The proposed system consists of four subsystems, each of which has a precise goal that complements the goals of the other subsystems, resulting in a complete postural analysis of the subject under examination. Each of the subsystems will now be described in detail.
MEDICAL HISTORY DATA
To frame, in a suitable way, the values and results that are obtained from the postural analysis, it is fundamental that current data and medical histories be collected for each subject. The list of items considered essential is shown in Fig. 1.
It is important to highlight that postural analysis is not exclusively performed by physicians as well as is used to aid physicians in decision-making processes; thus, the collection of medical history data should not be considered as an attempt to search for a condition or its diagnosis or to develop a rehabilitation plan. Indeed, the purpose is to acknowledge existing behaviours and conditions that could influence the posture of the subject.
None of the items listed in Fig. 1 need explanations since they are inherently clear and easy to understand. However, relating to "scar description", it is believed that some clarification may be useful.
Since "each scar is a possible disturbance", as reported by Caiazzo in 2007 [6], it is always very useful to consider not only the exterior aspect but also the viable activity using the vascular autonomic signal (VAS) test, also known as Rèflexe Arteriel de Nogier (RAN). Further, it should be understood that the same test can also be used to investigate parts of the same scar to understand whether the produced activity is linked to specific segments thereof.
PHOTOGRAPHIC REFERENCES [7–13]
Experience and observation, free of prejudice and judgment, are essential and fundamental tools in postural analysis and specific contributions of the operator. In this light, a set of photographic references enables precise postprocessing without the need for the patient to be present and concretizing of personal observations using simple graphic tools (the author generally uses GIMP).
The proposed photographic set consists of three parts, each of which has a particular purpose.
The first part concerns the whole structure of a person and consists of five pictures in an orthostatic position, from antero-posterior, postero-anterior, left lateral, right lateral and top view, after positioning the markers on the subject. Markers positioning requires the subject once supine and after being prone, to arrange markers on the front and lateral sides and subsequently on the back side. The position and the number of markers are reported in Fig. 2, differentiated according to sex. The letters indicate the distances between two markers. These distances are used to verify the conversion from pixels to millimetres, achieved using markers with known lengths that are positioned to the front, back and sides (on both the right and left sides) on a surface as flat and orthogonal to the floor as possible (e.g., the thigh).
The anterior superior iliac spine (ASIS) and posterior superior iliac spine (PSIS) are manually highlighted, i.e., without the use of markers, for better precision using a simple cosmetic make-up pencil. The equipment, built to obtain the described photographic references, is visible in Fig. 3, while in Fig. 4 and Fig. 5, the obtained results are displayed. As highlighted in Fig. 4, in the antero-posterior view, only the horizontal laser is used, centred on the interASIS line to create a fixed reference for future analyses; vertical laser off is a further safety for patient. In the other views, the lasers, horizontal and vertical, are both activated: the first one is still centred on the interASIS line in the antero-posterior view, while the second one is centred according to Barre's vertical in both the postero-anterior and latero-lateral views.
Three pictures are added to what is described above; they are used in postprocessing to objectify rotations of the pelvic girdle in the coronal and sagittal planes.
To obtain a picture enabling quantification of rotation in the coronal plane, it is necessary to centre one horizontal laser on the right ASIS and one horizontal laser on the left ASIS and to take a picture of both traces with the patient in orthostasis in the antero-posterior view. The measurement of rotation is then indicated by the gap, on the order of millimetres, between the two traces.
To obtain a picture enabling quantification of rotation in the sagittal plane, it is necessary to centre one horizontal laser on the right ASIS (in the antero-posterior view) and one horizontal laser on the right PSIS (in the postero-anterior view) and to take a picture of both traces with the patient in orthostasis in the right lateral view. In this picture, the laser trace centred on ASIS crosses the anterior body profile at a specific point (A). Analogously, the laser trace centred on PSIS crosses the posterior body profile at a specific point (P). The measurement of rotation is the angle between the horizontal line and the line joining A and P. The procedure is repeated in the same manner on the left side.
The second part concerns the stomatognathic apparatus and the acquisition of five pictures that describe the reciprocal layout of the dental arches in the antero-posterior, latero-lateral, left oblique, and right oblique views and at the largest buccal opening with the tongue on the palatal spot; this enables detection of the position of the upper canine and first upper molar teeth respect to the lower arch, as well as of the ability of the tongue to reach the palatal spot. Figure 6 shows them schematically and directly. Additionally, a video in the latero-lateral view is included in this group of pictures and highlights atypical movements observed during swallowing. In the case of atypical swallowing movements, it is more useful to perform at least three-four consecutive swallowing actions, possibly interrupted by a rest break.
Finally, the third part concerns the feet during standing and includes pictures of the feet during single- and double-leg standing in the postero-anterior view; the pictures may be supplemented by or replaced with a video that captures all of these aspects. The addition of a picture of the feet during double-leg standing in the cranial-caudal view is useful for highlighting deformities in the 1st radius (e.g., hallux valgus). In summary, with the system reported in Fig. 7, pictures can be acquired of the feet during standing with eyes both open and closed and with the dental arches separated and in contact.
OVERALL OBSERVATION [6]
Figure 8 shows the list of the item used in the analysis to describe how the person holds himself in the space in a general manner.
The organization of the analysis follows a directional logic in a cranial-caudal sense, starting from the temporomandibular joint (TMJ) and ending with the feet during standing as documented by the photographic references.
The overall observation is not meant to be an exhaustive evaluation but rather to be an examination of a wide spectrum of possible receptor influences on posture within a limited amount of time to avoid disturbing the postural system of the patient examined. In other words, an attempt was made to acknowledge the possibility that each receptor system that influences posture could be a source of postural disturbance without interference of the measuring system on the observed system. Thus, if some findings are suggestive of disharmonies, it is possible beneficial to consider having a specialist in the field (ophthalmologist, odontostomatologist, otolaryngologist, orthopaedic, physiatrist or podiatrist) conduct a more detailed evaluation based on what was objectively found, as measuring system disturbances have been avoided.
TEST [6, 14–15]
Figure 9 shows the list of selected tests.
The first five tests must be performed initially, and their main purpose is to identify the presence of a possible disharmonic syndrome, as described by Caiazzo in 2007 [7].
It should be observed that, as is common in posturology, it is not the result of a single test that indicates the presence of disharmony, but congruent results from multiple tests to indicate its probable presence.
All tests are widely described in the literature and do not need further explanation. However, for the “visceral” test, additional details can be useful. This test examines the possible influences of the visceral apparatus on postural disturbance, and after it is performed, the previously described items must be re-evaluated, especially if abnormal results have been found.
The two final tests aim to analyse the mobility of the vertebral column, in particular the possibility of shifts in the coronal plane, and the layers of torso-lumbar region musculature.