Quantifying whole human hair scalp fibres of varying curl: A micro-computed tomographic study.

Berg C, Khumalo N, Ngoepe M J Microsc. 2024; 297(2):227-251.

PMID: 39564786 PMC: 11733847. DOI: 10.1111/jmi.13365.

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