Rehabilitation in dysfunctions of temporomandibular joints

The treatment of the temporomandibular joints dysfunctions shall be complex due to several possible causes that trigger the disorders. Rehabilitation is based on adopting the techniques that originate from manual therapy, applying physiotherapy, classical and transverse massage, as well as autotherapy. Moreover, in the course of the therapy, Kinesio taping, post-isometric relaxation, positional release, release and rolling of the skin are also applied. Cooperating with an orthodontist, a stomatologist, a physiotherapist and a psychologist, as well as the commitment to the treatment on the part of the patient shall allow the cure to take effect in the joint itself and the muscles surrounding it

Kinesiotherapy as a method supporting the rehabilitation of lumbosacral spine pain in pregnant women

During pregnancy, a number of changes take place in the woman's body. They often cause pain in the spine, especially the lumbosacral segment. Dynamic slicing supports the rehabilitation of women during pregnancy, thanks to the fact that it has an analgesic effect, improves the flow of limes and increases the elasticity of tissues. Kinesiotherapy included in the rehabilitation is an effective method of pain relief in this area in pregnant women

Quantitative anatomy of the growing supraspinatus muscle in the human fetus

The supraspinatus muscle, one of the four rotator cuff muscles, initiates abduction of the arm, simultaneously stretching the articular capsule at the glenohumeral joint, and also contributes to exorotation of the arm. In the present study we aimed to evaluate the age-specific normative values for morphometric parameters of the supraspinatus muscle in human fetuses at varying ages and to elaborate their growth models. Using anatomical dissection, digital  image analysis (NIS Elements AR 3.0) and statistics (Student’s t-test, regression analysis), the length, width, circumference and projection surface area of the supraspinatus muscle were measured in 34 human fetuses of both sexes (16♂, 18♀) aged 18–30 weeks of gestation. Neither sex nor laterality differences were found in numerical data of the supraspinatus muscle. In the supraspinatus muscle its length and projection surface area increased logarithmically, while its width and circumference grew proportionately to gestational age. The following growth models of the supraspinatus muscle were established: y = –71.382 + 30.972 × ln(Age) ± 0.565 for length, y = –2.988 + 0.386 × Age ± 0.168 for greatest width (perpendicular to superior angle of scapula), y = –1.899 + 0.240 × Age ± 0.078 for width perpendicular to the scapular notch, y = –19.7016 + 3.381 × Age ± 2.036 for circumference, and y = –721.769 + 266.141 × ln(Age) ± 6.170 for projection surface area. The supraspinatus muscle reveals neither sex nor laterality differences in its size. The supraspinatus muscle grows logarithmically with reference to its length and projection surface area, and proportionately with respect to its width and circumference

Sensory Integration as One of the Methods in Physical Therapy for Pre-School Age Children

Sensory Integration (SI) is one of the therapeutic methods created and described by J. Ayres in 1972. In Poland, for a few years, more and more specialists, also rehabilitators, have followed this concept in their work.  SI is a subconscious process, whereby the ordering and assignment of meaning to information acquired by the senses takes place. The three principal senses, which Ayres described are: the sense of touch, proprioception, and the vestibular system.</p

Volumetric Growth of the Liver in the Human Fetus: An Anatomical, Hydrostatic, and Statistical Study

Using anatomical, hydrostatic, and statistical methods, liver volumes were assessed in 69 human fetuses of both sexes aged 18-30 weeks. No sex differences were found. The median of liver volume achieved by hydrostatic measurements increased from 6.57 cm 3 at 18-21 weeks through 14.36 cm 3 at 22-25 weeks to 20.77 cm 3 at 26-30 weeks, according to the following regression: y = −26.95 + 1.74 × age ± Z × (−3.15 + 0.27 × age). The median of liver volume calculated indirectly according to the formula liver volume = 0.55 × liver length × liver transverse diameter × liver sagittal diameter increased from 12.41 cm 3 at 18-21 weeks through 28.21 cm 3 at 22-25 weeks to 49.69 cm 3 at 26-30 weeks. There was a strong relationship ( = 0.91, &lt; 0.001) between the liver volumes achieved by hydrostatic (x) and indirect (y) methods, expressed by y = −0.05 + 2.16 ± 7.26. The liver volume should be calculated as follows liver volume = 0.26 × liver length × liver transverse diameter × liver sagittal diameter. The age-specific liver volumes are of great relevance in the evaluation of the normal hepatic growth and the early diagnosis of fetal micro-and macrosomias

Volumetric Growth of the Liver in the Human Fetus: An Anatomical, Hydrostatic, and Statistical Study

Using anatomical, hydrostatic, and statistical methods, liver volumes were assessed in 69 human fetuses of both sexes aged 18–30 weeks. No sex differences were found. The median of liver volume achieved by hydrostatic measurements increased from 6.57 cm3 at 18–21 weeks through 14.36 cm3 at 22–25 weeks to 20.77 cm3 at 26–30 weeks, according to the following regression: y = −26.95 + 1.74 × age ± Z  × (−3.15 + 0.27 × age). The median of liver volume calculated indirectly according to the formula liver volume = 0.55 × liver length × liver transverse diameter × liver sagittal diameter increased from 12.41 cm3 at 18–21 weeks through 28.21 cm3 at 22–25 weeks to 49.69 cm3 at 26–30 weeks. There was a strong relationship (r=0.91, p<0.001) between the liver volumes achieved by hydrostatic (x) and indirect (y) methods, expressed by y = −0.05 + 2.16x  ± 7.26. The liver volume should be calculated as follows liver volume = 0.26 × liver length × liver transverse diameter × liver sagittal diameter. The age-specific liver volumes are of great relevance in the evaluation of the normal hepatic growth and the early diagnosis of fetal micro- and macrosomias

Morphometric study of the diaphragmatic surface of the liver in the human fetus.

This study aimed to examine age-specific reference intervals and growth dynamics of the best fit for liver dimensions on the diaphragmatic surface of the fetal liver. The research material consisted of 69 human fetuses of both sexes (32♂, 37♀) aged 18-30 weeks. Using methods of anatomical dissection, digital image analysis and statistics, a total of 10 measurements and 2 calculations were performed. No statistical significant differences between sexes were found (p>0.05). The parameters studied displayed growth models that followed natural logarithmic functions. The mean value of the transverse-to-vertical diameter ratio of the liver throughout the analyzed period was 0.71±0.11. The isthmic ratio decreased significantly from 0.81±0.12 in the 18-19th week to 0.62±0.06 in the 26-27th week, and then increased to 0.68±0.11 in the 28-30th week of fetal life (p<0.01). The morphometric parameters of the diaphragmatic surface of the liver present age-specific reference data. No sex differences are found. The transverse-to-vertical diameter ratio supports a proportionate growth of the fetal liver. Quantitative anatomy of the growing liver may be of relevance in both the ultrasound monitoring of the fetal development and the early detection of liver anomalies

Volumetric Growth of the Liver in the Human Fetus: An Anatomical, Hydrostatic, and Statistical Study

Using anatomical, hydrostatic, and statistical methods, liver volumes were assessed in 69 human fetuses of both sexes aged 18–30 weeks. No sex differences were found. The median of liver volume achieved by hydrostatic measurements increased from 6.57 cm3 at 18–21 weeks through 14.36 cm3 at 22–25 weeks to 20.77 cm3 at 26–30 weeks, according to the following regression: y = −26.95 + 1.74 × age ± Z  × (−3.15 + 0.27 × age). The median of liver volume calculated indirectly according to the formula liver volume = 0.55 × liver length × liver transverse diameter × liver sagittal diameter increased from 12.41 cm3 at 18–21 weeks through 28.21 cm3 at 22–25 weeks to 49.69 cm3 at 26–30 weeks. There was a strong relationship (r=0.91, p<0.001) between the liver volumes achieved by hydrostatic (x) and indirect (y) methods, expressed by y = −0.05 + 2.16x  ± 7.26. The liver volume should be calculated as follows liver volume = 0.26 × liver length × liver transverse diameter × liver sagittal diameter. The age-specific liver volumes are of great relevance in the evaluation of the normal hepatic growth and the early diagnosis of fetal micro- and macrosomias