Associated with the large general developments of the technology, studies using state-of-the-art instruments and techniques, also during execution of daily living motor tasks, are growing rapidly by examining PFP patients through kinematic and kinetic analyses, imaging technologies, electromyography (EMG), isokinetics, etc. Unfortunately, results gathered from imaging and assessment measures can hardly be merged or compared, because of different factors, such as the reliability of instruments, real-life adaptability of the measure (i.e., somehow predictability of real-life conditions), and the large spectrum of variables
[6][7]. Due to these conflicts, manufacturers focused on developing new technologies to solve the inconsistency in the results and also tried to consider the issues such as cost-effectiveness, fewer side-effects, and practical use. Despite the heterogeneity of the technologies used, a number of studies have recently examined possible innovative technologies, also evaluating their cost-effectiveness, and pros and cons
[8][9][10]. These studies have highlighted the relevance of technological innovations in musculoskeletal rehabilitation and their potential to improve the sustainability of healthcare systems for the assessment and management of general patients.
Although measures from medical imaging in static conditions definitely provide valuable information, functional assessments during motor tasks can also provide observations from daily living and in real-time, thus giving access to the dynamic interactions of hard and soft tissues
[5][7]. This has been reported in a number of studies using gait analysis and biomechanical modeling
[11][12]. Now, medical imaging in dynamic and weight-bearing conditions also in 3D are accessible
[13][14][15] for these assessments. However, technical experience must become more mature, and costs, radiation, access to these instruments, data post-processing, etc., are known concerns that limit current relevant exploitations
[7]. Bi-dimensional analyses are still frequently used, such as those for the frontal plane projection angle
[16] and the Q-angle, but modern instrumented gait analysis provides thorough 3D dynamic measurements of joint kinematics and kinetics
[17][18], in real-time and also synchronized with surface EMG.
2. Biomechanical Analyses
There has been an increasing number of biomechanical studies in recent decades. This may be accounted for by the development of kinematic and kinetic analyses, the first game-changing technologies that later became the gold standard.
Biomechanical studies based on state-of-the-art gait analysis are substantial to interpret motion patterns at the knee joints. A number of studies show that excessive load at the patellofemoral joint leads to increased patellofemoral contact force, which can result in altered tibial and femoral kinematics, both in the frontal and transverse planes
[19][20]. Indeed, there is still a debate on these mechanisms, for which biomechanics can provide relevant evidence. To set standardized approaches to the kinematics and kinetics of the major joints of the lower limbs, a number of protocols have been developed and compared
[17][18]. Known limitations include adequate data collection, skin motion artifacts, anatomical landmark identification, and tracking
[17]. Appropriate marker positioning is essential to determine the joint kinematics and kinetics, and thus to work out relevant patterns within the gait cycle. The large majority of gait analysis protocols calculate motion of the tibiofemoral joint in the frontal and sagittal planes, and only a few on the transverse plane. Since skin markers should track motion of the underlying bones
[5], this assumption is particularly critical for the patella, because of its small motion, small dimension, and the large gliding of the skin. Metal probes have been implanted into the patella to obtain a rigid connection with the markers and thus a reliable joint motion, but this was possible only in in vitro studies
[5][21][22][23][24][25][26]. Thus, adapting the results of these studies to real patellofemoral joint function and PFP is difficult. Nevertheless, there are studies reporting the placement of skin markers on the patella
[27][28][29][30][31][32][33][34]; however, careful full-text readings revealed that patella movements apparently were not tracked in these articles. The present observation also points out the importance of consistent reports in the literature.
3. Imaging Studies
Radiographic, CT, and MRI evaluations are commonly preferred for differential diagnosis of PFP
[35]. Initially, anteroposterior and lateral radiographic imaging is involved for the evaluation since it is a simple and quick option to see the patellar position (patella alta, patella baja, mediolateral subluxation) for the first clinical diagnosis
[7]. However, CT and MRI imaging have advantages over radiographic assessments since they provide static and dynamic cross-sectional scanning including soft tissues and information about other possible abnormalities
[6][7]. However, all of the imaging techniques offer dynamic evaluations, and all of them have advantages and disadvantages in terms of radiation exposure, acquisition quality, and time limitations
[5][36][37][38]. Imaging is often performed in the supine position in which the patella is simply not exposed to any muscle forces. However, PFP patients experience symptoms while the patella is exposed to muscle forces such as running and stair ascent and descent. Especially with the advancement in biomechanical analysis and improved understanding of patellar kinematics
[19], acquisition techniques have become more specific and tailored by applying devices to create weight-bearing conditions. Thus, dynamic assessments have gained importance to provide a real-time interplay of soft tissue and bone structures.
In the current review, there were 34 articles using imaging evaluations in weight-bearing and dynamic conditions. Thirty of these used standard MRI, CT, and other radiographic devices with custom-built loading platforms to apply forces at the patello-femoral joint. These platforms were mainly fixed under the feet and allowed the subject to push and release force in their muscles. So far, the technology was well known but the technique was different from static acquisition. However, two studies used CBCT, which is quite a breakthrough version of CT
[39][40]. CBCT is an emerging medical imaging technique forming a cone shape as opposed to the spiral slicing of conventional CT
[13]. CBCT uses a rotating platform with a radiation emitter and flat panel detector to gather multiple quick exposures and produce a 3D volumetric image. By projecting a collimated beam with a large rotation around the stationary patient, a complete volumetric three-dimensional data-set is collected. This differs from traditional CT scans, which use a helical 2D fan shape, resulting in slower scanning times and higher radiation dosages. Exposure to less than half the radiation dosage compared to traditional CT has been noted for these foot and ankle scans
[41]. CBCT also has less image distortion and fewer artifacts associated with patient movement
[42]. This technique provides convenience by collecting the data very quickly, enables data collection in an up-right posture, and implies less radiation exposure. While up-right evaluation is particularly important for foot and ankle studies, these devices enable visualization and measures of the position of bones and muscles under physiological load, which is much better when compared to CT scans under simulated loading conditions. However, the cone-shaped beam causes scatter interference when radio-opaque materials, like metal, are in the anatomical area of interest. This interference significantly reduces the image quality
[42]. Regarding the cost-effectiveness, it has been reported that the yearly mean profit can even be over EUR 53,000 in a typical hospital
[43]. Also, it has been shown that using CBCT shortens the scanning time 77% per patient in the same study.
4. EMG Studies
The number of EMG studies demonstrates the importance of assessing muscle forces in PFP. These studies reported on a wide range of motor tasks and of muscle groups, also including those around the hip and the ankle joints, and both flexors and extensors. However, standard data collection methods and systems were used. Only two studies
[44][45], though the same research team reported the utilization of original high-density surface EMG (HDsEMG) electrodes; this technology enables the placement of several tens of electrodes for each single muscle. HDsEMG is a linear electrode grid array with 16 silver bar electrodes, with a 10 mm interelectrode distance (OT Bioelettronica, Torino, Italy). Each grid comprised 64 electrodes arranged in 5 columns and 13 rows with a single electrode missing in one of the corners. This electrode is claimed to provide information about innervation zones and anatomical factors for the best estimation of neuromuscular activation and regions. Using these electrodes, data from the vastus medialis and vastus lateralis were collected, since these can be placed between the edges of each muscle
[44][45]. Acknowledged advantages of HDsEMGs with respect to traditional bipolar electrodes are a topographical representation of the EMG amplitude, more selective recordings, and reliable motor unit behavior
[46][47]. Another study from the same team aimed to investigate whether Principal Component Analysis (PCA) and non-Negative Matrix Factorization (NMF) can provide similar results when used to identify regional muscle activation from HDsEMG signals and showed that a single factor from either the NMF or PCA explained on average 70% of the variance across channels
[48]. They found that up to 30% of the variance was explained by regional variations in muscle activity rather than common fluctuations across the muscle, suggesting that a single bipolar electrode would not fully capture the EMG across the whole muscle.
HDsEMGs differ from conventional sEMGs in terms of their scopes. Conventional sEMGs are mainly used in movement studies by yielding concurrent information on activity in different muscles. With HDsEMGs, it is possible to subtract information at a single motor unit, and also muscle-fiber conduction velocity can be gathered as in the needle EMG
[49]. Surface electromyographic amplitude is influenced by factors such as adipose tissue thickness, normalization, cross-talk, and motor unit action potential cancellations
[44]. As signals are collected from different locations of the muscles, HDsEMG helps to overcome the limitations such as describing activation of the regions within a muscle and taking into account the effect of location of the innervation zone
[45]. For example, in the selected study, Gallina et al. showed that females with PFP have simpler VM and VL activation strategies, observed as a lower co-activation of regions between VM and VL and a lower redistribution of activation from VL to VM when the concentric and eccentric phases of the knee extension are compared by using this novel electrode
[45]. HDsEMG is an electrode that needs uniformity from different perspectives since it is still in a very early stage in terms of clinical applications and the existence of different names for HDsEMGs (high-resolution EMG, multi-array EGM, matrix electrodes).
Despite the obvious experimental issues, these novel electrodes may provide relevant information regarding femur muscle characteristics in different motor tasks.
5. Recommendations for Future Studies
5.1. Finite Element Analysis/Calculations/Networks/Artificial Intelligence
These assessment approaches seem to be receiving a lot of attention in the literature and there has been a rise in their number
[50][51][52]. These methods either enable large amounts of data to be processed efficiently and yield results
[53][54] or provide very detailed results from a very small number of subjects with detailed assessments
[11][51][55][56][57][58][59][60][61][62]. They seem to have important potential for future studies, as they are approaches for processing data independent of the technology used. However, the obtained information should be manageable and convertible into useful information at the clinical level. It seems that the development of common approaches to understand the PFP characteristic may be useful for further studies.
5.2. Combined fMRI-, TMS-, and EEG-Based Analysis
By understanding the importance of central nervous system processes that modulate the interaction between pain and sensorimotor control for the people with movement dysfunctions, investigating brain activity has gained popularity in chronic pain patients
[63][64]. This has led researchers toward technological evaluation methods that can be used to investigate the relationship between brain-activity-related signals and PFP. In the current review, there were studies using functional MRI (fMRI), electroencephalography (EEG), and transcranial magnetic resonance (TMS) imaging techniques to evaluate patient differences or the effectiveness of taping or exercise
[63][64][65][66][67][68][69][70].
5.3. Ultrasonographic Imaging
Ultrasonographic evaluations are frequently used in the clinic because of their easy access and use. Although this is not in itself a novel technology, some its novel features can be taken into consideration in the future to understand the soft tissue properties in PFP through elastographic, architectural, and echo-intensity feature assessments of muscles
[71][72][73]. In addition, with the introduction of portable systems and transducer fixation devices, dynamic skeletal muscle evaluation has become possible during different motor tasks
[74].
5.4. Acoustic Emission
Acoustic emission is a technique used to detect the waveform features, which has been shown to provide potential biomarkers collected from the knee joint. Shark et al. conducted a study on osteoarthritis patients to demonstrate the differences in the knee from degeneration and age in the flexion–extension-related tasks
[75]. The results showed that there was higher movement variation and increased asymmetry in the patient group compared to healthy individuals. Acoustic emission is shown as a measurement reflecting a composite of structural changes and joint loading factors and is highlighted as a potential candidate for relevant future studies
[76]. However, even collecting data has some challenges such as application difficulties, optimal placement, accessibility, and being a novel method that still needs improvement. It can also be considered as a promising technology with the advantages of being non-invasive and non-radioactive and providing information about internal joint contact forces
[77][78].
5.5. Myotonometry/Reaction Time
In the present search, three new technologies for PFP assessments were found. However, these were not exactly related to the patellofemoral joint but somehow to relevant muscular conditions. One is tensiomyography, which evaluates the muscular mechanical and contractile properties by means of an external electrical stimulus of controlled intensity. It provides information on fatigue, muscle activation, and tone
[79]. Another one, used in the same study, is a myotonometry device that measures the stiffness of the muscle at rest
[79]. Both of these assess biomechanical muscular properties in an objective way and have been shown to be of value. Muscle stiffness and fatigue are mentioned in fact to be among possible risk factors for knee-joint-related injuries
[80]; thus, these new methods may provide original information in addition to EMG.
The third method can evaluate the muscle reaction time, i.e., the time from the appearance of unpredictable stimuli to the start of the selected motor response. It includes central processing and motor time that is necessary for motor response. The reaction time was found higher in PFP patients compared to healthy populations, with this being a valuable representation of the central process and motor reaction delay
[81][82]. This assessment can be used as a non-invasive and easy alternative for central deficit assessments.
5.6. Accelerometers
With the increased use of microsensor technology, relevant devices have become available to quantify kinetic and kinematic outcomes. Tibial accelerometers have been used in the past also in vivo, being mounted directly on the bone using transcortical pins to infer tibial axial acceleration from ground reaction forces
[83]. More recently, skin-mounted accelerometers have been utilized to determine physical activity loading, running kinematics, and even ground reaction forces
[84]. Being less expensive, user-friendly, and accessible than force plates, skin-mounted tibial accelerometers could be another novel option in research or clinical settings in PFP patients. However, it should be kept in mind that they do not measure vertical ground reaction forces as standard force plates; they are considered accurate and reliable tools to measure lower extremity load in constant-velocity running
[84].