Comparison Oclean Endurance vs Xiaomi MiJia T100

The number of working nozzles that are standardly supplied with the device. Nowadays, options are quite common with both one and two or three nozzles in the kit; and in the most extensive sets, this number can be four or five or even more.

In many sets, several nozzles may have different purposes. For instance, an irrigator, in addition to its standard nozzle, might include orthodontic and periodontal nozzles. However, it's important to note that models with the same number of accessories in the kit can have different specific specializations. So, when making a choice, it's wise to consider not just the quantity but also the types of nozzles available. Additionally, there's an option where several identical interchangeable heads come with one handle. This configuration is particularly common in toothbrushes. It enables multiple individuals, such as family members, to use a single device, and such a set is usually more cost-effective than purchasing individual toothbrushes for each person.

Types of nozzles supplied as standard with the device.

The availability of nozzle types largely depends on the device's intended purpose (as discussed in the "Type" section). Toothbrushes typically offer standard round and oval-shaped nozzles, as well as options for sensitive teeth (also available in both round and oval shapes), and combined devices that may have multiple functions. In contrast, irrigators can come with various nozzles, including conventional ones, those designed for cleaning gum pockets (periodontal), and even nozzles for nasal irrigation. Devices intended for use with braces, implants and tongue cleaning are primarily found in irrigators, although they may also be compatible with some toothbrushes.

Here is a more detailed description of each of these options:

— Oval standard. Oval-shaped toothbrush heads are designed for standard cleaning intensity and are not specifically intended for sensitive teeth. The performance of these nozzles depends on the cleaning technology they employ (as explained below). For instance, models using reciprocating sweeping patt...erns offer more intensive treatment compared to similar round heads with reciprocating technology. However, this type of cleaning is less gentle and requires precision even for individuals with healthy teeth and gums. In the case of sonic and ultrasonic brushes, there is no significant difference, and oval-shaped heads are widely used because they cover a larger surface area, allowing for quicker toothbrushing. Occasionally, you may come across oval nozzles with a reciprocating-rotating mechanism, which, in terms of shape and application, are closer to round heads.

— Round standard. Round toothbrush heads are designed for standard cleaning and are not specifically intended for sensitive teeth. They are primarily used in models featuring reciprocating cleaning technology (as explained below). In comparison to their closest alternative, oval-shaped reciprocating-sweeping heads (as described earlier), round nozzles offer a gentler cleaning action and better access to hard-to-reach areas. They may not perform as well in cleaning open spaces, but this is typically not a critical issue. However, in "sonic" brushes, round heads are quite rare. In such cases, round heads do not offer significant advantages over oval ones, and their coverage area is noticeably smaller, which can reduce their overall effectiveness.

— Oval for sensitive teeth. A variation of the oval heads described above, optimized for the cleaning of sensitive teeth and gums (including inflammation in the oral cavity). Such devices are distinguished primarily by softer bristles than in standard nozzles; in addition, other design features may be provided to ensure the most delicate and gentle impact.

— Round for sensitive teeth. Round heads specially designed for sensitive teeth and gums. For round nozzles in general, see above; and the main difference of this variety is a softer bristle, which allows you to achieve the necessary accuracy and care during processing. In addition, the design may provide other solutions that eliminate discomfort when used with sensitive teeth or inflamed gums.

— Combined. A head that combines round and elongated (like an oval) sections. Allows you to combine the advantages of both options to some extent. Note that such heads are rarely used as regular ones, in most cases they are produced as interchangeable accessories.

— Standard for an irrigator. Classic irrigator heads designed mainly for cleaning healthy teeth and gums. The working part of such a head has the form of a nozzle of small diameter, and almost all modern irrigators and flossing systems are equipped with similar devices (see "Type"). Often, several standard heads are supplied in the kit at once — this allows several users to use one device at once without worrying about hygiene.

– Orthodontic (for braces). Specialized heads for removing plaque and dirt in hard-to-reach places under braces and other orthodontic structures. For this purpose, you can use a standard head, however, such devices more effectively cope with such tasks. Most often they come with irrigators and flossing systems, but they are also found in toothbrushes.

– Periodontal (cleaning pockets). Gum pocket cleaning heads are designed for cleaning the areas where the gums make contact with the teeth, known as "gingival pockets." These devices feature thin heads made from soft materials to provide gentle and precise cleaning. They are particularly effective for individuals with inflamed gums and certain other oral conditions, but they can also be beneficial for users with entirely healthy gums.

— For implants. Heads designed for cleaning implants, crowns, bridges, and similar dental structures serve a similar purpose as braces heads, focusing on effectively cleaning hard-to-reach areas. These heads may be included with toothbrushes, although they are more commonly found in the accessory sets of irrigators.

— Tongue cleaning. Special heads designed for cleaning the tongue and inner surface of the cheeks help maintain overall oral hygiene and combat bad breath by removing foreign plaque. In irrigators, these nozzles typically feature a spatula-like shape that scrapes away plaque, which is then washed away by a stream of water. Toothbrushes designed for tongue cleaning use a head with a specialized surface that replaces traditional bristles with low-height solid protrusions, typically less than a millimeter in height. These protrusions effectively clean the tongue, primarily focusing on this area.

— Nasal cleaning. An irrigator equipped with a head for nose washing serves multiple purposes, including the treatment of conditions like a runny nose or sinusitis, as well as general nasal hygiene and prevention. The head for this purpose includes a unique "plug" that securely seals one nostril to prevent liquid from flowing back. The nose washing procedure is typically performed with the head in a sideways position. Water or saline solution is gently introduced into one nostril, which is positioned higher, and flows out through the other nostril. The head is then turned to the opposite side, and the process is repeated. It's important to note that while this procedure is generally safe, there are specific contraindications, so consulting with an ear, nose, and throat (ENT) doctor before using an irrigator in this capacity is advisable.

Apart from the mentioned nozzles, modern toothbrushes and irrigators may come with various other types of attachments. Toothbrushes might include attachments for tartar removal, flossing heads with ultra-thin bristles that mimic dental floss, or specialized gum massage heads. Irrigators may offer specialized nozzles for intensive or gentle treatment, multi-jet nozzles and more.

The brushing technology used by the toothbrush (see "Type").

In today's market, toothbrushes mainly feature cleaning technologies such as a href="/list/420/pr-14372/">reciprocating, reciprocating-sweeping, sonic and ultrasonic. The first two options can also include the additional feature of pulsating technology. The main difference between these methods lies in the nature of the movement of the bristles; Here is a more detailed description of each option:

— Reciprocating. This cleaning technology involves the bristles on brushes with round heads moving in a traditional manner. As the name suggests, the head rotates back and forth at a slight angle during operation. This technology is considered somewhat more advanced than reciprocating-sweeping, particularly because it offers improved cleaning in interdental and similar areas. However, it's important to note that brushes with this technology still don't match the efficiency of sonic and ultrasonic brushes but are generally more budget-friendly.

— Reciprocating-sweeping. Historically, this technology was the first to be used in brushes with oval nozzles. In brushes employing this principle, the bristles oscillate from left to right, resembling the motion of a broomstick—hence the name "reciprocating." Classic reciprocating brushes are characterized by a sim...ple design but are not particularly effective. Consequently, there are few such models available today, primarily found in low-cost devices. Most toothbrushes with oval heads now use more advanced sonic or ultrasonic technology.

— Pulsating. Usually, this term refers to the format of operating, in which the bristles move up and down relative to the surface of the nozzle, in other words, they go deep into the head and move back. This technology is rarely used in its pure form, it usually complements a reciprocating or reciprocating sweeping head, providing 3D cleaning capabilities (refer to "Modes"). But if the 3D mode is not claimed in the toothbrush, it is worth clarifying separately what is meant by pulsating technology. So, in some models, we are actually talking about the whitening mode, when, for maximum intensity of exposure, the device does not work constantly, but in separate pulses; in others, the term "pulsating" actually refers to the sonic or ultrasonic mode of operation.

— Sound. Sonic cleaning technology involves bristle vibrations with a small amplitude at a high frequency, reaching up to 40K vibrations per minute — this speed aligns with audible sound frequencies, hence the name "sonic." This cleaning method is considered more advanced than reciprocating and even reciprocating-sweeping technology. Sonic brushes, thanks to their high vibration speed, create a fine, uniform foam by mixing toothpaste, saliva, and air during cleaning. This foam can effectively penetrate hard-to-reach areas, and the vibrations themselves prove highly efficient at removing plaque, including from interdental spaces. While ultrasonic cleaning is considered even more advanced (as discussed below), sonic brushes are generally more affordable.

— Ultrasonic. Ultrasonic cleaning technology represents a further advancement of the sonic technology described earlier, distinguished primarily by a higher oscillation frequency. It's important to note that not all brushes in this category operate in the ultrasonic range; some models have oscillation frequencies that only slightly exceed 40K per minute, which is still within the range of audible sound. However, the operating frequency of such devices is significantly higher than that of standard sound devices. Ultrasonic technology offers several advantages, including thorough cleaning with access to hard-to-reach areas and a bactericidal effect. Ultrasound is capable of destroying bacteria responsible for plaque formation. However, brushes with this technology tend to be somewhat more expensive than their sonic counterparts.
It's important to mention that ultrasound technology is not as effective as conventional sound vibrations for cleaning braces and similar structures. As a result, some devices in this category incorporate both ultrasonic and conventional sound vibrations to ensure thorough cleaning in all situations.

The frequency of sound vibrations provided by a brush with a sonic or ultrasonic principle of operation (see "Cleaning technology").

A high oscillation frequency (from 40 000/min and above), ositively impacts the efficiency and quality of oral processing. In fact, brushes that generate more than 40,000 oscillations per minute are often referred to as ultrasonic brushes, although true ultrasound starts at much higher frequencies. However, it's important to note that these high-speed brushes tend to come with a higher price tag. It's also worth mentioning that for specific tasks, such as delicate treatment of sensitive teeth, relatively lower frequencies may be more suitable. Therefore, when choosing an oral care device, it's essential not to prioritize the maximum oscillation frequency but rather consider the individual needs of the user(s). Consulting a dentist for personalized recommendations is a prudent approach.

It's important to clarify that in this context, a full cycle of bristle movement is defined as one complete oscillation, which includes both the forward and backward motion. Some manufacturers employ a marketing tactic where they list their brush's operating frequency not in terms of complete oscillations but as the number of movements per minute, counting only half of the cycle — either the forward or backward motion. This can lead to impressive-sounding numbers in product specifications since the count of...movements is double the count of oscillations. However, the primary performance metric remains the number of complete cycles or oscillations, and that's the value provided in this section of our catalog.

The last mode memory allows the device to "remember" which mode was active at the time of shutdown — thus, after switching on, work will continue in the same mode.

This feature is primarily found in toothbrushes (see "Type"), especially relevant due to the various programs available in such devices. However, it's important to consider that the memory of the last mode is convenient when consistently using one mode. If switching between different modes, it can become inconvenient. For instance, if a user starts with a regular cleaning program and then switches to a separate polishing program, the brush will default to polishing mode each time it's turned on, requiring manual adjustment to switch back to cleaning mode. Therefore, before seeking a device with this feature, ensure it aligns with your usage needs.

Possibility of mounting the device on the wall.

The design of the mount for these devices depends on the device type (as mentioned earlier) and how it's typically used. In the case of most toothbrushes, which are typically self-powered, they come with a wall-mounted stand that also functions as a charger. Some irrigators and dental centers follow a similar setup, but many of these devices are designed for stationary use and have a larger main unit to which a handle with a nozzle attaches. In such models, the wall mount is designed to accommodate the entire main unit.

Wall installation offers a significant advantage by saving shelf space, which is particularly beneficial in tight spaces. However, this installation method entails additional preparatory work, which can be somewhat challenging. Furthermore, not all wall mounts facilitate easy removal and installation of the device, making it less suitable for situations where you frequently need to take the toothbrush or irrigator with you on trips.

The time required to charge the battery from zero to 100% in a device with the appropriate power type (see above). This parameter can vary from 1 – 3 hours in relatively simple and low-power devices to a day in advanced models with capacious batteries. At the same time, the longer the maximum operating time on a charge (see above), the longer, usually, the time required for charging, although there is no hard dependence here.

In general, having fast charging capabilities improves the convenience of a device by reducing interruptions in its operation. However, there is a trade-off to consider: fast charging often means either a smaller battery capacity or a higher price due to the use of specialized technologies to speed up the charging process. When evaluating this parameter, it's essential to think about how you intend to use the device. For instance, if a toothbrush or irrigator is solely used at home by one person and comes with a charging stand, fast charging may not be a critical factor. The device remains consistently charged as it's constantly on the charger, and its battery doesn't deplete significantly during one use. The time between sessions, usually around 8 to 12 hours, is more than enough to maintain a charged battery, even for devices with slower charging. However, if you plan to use the device while traveling, where access to power outlets is sporadic, it's preferable to have minima...l charging time to ensure you can recharge quickly during your trips.

General dimensions of the device. Most manufacturers report this data only for stationary devices — irrigators of the appropriate variety and dental centers (see "Type") — because it is believed that toothbrushes (even with stands) are not so large as to be inconvenient, and not so varied in size, to pay attention to this difference.

Note that the dimensions are usually given only for the main unit, without taking into account the tools installed on it; however, the size of these instruments, again, it is not large enough to cause serious inconvenience.

The total weight of the device is an important consideration. In the case of stationary irrigators and dental centers (as mentioned in the "Type" section), weight isn't a significant factor since the main unit is placed on a stand or wall, and you don't have to hold it. In fact, for some of these models, weight may not even be specified. However, when it comes to toothbrushes or portable irrigators, the device's weight becomes a crucial factor. A heavy device can strain your hand and make it challenging to use during teeth brushing or other procedures. It's generally recommended that the weight of a portable device should not exceed 200 g, and lighter is often better. It's worth noting that in models that come with stands (as discussed earlier), the total weight is typically provided, accounting for both the main unit and the stand. The weight of the main unit alone is usually around 1.5 to 2 times less than the total weight.