If Turner's hypoplasia is found on a canine or a premolar, the most likely cause is an infection that was present when the primary (baby) tooth was still in the mouth. Most likely, the primary tooth was heavily decayed and an area of inflamed tissues around the root of the tooth (called a periapical inflammation), affecting the development of the permanent tooth. The tooth most likely affected by this cause is the canine tooth. The appearance of the abnormality will depend on the severity and longevity of the infection.

If Turner's hypoplasia is found in the front (anterior) area of the mouth, the most likely cause is a traumatic injury to a primary tooth. The traumatized tooth, which is usually a maxillary central incisor, is pushed into the developing tooth underneath it and consequently affects the formation of enamel. Because of the location of the permanent tooth's developing tooth bud in relation to the primary tooth, the most likely affected area on the permanent tooth is the facial surface (the side closer to the lips or cheek). White or yellow discoloration may accompany Turner's hypoplasia. Enamel hypoplasia may also be present.

Turner's hypoplasia usually affects the tooth enamel if the trauma occurs prior to the third year of life. Injuries occurring after this time are less likely to cause enamel defects since the enamel is already calcified.

The same type of injury is also associated with the dilaceration of a tooth.

Dilaceration is a developmental disturbance in shape of teeth. It refers to an angulation, or a sharp bend or curve, in the root or crown of a formed tooth.

The condition is thought to be due to trauma or possibly a delay in tooth eruption relative to bone remodeling gradients during the period in which tooth is forming. The result is that the position of the calcified portion of the tooth is changed and the remainder of the tooth is formed at an angle.

The curve or bend may occur anywhere along the length of the tooth, sometimes at the cervical portion, at other times midway along the root or even just at the apex of the root, depending upon the amount of root formed when the injury occurred.

Such an injury to a permanent tooth, resulting in dilaceration, often follows traumatic injury to the deciduous predecessor in which that tooth is driven apically into the jaw.

Clinical examination and x rays can help diagnose the condition. For examples :

- Valsalva test (nose blowing test): Ask the patient to pinch the nostrils together and open the mouth, then blow gently through the nose. Observe if there is passage of air or bubbling of blood in the post extraction alveolus as the trapped air from closed nostrils is forced into the mouth through any oroantral communication. Gentle suction applied to the socket often produces a characteristic hollow sound.

- Perform a complete extra- and intra-oral examination using a dental mirror under good lighting, look for granulation tissue in the socket and openings into the antrum.

- Panoramic radiograph or paranasal computed tomography can help to locate the fistula, the size of it and to determine the presence of sinusitis and other foreign bodies. Other methods like radiographs (occipitomental, OPG and periapical views) can also be used to confirm the presence of any oroantral fistulas.

- To test the patency of communication the patient is asked to rinse the mouth or water is flushed in the tooth socket.

- Unilateral epistaxis is seen in case of collection of blood in the sinus cavity.

- Do not probe or irrigate the site, because it may lead to sinusitis or push foreign bodies, such as contaminated fragments, or oral flora further into the antrum. Hence, leading to the formation of a new fistula or widen an existing one.

It can be caused by any of the following:

- Nutritional factors.

- Some diseases (such as undiagnosed and untreated celiac disease, chicken pox, congenital syphilis).

- Hypocalcemia.

- Fluoride ingestion (dental fluorosis).

- Birth injury.

- Preterm birth.

- Infection.

- Trauma from a deciduous tooth.

The maxillary sinus is known for its thin floor walls and close proximity to the posterior maxillary teeth. Dental procedures such as extraction of these teeth sometimes cause OAC. The posterior maxillary molars and maxillary sinus are innervated by the same branch of nerves which is the maxillary division of trigeminal nerve. This innervation complicates the situation as the pain from maxillary sinus might be indistinguishable from a posterior maxillary toothache. Other known causes of OAC are fracture across the antral floor typically Le Fort I, displacement of posterior maxillary molar roots into antrum, and direct trauma. Extraction of primary teeth are not considered a risk of OAC due to the presence of developing permanent teeth and the small size of a developing maxillary sinus. OAC can happen for many other reasons, such as acute or chronic inflammatory lesions around the apex of tooth root present in close proximity with the maxillary antrum, necrotic lesions of the maxilla, failure of sublabial incision to heal after Caldwell-luc antrostomy, multiple and extensive fractures of the facial region, Osteomyelitis of the maxilla, injudicious use of instruments during oral procedures, malignancy of the maxillary sinus, Syphilis, malignant granuloma, radiotherapy, implant denture, removal of a large cyst or resection of large tumour involving maxilla, development of tumour causing bone destruction and loosening of teeth.